Lecture Notes in Mathematics Edited by A. Dold and B. Eckmann
1027 Morisuke Hasumi
Hardy Classes on Infinitely Connect...
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Lecture Notes in Mathematics Edited by A. Dold and B. Eckmann
1027 Morisuke Hasumi
Hardy Classes on Infinitely Connected Riemann Surfaces
Springer-Verlag Berlin Heidelberg New York Tokyo 1983
Author
Morisuke Hasumi Department of Mathematics, Ibaraki University Mito, Ibaraki 310, Japan
A M S Subject Classifications (1980): 30 F99, 30 F 25, 46 J 15, 46 J 20, 31A20, 3 0 D 5 5 ISBN 3-540-12729-1 Springer-Verlag Berlin Heidelberg New York Tokyo ISBN 0-387-12729-1 Springer-Verlag New York Heidelberg Berlin Tokyo This work is subject to copyright.All rights are reserved,whetherthe whole or part of the material is concerned,specificallythose of translation,reprinting,re-use of illustrations,broadcasting, reproductionby photocopyingmachineor similar means,and storage in data banks. Under § 54 of the GermanCopyright Law where copies are madefor other than private use, a fee is payableto "VerwertungsgesellschaftWort", Munich. © by Springer-VerlagBerlin Heidelberg 1983 Printed in Germany Printing and binding: Beltz Offsetdruck, Hemsbach/Bergstr. 2146/3140-543210
PREFACE
The purpose on i n f i n i t e l y Already "Hardy print
connected
in this Classes
on R i e m a n n
Surfaces"
analytic
when
H a r d y himself,
disk
J. E.
Speaking
roughly,
sively
in the case of the unit
as well as simplicity. or not,
has
drawn m u c h
Opposed
to this,
our
laid
stress
made
discussed
their
amount
have
been
now be
in the
growth
of func-
The theory
of these
G.
i~ the work
Szeg~
among
of l i t e r a t u r e studied
from the cradle
in
years.
debut
the mean
[15].
appeared
should
its f o u n d a t i o n
growing
classes
which
subsequent
F. and M. Riesz,
disk
topics.
monograph
most
of
others.
in this inten-
for its i m p o r t a n c e
The case
of f i n i t e l y
oonnected
attention
and e n j o y e d
considerable
our k n o w l e d g e
connected
classes
deals m o s t l y
bearing
on our present
analytic
methods
of c o m p l e x class
for example.
theory
theory thus
of f u n c t i o n
surfaces,
planar
progress
it,
still
an i n d e p e n d e n t of general
so we should finitely
this
in
theory
from G a m e l i n ' s
the r e a c h
field
"For w h i c h
known
class
can one get a f r u i t f u l
classes?" at least,
In the present to this
[I0]
surfaces, and
and balls.
is not yet very well
surfaces
partial
connected
book
of the new t h e o r y
of p o l y d i s k s
question:
of H a r d y
try to give an answer,
in the
and the a b s t r a c t
grown to form the core of the n e w l y -
surfaces
Riemann
direct
functional-
applications
classes
in the
of Hardy
not have m u c h
the case of i n f i n i t e l y
basic
small
theory
downwards,
as e v i d e n c e d
lies b e y o n d
Riemann
open
sion of the c l a s s i c a l we will
Hardy
study as in the case
begin with
connected
has
algebras,
1950's
successful
including
created
to be r e l a t i v e l y
The c l a s s i c a l
disk and does
From
their
Nevertheless,
as I u n d e r s t a n d
structure
problem. found
seems
surfaces.
with the unit
have
function
born t h e o r y
needs
Hardy
some r e l a t e d
years.
case of i n f i n i t e l y
Hardy
classes
was
and still
area.
that
in his pa p e r
Littlewood,
classes
Heins,
seen d u r i n g
Hardy
of functions
A n d we now have a large
recent
natural
G. H. H a r d y
on the unit
classes
and
of H a r d y
we have a b e a u t i f u l by M a u r i c e
we have
recognized,
in 1915,
surfaces
series
It is t h e r e f o r e
As g e n e r a l l y
very useful
is to give an account
Riemann
Notes
on some new a d v a n c e s
literature tions
notes
open
Lecture
in 1969.
placed
of these
The and
of inextennotes
question.
IV
Our
idea for a t t a c k i n g
any nice
surface
But what
do we mean
as most
should
promising
(abbreviated in Chapter
to
V.
in the
class
perhaps
motives.
result
class
An open
if every
bounded
holomorphic
of the unit results
almost
every
converges (D) origin
by M.
reason
here
of P a r r e a u - W i d o m will
[70]
[52]
in 1971
which
in
from very
later
why we are
following
type
be given
Parreau
definitions,
in the
functions.
turned
interested
fundamental
of this
following, positive
Green
where
measurable
R
denotes function
other
R
space
has
origin
to the given
boundary
function
along
Almost
Green
every
converges
to a point,
indeed
for
R
(D) means
that
PWS's
for w h i c h
in detail
in the M a r t i n
vertex
behavior
general
at almost
to g e n e r a l i z e
consists
the direct theorem.
the
Cauchy
whose
theorem--(DCT)
Concerning
these,
line.
A
every
of
with r e s p e c t on
solution
boundary
A of the
function
line.
class
maps
prob-
for any PWS. of surfaces
solution. the
following:
point from
of
More-
in R
A
can be
can be
disk.
Cauchy-Read
of two statements,
for
Green
measure
answer
so as to have
of a n a l y t i c
R
which
the B r e l o t - C h o q u e t
has a p o s i t i v e
as in the case of the unit
It is p o s s i b l e
Green
affirmative
first
problem
that
on
boundary
the usual
measurable every
along
from any fixed
and the h a r m o n i c
almost
relevant
R.
every
b~,
(D) can be r e f i n e d with
issuing
Furthermore,
form the
this
almost
R
in p a r t i c u l a r
properties
solution,
on
any b o u n d e d
[5]) has a c o m p l e t e l y
Stolz regions
Cauchy
with
in
lines
is m e a s u r e - p r e s e r v i n g
to the data along
and the b o u n d a r y
respectively,
~ ÷ b~
on the one hand,
statement
The t h e o r e m
Z say
on the other.
statement
genus
line
nice
a limit
of Green
has a unique
0
if and
a PWS. on
function
problem
type
has n o n c o n s t a n t
We list most
boundary
It seems
analysed
R
many
from any fixed
infinite
(E)
over
surfaces.
on the
(see Brelot
defined
inherit
issuing
converges
the
bundle
problem
for the point
The
kind
connected
harmonic
and the c o r r e s p o n d e n c e
A
is of P a r r e a u - W i d o m
line
line
0
Dirichlet
R
complex
sections.
to the Green m e a s u r e
verse
surfaces
The D i r i c h l e t
any b o u n d e d
over,
says that
to put f o r w a r d
The d e f i n i t i o n
The main
surface
disk or f i n i t e l y
Every
(C)
lem
and
of h o l o m o r p h i c
by H. W i d o m
different
same.
simple
we wish
introduced
is e x p r e s s e d
flat
surfaces
in the
(B)
on
first
independently,
Riemann
unitary
Moreover,
R
of R i e m a n n
following).
They used the
family
The c a n d i d a t e
was
of surfaces
is very
of Widom:
(A) only
an ample
is the class
"PWS"
out to be e s s e n t i a l l y in this
carry
by this?
This
1958 and also, different
the p r o b l e m
theorem
refinements for
we first
to PWS's. are called,
short--and have:
the
in-
V
(F)
The
inverse
The c o n v e r s e (G)
If
of b o u n d e d
R
holomorphic
the
utmost As we rect
type.
refinement shall
direct
there
theorem
Cauchy
we have:
(H)
Every
PWS
This,
expectation a PWS can Cauchy
state a n o t h e r
H~(R)
cussed
if
R
exist
genus
planar
of
(R)
R,
surfaces
Cauchy
formula--is
H
is a PWS.
characterizes
of
theorem--an
not always
valid.
for w h i c h
the di-
PWS's
for w h i c h
some
say about
algebra
the
fact
theorem without like
as an open
answer,
in this
is r e g u l a r
in the sense
PWS.
sub-
The
contrary
connection
satisfying
look
interesting
H~(R).
an a r b i t r a r y
has a n eg a t i v e
A curious
with
homeomorphieally
Banach
two things
R
in the
space
to the
is that
the direct
independent.
Finally,
notes.
Riemann
surfaces
tively,
PWS's
Apart
our last r e s u l t
out,
surfaces
shows
relevant
problem
subsets
this
we
that plane
of
of plane
are good regions
theory,
on
R
then
in the
R.
of PWS's
to be dis-
book c o n t a i n s
a detailed
regions
all that h a p p e n
in the c a t e g o r y which
functions
properties
from PWS's,
almost
can h a p p e n
are
on compact
about
of the c l a s s i f i c a t i o n As it turns
of p o t e n t i a l
of all h o l o m o r p h i c
convergence
been t a l k i n g
in these
account
the points
the direct
can be studied
of the
PWS's
the corona
of u n i f o r m
classes.
we have:
if the set
fact:
is dense
We have
space
have.
These
If a PWS
topology
almost
of i n f i n i t e
is all one can
one m i g h t
satisfy
separates
can be e m b e d d e d
for general
theorem.
(I)
R ideal
however,
problem
and
if and only
there
for PWS's
First
set in the m a x i m a l
PWS's
Namely,
surface
integral
while
PWS.
true.
fails.
problem
results.
corona
theorem
exist
holds,
theorem
The c o r o n a
R
On the other hand,
of the Cauchy
see,
Cauchy
on
t h e o r e m holds
Cauchy
for any
is also
Riemann
functions
Cauchy
inverse
Parreau-Widom
t h e o r e m holds
statement
is a h y p e r b o l i c
then the inverse Thus
Cauchy
of this
in terms
of Hardy
in the c a t e g o r y
of plane regions.
in some
sense
of
Intui-
or other.
can be as i l l - b e h a v e d
So
as one
can imagine. In w r i t i n g faces
of P a r r e a u - W i d o m
behaved
surfaces
It is hoped this
t h e s e notes
feeling
study
that
type
been
probably
our d e s c r i p t i o n
somehow
aims
or other. adaptation
faces.
It also
general
nor too special.
at finding
~ust refleet
led by the
of Hardy
I wish
of the e x i s t i n g some new facts
The present
notes
personal
pages
knowledge
will
of well-
justify
is that
our
of R i e m a n n
are n e i t h e r
are not c o m p l e t e interest
the sur-
is concerned.
to note
which
that
family
classes
in the f o l l o w i n g One thing
the a u t h o r ' s
feeling
form the widest
as far as the t h e o r y
is not a mere
sense but
I have
too
in any
in the field.
sur-
VI
At all event I hope that our effort w o u l d help not only extend the theory of H a r d y classes but also increase our k n o w l e d g e of R i e m a n n surfaces in general. The p r e r e q u i s i t e s
f o r ' r e a d i n g these notes are the f u n d a m e n t a l s of
a d v a n c e d complex function theory and some k n o w l e d g e of f u n c t i o n a l analysis.
As for the function theory~
we assume that the r e a d e r has some
a c q u a i n t a n c e with the facts to be found in Chapters Ahlfors and Sario
I, II, Iii, V of
[AS] and also in the first four chapters of the book
[CC] by C o n s t a n t i n e s c u and Cornea. Chapter i of Hoffman
As for the f u n c t i o n a l analysis,
[34] may be useful,
if not sufficient.
We now comment on the contents of the present notes. theoretic prerequisites
are sketched
The f u n c t i o n -
in Chapter I without proof.
order to deal r e a s o n a b l y with Hardy classes on m u l t i p l y - c o n n e c t e d surfaces,
we rely on two concepts:
and Martin c o m p a c t i f i c a t i o n . III, respectively.
multiplicative analytic
These are e x p l a i n e d
Chapter IV contains
In open
functions
in Chapters
II and
preliminary observations
on
H a r d y classes, where the b o u n d a r y b e h a v i o r is our p r i n c i p a l concern. The main body of this book begins
in Chapter V.
There,
the d e f i n i t i o n
of surfaces of P a r r e a u - W i d o m type is given after Widom. by means of r e g u l a r i z a t i o n , valent to Parreau's,
that this d e f i n i t i o n
p r o b l e m for PWS's
gebra of
L~
(see
(B),
(see (D)).
(F) is e s t a b l i s h e d by using Green lines and, as an
it is shown that
H~
is a m a x i m a l w e a k - s t a r closed subal-
on the Martin boundary.
(DCT) is p r e c i s e l y stated.
Next, the direct Cauchy t h e o r e m
We prove a w e a k e r v e r s i o n of (DCT), which
is valid for any h y p e r b o l i c Riemann surface, ation.
(C)) and then solve the Two types of Cauchy theo-
and i n v e r s e - - o n PWS's form the main theme of Chapter VII.
There, the statement application,
On the other hand,
t o g e t h e r with some applic-
(DCT) itself fails sometimes.
not be seen until we know something about invariant are studied in Chapter VIII. submodules of
But this can-
subspaces,
subspaces of
LP--on the Martin
C o r r e s p o n d i n g to the known results
for the case of
the unit disk, we c o n s i d e r two p r i n c i p a l types of invariant which are called doubly invariant and simply invariant, As for doubly invariant
which
In Chapter VIII we c l a s s i f y closed H ~-
LP--(shift-)invariant
b o u n d a r y of a PWS.
any PWS.
fundamental
In Chapter VI we discuss the D i r i c h l e t
p r o b l e m on the space of Green lines rems--direct
is e s s e n t i a l l y equi-
we present a d e t a i l e d proof of Widom's
t h e o r e m m e n t i o n e d in (A) above.
Brelot-Choquet
A f t e r showing,
subspaces,
respectively.
subspaees the situation is r a t h e r simple for
But the so-called Beurling type t h e o r e m for simply invariant
subspaces is not always valid for PWS's.
It is proved in fact that the
VII
Beurling
type
nection,
examples
types
theorem
is v a l i d
in C h a p t e r
of constr~etion:
Myrberg
type)
planar
PWS's
the third
for w h i c h
gives
same c h a p t e r we first bolic
prove
the
first
(DCT) (DCT)
fails
the
statement
(DCT).
classification (E) will not
are three
appendices
if
(DCT)
PWS's
the
is.
(G), w h i c h
of plane
theorem
a couple
just
by using
and a list of r e f e r e n c e s ,
PWS's
among
Hardy
IX hyper-
on PWS's
problem
classes.
in Chapter
which
and
In the
of c o n d i t i o n s
sketched
(of
In C h a p t e r
XI we solve Heins'
regions
but
three
of
holds;
is false. (I).
characterizes
in Chapter
con-
genus
a family
theorem
(H) and
collect
be proved
yields
but the corona
the c o r o n a
In this
We give there
of i n f i n i t e
second
statements
and then
Finally
statement
defines
holds;
for w h i c h prove
surfaces,
to
concerning
PWS's
we also
Riemann
equivalent
the
for w h i c h
if and only
X m a y be interesting.
The
VI.
There
is by no means
ex-
haustive. My i n t e r e s t was v i s i t i n g this
I am i n d e b t e d
It was
like
classes
to thank
after
thesis
Professor
when
primitive
the notes
written
thanks
expand
for a series
Metropolitan
notes
are due to P r o f e s s o r s and made
who
my k n o w l e d g e
Most
Sakai
some v a l u a b l e
and
remarks
from Professors
to w h o m
I wish
is my first
teacher
couragement
have r e m a i n e d
Mito,
Ibaraki
July,
1983
this
on the r e s e a r c h
book
who
Year
chapters topics
in The have
were reat Tokyo
Particular who o r g a n i z e d
I have much
benefited
and H. W i d o m
and
my appreciation.
to P r o f e s s o r
level
right
classes.
5, 1982.
Z. K u r a m o e h i
to express
thus
New d i s c o v e r i e s
S. Yamashita,
suggestions.
by very h e l p f u l
like to d e d i c a t e
of H a r d y
of the main
of July
study
I would
its B e u r l i n g
then.
I
For
L. Carleson,
I gave on the present
Dr. M. Hayashi, I would
to a serious
surfaces.
during
while
L. Kelley.
showed me the thesis
was w r i t t e n
the week
M.
and J.
to P r o f e s s o r
Institute
subsequently.
during
Riemann
aroused
in 1962-64.
H. H e l s o n
led me in 1972
thanks
to deepen
of lectures
University
lectures
that
first
at B e r k e l e y
Bishop,
L. A. Rubel,
of these
here was
connected
I also owe
I was able
version
E.
[45],
me to the M i t t a g - L e f f l e r
1976-77,
made
treated
of C a l i f o r n i a
on i n f i n i t e l y
its completion.
invited
subject
to P r o f e s s o r s
C. N e v i l l e ' s
of Ha r d y
the
in the
the U n i v e r s i t y
and w h o s e
Zir6 Takeda, inspiration
who
and en-
with me as fresh as ever.
Morisuke
Hasumi
CONTENTS
PREFACE
. . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CHAPTER
I.
§i.
§2.
§3.
Topology
Riemann
2.
The
Homology
3.
The
Fundamental
Classical
SURFACES:
Surfaces
Groups
Potential
Theory
. . . . . . . . . . . . . . . . .
4
. . . . . . . . . . . . . . . .
4
. . . . . . . . . . . . . . . . .
S
6.
Potential
Theory
Differentials
9.
Cycles
Definition
Class
F
and
Riemann-Roch Cauchy
9
Subclasses
on
9
. . . . . . . . . . . .
. . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . .
Compact
Bordered
Surfaces
. . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . .
II.
MULTIPLICATIVE
The Line
3.
Existence
Cohomology
Bundles
and
of
Basic
5.
0rthogonal
Group
of
Structure
. . . . . . . . . . . . .
23 23
Analytic
Sections Functions
Functions
.
31
. . . . . . . . . .
33
. . . . . . . . . . . . . . . .
Definition
2.
Integral
3.
The
33 36 38
COMPACTIFICATION
Compactification i.
28
. . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . MARTIN
14 17 22
. . . . . . . . . . . . . . . . . . . .
Decomposition
12
. . . . . . . . . . . . . . .
Multiplicative
Harmonic
ii
FUNCTIONS
Functions
Holomorphic
Structure
4.
ANALYTIC
Analytic
First
2.
III.
its
Theorem
Kernels
Multiplicative
CHAPTER
7
. . . . . . . . . . . . . . . . . . . .
and
Differentials
ll.
Notes
. . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . .
I0.
Lattice
i 2
Problem
Dirichlet
i
3
The
The
. . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . .
5.
Basic
REVIEW
. . . . . . . . . . . . . . . . . .
Functions
8.
QUICK
Group
Superharmonic
7.
A
. . . . . . . . . . . . . . . . . . . . . . .
4.
i.
51.
RIEMANN
Exhaustion
CHAPTER
§2.
of
OF
1.
Notes
§i.
THEORY
iii
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Representation
Dirichlet
Problem
39 39
. . . . . . . . . . . . . . . .
40
. . . . . . . . . . . . . . . . .
43
X
§2.
§3.
Fine
Limits Definition
5.
Analysis
Covering
IV.
§3.
Some
Harmonic
Harmonic
the
Unit
Definitions
3.
Boundary Some
5.
The
on
. . . . . . . . . . . . .
Functions Measures
Disk
Behavior on
B-Topology
RIEMANN
57
. . . . . . . . . . .
59 63
. . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . .
of
Riemann Hp
and
Multiplicative
Surfaces hp
. . . . . . . .
Functions
Analytic
. . . . . .
Functions
and
Basic Widom's
3.
Regularization
Definitions
Widom's
of
on
5.
Proof
Necessity
of
Widom's of
(I)
Regular
of
. . . . . . . . . . .
Parreau-Widom
Type
....
. . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . .
Theorem
6.
Review
Principal
7.
Modified
Green
8.
Proof
of
Sufficiency
9.
A
Direct
(II)
. . . . . . . . . . . . . . .
Operators
Functions
. . . . . . . . . . . . .
. . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . .
Consequenoes
. . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . GREEN
The
Dirichlet
i.
Definition
2.
The
The
Space
3.
The
4.
Limit
Green
73
83 83 85 86 90 90 95 99 99 102 iii 117 118
LINES Problem of
Dirichlet of
73
TYPE
. . . . . . . . . . . . . . . .
Subregions
66
75
. . . . . . . . . . . . . . . .
Surfaces
64
82
. . . . . . . . . . . . . . . . . . .
Theorem
Analysis
VI.
Properties
Characterization
4.
Few
PARREAU-WIDOM
Fundamental
2.
of
OF
64
74
. . . . . . . . . . . . . . . . . . . . .
SURFACES
i.
of
50 57
. . . . . . . . . . . . . . . . . . . . . . . . . . .
V.
49
. . . . . . . . . .
. . . . . . . . . . . . . . . . . . .
Results Hyperbolic
Results
Definitions
CHAPTER
§2.
of
on
Classes
Notes
§i.
of
Classical
4.
Proof
Behavior
CLASSES
Classes
Basic
Proof
49
. . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . .
HARDY
2.
Hardy
Limits
. . . . . . . . . . . . . . . . . . . . . . . . . . .
i.
CHAPTER
§2.
Maps
Preservation
Hardy
Fine
Boundary
7.
Notes
§i.
of
Correspondence
CHAPTER
§2.
of
6.
Notes
§i.
. . . . . . . . . . . . . . . . . . . . . . . .
4.
the
Star
Lines
of
Green
Lines
. . . . .
. . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . on
Regions
Green
Space
Lines
Problem
Green
along
on
Green
Lines
a
Surface
of
Parreau-Widom
Type
119 119 121 124
. . . . . . . . . . . . . . . . .
124
. . . . . . . . . . . . . . . .
129
XI
§3.
The
Green
5.
Convergence
of
6.
Green
and
7.
Boundary
Notes CHAPTER §i.
§2.
§3.
VII.
Statement Proof
The
Direct
3.
Formulation
4.
The
§2.
of
of
. . . . . . . . . .
132
. . . . . . . . . . . . . . .
132
Boundary
13S
Analytic
Common The
Theorem Results
Cauchy
IB
. . . . . . . . . .
Maps
. . . . . . . . . . .
140 143
. . . . . . . . . . . . . . . . .
144
. . . . . . . . . . . . . . . . . .
144
. . . . . . . . . . . . . . . . . .
145
Theorem of
the
Cauchy
. . . . . . . . . . . . . . . . .
Condition Theorem
of
151
. . . . . . . . . . . . . .
iSl
Weak
152
Type
. . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . .
Weak-star
7.
Maximality
Inner
of
Factors
Ha
155
. . . . . . . . . . . . . .
155
. . . . . . . . . . . . . . . . . .
Orthooomplement
of
156
H~(dx)
157
. . . . . . . . . . . . . . . . . . . . . . . . . . .
VIII.
SHIFT-INVARIANT
Preliminary
Generalities
2.
Shift-lnvariant
Invariant
Subspaces
Subspaees Invariant
4.
Simply
Invariant
S.
Equivalence
160
of
on
the
Unit
Disk
160
. . . . . . .
162
. . . . . . . . . . . . . . . . . . . .
167
Subspaces
. . . . . . . . . . . . . . .
167
Subspaees
. . . . . . . . . . . . . . .
169
( D C T )a
. . . . . . . . . . . . . . . . .
177
. . . . . . . . . . . . . . . . . . . . . . . . . . . CHARACTERIZATION
Inverse
Cauchy
i.
Statement
2.
A Mean
3.
Proof
Conditions
of
Value of
the
General
S.
Functions
OF
Theorem
the
Main
Theorem Main
Equivalent
4.
Notes
. . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . .
Doubly
IX.
159
SUBSPACES
Observations
i.
The
Martin
of
Theorem
Direct
6.
CHAPTER
Boundary
Lines
THEOREMS
Cauchy
Applications
Notes
§i.
CAUCHY
2.
3.
Martin
the
Behavior
i.
Notes
§2.
the Green
. . . . . . . . . . . . . . . . . . . . . . . . . . .
Inverse
CHAPTER
and
Lines
The
5.
§i.
Lines
Discussion mP(~,a)
SURFACES and
OF
Surfaces
Result
PARREAU-WIDOM of
178 TYPE
Parreau-Widom
. . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . .
Theorem to
the
. . . . . . . . . . . . . . . Direct
Cauehy
Theorem
.....
. . . . . . . . . . . . . . . . . . . and
(DCT)
. . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . .
Type
179 17g 183 187 198 198 200 207
XII
CHAPTER §i.
§2.
§3.
§4.
X.
PWS
of
§3.
Infinite
Genus
PWS's
2.
Verification
Plane
of
3.
Some
Existence
Further
of
of
Simple
Embedding
6.
Density
The
Corona
7.
(DCT)
8.
Negative
for
. . . . . . . .
208
Which
(DCT)
Fails
215 217
. . . . . . . . . . . . . . . . . Ideal
Space
. . . . . . . . .
Hardy-Orlicz
223
PWS
227
. . . . . . . . . . . . . . . . .
Theorem:
Positive
Examples
....
. . . . . . . . . . . . . . . . . . .
Classes
i.
Definitions
2.
Some Sets
of
3.
Preliminary Existence
N~
of
5.
Lemmas
6.
Classification
7.
Majoration
Null
233
234 234 235
. . . . . . . . . . . . . . . . . . .
238
. . . . . . . . . . . . . . . . . . .
238
. . . . . . . . . . . . . . . . .
Regions
. . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . .
by
229
. . . . . . . . . . . . . . . . .
Sets
Plane
227
REGIONS
. . . . . . . . . . . . . . . . . . . .
Lemmas of
Classification
Notes
PLANE
Properties
Class
4.
OF
. . . . . . . . . . . . . . . . . . . . . .
Basic
221 221
. . . . . . . . . . . . . . . . . . .
Corona
CLASSIFICATION
215
. . . . . . . . . . . . . . . . . . .
Maximal
Examples
for
. . . . . . . . . . . . . . . . . . .
PWS
for
Type
. . . . . . . . . . . . . . . . . . . . . . . . . . .
XI.
208
213
(R)
the
Holds
. . . . . . . . . . . . . . . . .
of
H
(DCT)
. . . . . . . . . . . . . . . . .
the
Problem and
Which
TYPE
Type
Lemmas
into
PARREAU-WIDOM
(DCT)
Theorem
of
OF
Parreau-Widom
Properties
5.
Null
SURFACES
Myrberg
Regions
4.
CHAPTER
§2.
OF
i.
Notes
§i.
EXAMPLES
Theorem
. . . . . . . . . . . . . . . . .
Quasibounded
Harmonic
Functions
. . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . .
247 253 253 256 260 261
APPENDICES A.I.
The
Classical
A.2.
Kolmogorov's
A.3.
The
F.
References Index Index
of
and
Fatou Theorem
M.
Riesz
Theorem on
. . . . . . . . . . . . . .
Conjugate
Theorem
Functions
. . . . . .
. . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . Notations
. . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . .
262 267 269 272 276 278
CHAPTER
I.
Some basic
THEORY
results
OF RIEMANH
in the theory
here
for our later reference.
them
can be found
Sario,
Riemann
Riemannsoher
§i.
together
Surfaces
Fl~chen,
OF R I E M A N N
We refer
to
[AS]
A QUICK REVIEW
of R i e m a n n
surfaces
They are
with
stated w i t h o u t
complete
proofs
or in C o n s t a n t i n e s c u
referred
TOPOLOGY
SURFACES:
to as
[AS] or
for most
basic
definitions
not be given here,
e.g.
parametric
disk,
number,
surfaces
i.
IA.
Every in
structure regular in
R.
Unless
concerning
conformal
otherwise
etc.
Riemann
structure, In what
stated,
local
follows,
all Riemann
to be connected.
Every
region
and
in
R
creasing
R
in
Any sequence
number
a (sub-)region
(or
to have the c o n f o r m a l
D
in
compact,
R
is called
the b o u n d a r y
of n o n i n t e r s e c t i n g
a gD
of r e g u l a r
surface,
then there
regions
n = i,
Existence R
admits
and hence
regions
exhaustion
of
of a r e g u l a r a locally
that
R
of
analytic
components.
of r e g u l a r
for each
is called
A region
if it is r e l a t i v e l y
{Rn}n~ 1
a regular
IB.
disks
R.
is an open R i e m a n n
Rn+ I
R
is supposed
2,...
in and
R
exists
an in-
such that
CI(R n)
R : Un= I R n.
([AS],
12D)
is called
surface
R
has no compact
sequence
is included
set in
in
of a finite
R\ D
If
open
region
from that of
consists
Theorem.
II~
connected
induced
R
curves,
Ch.
and
R~nder
Exhaustion
domain)
D
intersection
surface.
are assumed
Ideale
SURFACES
which will
a Riemann
in Ahlfors
of
[CC] below.
surfaces,
denotes
either
and Cornea,
variable, R
are c o l l e c t e d
proof but most
R
n
in
R
having
shows
that
this
property
R.
exhaustion
finite
covering
can be r e g a r d e d
consisting
every Riemann of p a r a m e t r i c
as a polyhedron,
i.e.
a tri-
angulated
surface,
Theorem.
K = K(R)
hedron
if and
IC. of
K
(ii) An
Let
K
called every
has
I,
that
{Rn}n~ I
every
K
if
does
not
Riemann
which
P
a single
P
to
and
contour.
of
is the u n i o n
surface.
poly-
surface.
subcomplex
subcomplexes
belong
46A).
is a p o l y h e d r o n
and has
K
permits
Every
2A.
open
K
of
P
is and
n
if
Pn"
Then
the
a canonical
polyhedron
exhaustion.
K ([AS],
Let
R
hedron
K
regarded
Riemann
([AS],
2B.
surface ([AS],
the
looking
into
in p a i r s
= b. × b.
= 0,
I,
23D).
R
region
D
contour.
admits
1-simplex
Ch.
34A).
I,
properties
a regular
a. x b.
bi,
= i
exhaustion
or i n f i n i t e
and
a. × b. i
number
which
R.
sequence
for
in
K
is
gives
the
K
poly-
rise
to
canonical
can be o b t a i n e d
a canonical : 0
by
of this
This
is c a l l e d
HI(R)
surface
we d e n o t e
group
1-simplex
surface
of the g r o u p
1-dimensional
By IC the
homology
oriented
is c a l l e d
the
33B).
polyhedron,
on the
i
intersection
HI(R) I,
HI(R) , w h i c h
A finite ai,
and Ch.
Every
onto
by i
the
a regular
a single
1-dimensional
HI(K)
HI(K).
3
R
be the
Ch.
of
labeled
of
as an o r i e n t a b l e
([AS],
Thus
we m e a n
subregions.
group
as a s i n g u l a r
isomorphism
R has
surface
of c a n o n i c a l
HI(K)
an i s o m o r p h i s m
in
R \ D
be a R i e m a n n
can be r e g a r d e d Let
of
Groups
homology
= K(R).
l
(sub-)region
component
The H o m o l o g y
a × b
Pn+l
a subdivision
consisting
singular R
of
bordered
A finite
(i)
of c a n o n i c a l
I,
29A)
Corollary.
2.
of
polyhedron. if
Ch.
It is a f i n i t e
or c o m p a c t
is i n f i n i t e
}"
be an o p e n
By a c a n o n i c a l such
K \ P {Pn n=l
([AS],
polyhedron.
subcomplex
exhaustion
R
K = K(R)
is a c o m p a c t
of
simplex
Let
by
be an o r i e n t a b l e
sequence
border
= K(R)
R
a canonical
a canonical
Theorem.
Ch.
if
component
increasing
we d e n o t e
is an o r i e n t a b l e
only
is c a l l e d every
which
of c y c l e s sequence
in
by K,
a m. × a . 3
if
i ~ j, d e n o t i n g
by
]
of i - c h a i n s
a
and
b
([AS],
Ch.
I,
3iA). If hedron which
R
is a c o m p a c t
and t h e r e forms
exists
a basis
for
surface,
then
a canonical Hi(K).
K
is a f i n i t e
sequence
Hence,
ai,
d i m Hi(R)
bi,
orientable
poly-
i = 1,...,
g,
= d i m Hi(K)
= 2g.
The number If Cq_l,
g
R
q ~ i, then there exists in
i = i,..., of
is called the genus of the surface
is a compact bordered surface with
Hence,
The number
2C.
a canonical
contours
CO,... ,
sequence
ai, bi,
g, which, t o g e t h e r with all but one contours,
HI(K).
31D).
K
R.
q
dim HI(R) g
= dim HI(K)
= 2g + q - i
is again the genus of
Finally let
R
([ASJ, Ch. I,
R.
be an open surface,
so that
K
is an orient-
able open polyhedron.
Let
closure
is r e g a r d e d as a compact b o r d e r e d surface,
CI(D)
of
D
D
forms a basis
defines a finite p o l y h e d r o n sion to of
K.
K
be a r e g u l a r subregion of
K(CI(D)).
K(CI(D))
So we have a natural h o m o m o r p h i s m of R \ D
it
is a subcomplex
HI(K(CI(D)))
into
HI(K).
are compact, we see that the h o m o m o r p h i s m
is in fact an i s o m o r p h i s m and therefore that fied with a subgroup of
Since the
By applying a suitable subdivi-
if n e c e s s a r y we may assume that
Since no components of
R.
HI(K).
HI(K(CI(D)))
Turning to the region
is identi-
D
itself, we
have Theorem.
Let
D
be a r e g u l a r subregion of
is regarded as a subgroup of with one in In case that
HI(D)
HI(R)
R.
Then the group
HI(D)
by identifying every 1-chain in
D
R. D
is a canonical
subregion of
R, it is seen m o r e o v e r
is a direct summand of the free abelian group
HI(R).
See
[AS], Ch. I, §§31-32 for a d e t a i l e d discussion.
3.
The Fundamental Group 3A.
Let
mental group
0
be a point in
R, which is held fixed.
F0(R) , r e f e r r e d to the "origin"
The funda-
0, is defined to be the
m u l t i p l i c a t i v e group of h o m o t o p y classes of closed curves issuing from 0
([AS~, Ch.
I, 9D).
Every closed curve
as a singular 1-simplex. onto
y
from
the c o m m u t a t o r subgroup
phism of
y
Fo(R)/[Fo(R)]
[F0(R)]
of
F0(R).
By a c h a r a c t e r of an abstract group G
into the circle group
plex numbers of modulus one).
of
HI(R)
F0(R)
([AS], Ch.
G
F0(R)
to its h o m o l o g y class.
Under the natural h o m o m o r p h i s m the h o m o l o g y group
isomorphic with the quotient group
3B.
can be considered
We thus get a natural h o m o m o r p h i s m of
HI(R) , which takes the h o m o t o p y class of
Theorem.
0
is
modulo
I, 33D)
we mean any h o m o m o r -
(= the m u l t i p l i c a t i v e group of com-
The set of all characters of
G
forms
a group group by
with
thus
G*.
The
F0(R)*.
Let
such
§2.
4.
4A.
Let
s(z)
on
a
such
D
s
4B.
exists D;
and a
on
(ii)
on
an
s3
for
D, t h e r e
z
D
and
s(a)
=> ~
120
V
S
(i)
with
s
in
S
exists
an
s'
in
V; and
s
S.
A collection
if
-S = {-s:
tions.
The
character
surface
and of
every
F0(R).
reason
surface
An
extended
if
(i)
if
with -s
S
s E S}
pair
S
such
are
is g i v e n
V
S
has s"
and
with
A
A function
subharmonic.
on
Sl,
~ s3(z)
D
is c a l l e d
s2
in
for
disk
[e i t - z~
V
S
all
there z
with
in CI(V)
dt
a subharmonie
on
D
such
subharmonic
useful
by the
disk.
that
is a P e r r o n very
unit
functions
parametric
s(elt)Re
0
and
of e l e m e n t s
every
of
disk
is s u p e r h a r m o n i c .
superharmonic
and
(iii)
-~ <
semicontinuous;
the o p e n
m ~ n { s l ( z ) , s2(z)}
function
families
R.
superharmonic
of s u p e r h a r m o n i c
for e v e r y
S
Perron
Riemann F0(R)
a parametric
is i d e n t i f i e d
in
tions.
some
of
is l o w e r
exists
is s u b h a r m o n i c
a subharmonie
in
with
s(reit)dt
if it is b o t h
if
s
~ D
exists
family
(ii)
CI(V)
every
in
of
is c a l l e d
there
' s (z) ~ ~
for all
The
is d e n o t e d
isomorphic
of an o p e n
is a s u b g r o u p
D
A collection family
is
and
2C we h a v e
in a R i e m a n n D
s ~ +~;
in
that
is h a r m o n i c
a Perron
G
THEORY
s
0 < r ~ i, w h e r e
function on
of c h a r a c t e r s .
of
HI(R)*
in
subregion
F0(D)
be a r e g i o n
D
every
center
for
D
for
that
remark
group
Functions
function
~ +~
(iii)
shows
last
multiplication
character
is the r e s t r i c t i o n
POTENTIAL
Superharmonic
real-valued
the
Then
F0(D)
CLASSICAL
the
be a c a n o n i c a l
0 E D.
of
pointwise
theorem
with
D
that
character
to the
is c a l l e d
preceding
Combined
Theorem. R
respect
obtained
mlnorant,
that
s > s"
functions
family
of
on
there all
is a P e r r o n
superharmonic
in c o n s t r u c t i n g
following
D
i.e. for
harmonic
funcfunc-
Theorem.
Let
and set D.
S
u(z)
be a Perron fdmily of s u p e r h a r m o n i c functions on
= inf{s(z):
Then
u
D
is a h a r m o n i c f u n c t i o n on
([CC], p. 14)
4C.
In particular,
s u p e r h a r m o n i c majorant, on
s E S}.
D, then the set
if a subharmonic f u n c t i o n
i.e. a s u p e r h a r m o n i c f u n c t i o n
Su
of all s u p e r h a r m o n i c m a j o r a n t s
Perron family and the m i n i m u m element ceding theorem,
u
in
on
D
s
with of
has a s ~ u
u
forms a
Su, which exists by the pre-
is the least h a r m o n i c f u n c t i o n that m a j o r i z e s
u
on
D.
This is called the least h a r m o n i c m a j o r a n t of
u
LHM(u).
Then the p o i n t w i s e max-
imum
Let
uI
max{ul,
and
u 2}
superharmonie)
on
u2
D.
So, if
superharmonic majorant
5.
uI v u 2
max{ul,
void.
(resp.
Let
D
be a r e g i o n in
the set of s u p e r h a r m o n i c
is bounded below;
(ii)
min{ul,
R, whose b o u n d a r y
u2}) has a
then it has the
-S(-f;D). H[f;D]
of functions in
H[f;D])
in
S(f;D)
S(f;D)
and
s"
so that
numbers,
then
If
and
in
~D.
A function
S(f;D)
f
fl' f2
~ifl + ~2f2 ,
both
on
~D
D
on
H[f;D]
R
which
~D, we denote by
~
supremum)
s' ~ s" S(f;D)
on
D
for every and
S(f;D)
are h a r m o n i c on
D
is called r e s o l u t i v e if H[f;D]
= H[f;D].
The
and is called the S o l u t i o n
el' ~2
and
=
are nonvoid and let
are r e s o l u t i v e and f2 )
s
(iii)
S(f;D)
f.
max~fl,
(i)
denotes the R; and
with the b o u n d a r y data ~D
is non-
such that
(resp.
H[f;D]
are nonvoid and
in
We set
Since
and
r e s o l u t i v e and satisfy the following, H[.;D]:
D
S(f;D)
S(f;D),
H[f;D]
of the D i r i c h l e t p r o b l e m for (a)
in
S(f;D)).
common f u n c t i o n is then denoted by
Theorem.
a
S(f;D)
(resp.
and every
H[f;D] ~ H[f;D].
on
on
be the p o i n t w i s e infimum
S(f;D)
are Perron families,
f
s
c o m p a o t i f i c a t i o n of
for every
Suppose that both
(resp.
function
functions
~D
lim i n f D ~ z ÷ ~ s(z) ~ 0, where
lim infD~z÷ a s(z) ~ f(a)
of
(resp.
(resp.
u I A u2).
point at infinity of the o n e - p o i n t
both
u 2}
is subharmonic
(resp. the g r e a t e s t h a r m o n i c minorant),
For every e x t e n d e d r e a l - v a l u e d
~(f;D)
and
u2])
The D i r i c h l e t P r o b l e m 5A.
s'
D.
min{ul,
(resp. a subharmonic minorant),
least h a r m o n i c m a j o r a n t is denoted by
be h a r m o n i c on
(resp. m i n i m u m
and is denoted by
min(fl,
f2 )
in which we write
are real
are also
H[.]
in place
H I , i f I + ~2f2 ] = ~ i H [ f l ] + ~2H[f2 ], H[max{fl,f2}] (b)
Let
on
8D
with
the
sequence
: H[f I] v H [ f 2 ] ,
{fn}n~l limit
H[min{fl,f2}]
be a m o n o t o n e
sequence
= H[f I] A H[f2].
of r e s o l u t i v e
functions
f = lim
f . Then f is r e s o l u t i v e if and n n c o n v e r g e s . If this is the case , t h e n
{H[fn]} n:l ~
only
if
H[f]
= lim n H[fn]. (c) included and
Let in
f D
be a r e s o l u t i v e and
= H[f;D]
on
define DA
f'
~D'.
function
on
~D'
Then,
on
by
SD.
Let
D'
f'
= f
setting
H[f';D']
= H[f;D]
on
be a r e g i o n on
~D n ~D'
D'. ([CC],
5B.
A point
real-valued
a
in
function
~D
f
is c a l l e d
on
f
is c o n t i n u o u s
at
in
SD
superharmonic
a, t h e n
in
~D
if
(i)
neighborhood Theorem. Then
the
Let
The
(b)
of D
every
bounded
inequality
regular
on
D
= 0
and
: f(a).
is c a l l e d
is c a l l e d (ii)
implies
irregular.
a barrier
A positive
for a p o i n t
i n f z e D \ V s(z)
> 0
for
a every
a.
be a r e g i o n
in
R
statements
are
equivalent:
point
a
There
exists
There
exist
is a r e g u l a r a barrier
and
let
a
boundary
be a p o i n t
point
of
a
with
for the p o i n t
in
~D.
D. respect
to the
D.
(c) harmonic
function
If the then
s
this
: lim H [ f ; D ] ( z ) z÷a
is not
l i m z ÷ a s(z) V
folZowing
(a)
region
which function
for
~ lim sup H [ f ; D ] ( z ) . Dgz÷a
lim H [ f ; D ] ( z ) z÷a A point
if,
22)
~D,
lim sup f(b) ~Dgb÷a If
regular
p.
a
5C. constant Theorem. tinuous
u
on
connected
is a r e g u l a r
A region positive If
D
function
a neighborhood V nD
such
component boundary
D
in
R
of point
V that ~D of
is c a l l e d
superharmonie
function.
is a h y p e r b o l i c
region
on
~D
of
is r e s o l u t i v e .
a u(z)
and ÷ 0
containing D.
([CC],
hyperbolic
in
R, t h e n
([CC],
a positive
p.
as
super-
z ÷ a.
a
is a c o n t i n u u m ,
p.
23)
if it c a r r i e s
every 27)
bounded
a non-
con-
5D.
Let
D
be a h y p e r b o l i c region in
R
the set of all r e a l - v a l u e d bounded continuous is a linear space over
~
p l i c a t i o n of functions. the s u p r e m u m n o r m every
f
in
function
H[f;D]
on
on
on
D.
functions on
ZD.
be This
It becomes a Banach space if we equip it with If(b)l.
By the p r e c e d i n g t h e o r e m
is r e s o l u t i v e and thus determines a h a r m o n i c D.
In view of Th.
Cb(~D,~)
5A, the map
f + H[f;D]
is a
into the space of bounded h a r m o n i c functions
D, which is o r d e r - p r e s e r v i n g , 0
Cb(~D,~)
under the usual a d d i t i o n and scalar multi-
llffl = suPbE$ D
Cb(~D,~)
linear map from
and let
i.e.
For every fixed point
a
is a bounded linear functional on
f ~ 0 in
D
Cb(~D,~)
on
~D
implies
the map with
H[f;D]
f ÷ H[f;D](a)
rH[f;D](a) i ~ JJfll .
By Riesz's r e p r e s e n t a t i o n t h e o r e m there exists a unique n o n n e g a t i v e D ~a' on ~D such that
regular Borel measure,
(i)
H[f;D](a)
= I
f(b) d ~ ( b ) ~D
for every H[I;D]
f
< i
in
Cb($D,~)
with compact support.
on
~D
solutions,
~D(~D)
The inequality
It may h a p p e n that the Dirichlet D p r o b l e m has only the trivia] solution. In that case the m e a s u r e s wa vanish i d e n t i c a l l y for all a in D. When the Dirichlet p r o b l e m has nontrivial
shows that
< I.
the measure
Da
is called the harmonic m e a s u r e
at the point
a
(with respect to the r e g i o n
A function
f
on
Theorem.
~D-summable. a
~D
is r e s o l u t i v e
D).
if and only if it is
If this is the case, then the equation
(I) holds.
([CC],
p. 28) We now slightly extend the d e f i n i t i o n of
H[f;D].
Namely,
be an extended r e a l - v a l u e d
function defined on a subset of
the b o u n d a r y
f0
We call
f
~D
and let
be the r e s t r i c t i o n of
r e s o l u t i v e with respect to
sense d e s c r i b e d above,
i.e.
f0
is
D
if
f0
H[f0;D]
the b o u n d a r y data
6.
H[f;D]
f
to the set a
~D.
in the
in
D.
to denote
of the Dirichlet p r o b l e m for the region
D
with
f0"
Potential Theory 6A.
Let
let
including
is r e s o l u t i v e
D - s u m m a b l e for some ~a
If this is the case, then we again use the symbol the solution
f
R
ga(Z)
In the rest of §2, = g(a,z)
R
denotes a h y p e r b o l i c Riemann surface.
be the Green function for
This is c h a r a c t e r i z e d by the following
R
with pole
a
in
R.
Theorem.
For e v e r y
harmonic
function
(AI) harmonic z
in
in
R
in any p a r a m e t r i c function
V, w h e r e (A2)
for
ga : H [ g a ; D ]
6B. we
a
u V
on
every on
V
exists
satisfying disk
V
subregion
center
the
of
R
positive
super-
conditions:
ga(Z)
with
D
a unique
the
with
such that
is i d e n t i f i e d
a
there
exists
= - l o g Izl + u(z)
open unit with
disk
< i};
we h a v e ([CC],
For a n y g i v e n
finite
positive
regular
f : | g(z,w) JR
d~(w)
Borel
a
f o r all
{Izl
a ~ CI(D)
D.
measure
p.
~
32)
on
R
set
U~(z)
for
z
in
R.
everywhere
We c a l l
infinite.
function
on
Moreover
we have
Theorem. only
if
does
not
A subset
U~
E
of
on
E.
A countable a condition
a subset
A
of
R
condition
holds
on
Theorem.
Let
u
A
If
U~ £ u R.
As
exists
sets
points
on t h e
closed
D
R
if a n d
potential
set
if t h e r e to
is
exists
+~
E ~ A
a
identi-
a polar
(abbreviated
of
Z.
35)
is a g a i n
set
of
in
Every
p.
it is
superharmonie
support
is e q u a l
superharmonic
p.
~, u n l e s s
set
~.
a polar which
a polar
at t h e
q.e.
([CC],
of
([CC],
of p o l a r
be a p o s i t i v e
on
R
closed
quasi-everywhere
except
u
6D.
on
union
if t h e r e
support
is c a l l e d
holds
a potential. everywhere
R
function
the
o n an o p e n
measure.
by
is a p o s i t i v e
outside
the
positive
generated
U~
is h a r m o n i c
intersect
superharmonic
say that
potential
is h a r m o n i c
by a u n i q u e
6C. positive cally
R, w h i c h
D
it t h e
So a p o t e n t i a l
A potential
generated
We
there
z + ga(Z)
set.
to q.e.)
such that
on
the
E. function
support
on
of
R
and
U~
~, t h e n
U~
we h a v e
the
37)
f o r the r e g u l a r i t y
of t h e
Dirichlet
problem
following Theorem. set.
Then
([CC],
p.
6E. u
on
R
Let
D
the
be a r e g i o n
irregular
in
boundary
R
such that
points
of
R\ D
D
is n o t
form a polar
a polar set.
42)
For a subset
E
we
function
define
the
of
R
and
a positive
R[u;E]
on
R
superharmonie to be t h e
function
pointwise
infimum
of p o s i t i v e
u(z) The
on
E.
(resp.
We R uE
function
Let
function
on
(a)
v
H[u;R\E] points
of
is not
R
of
be a c l o s e d
u
set
v = u~.
R\ E
s
on
R
such
that
s(z)
and to
relative in
Then
R,
the
u
on
E
E.
a positive
following
function
u
to
on
superharmonic
hold:
R, w h i c h
except
R.
at the
is e q u a l
irregular
to boundary
R \ E. is the
smaller If
6F.
smallest
than E
Theorem.
Every as the ([CC],
q.e.
positive on the then
is d e t e r m i n e d
Finally
uniquely
u
is c o m p a c t ,
E, w h i c h
R.
function)
and
functions
u~(a) = lim inf R[u;E](z) for all a in m z÷a R [ u ; E ] ) is c a l l e d the b a l a y a g e d f u n c t i o n
is a s u p e r h a r m o n i c
v
(e) on
E
on
(b)
§3.
set (resp.
the r e d u c e d
Theorem.
on
superharmonic
we
state
positive
set
uniquely.
the
for
some
([CC],
decomposition
superharmonic
function
on
R
that
E.
v : U~
sum of a n o n n e g a t i v e p.
superharmonic
p.
nonnegative
theorem
function harmonic
measure
43)
on
of F. Riesz: R
can be w r i t t e n
function
and
a potential
41)
DIFFERENTIALS
7.
Basic 7A.
Definition Let
R
be a R i e m a n n
differential
~
b dye
(resp.
2-forms
local
variable
are
on
= x
z
complex-valued
disks
Ve
and
R
is d e f i n e d c dx dy + lye, "
functions
V6,
surface.
on
for
that
with
each
(i)
z (V)
respectively
(resp.
as a c o l l e c t i o n
), one such
A first
of 1 - f o r m s
parametric
a~
and local
second)
and
(ii)
b
a dx
disk
V
(resp.
for any
variables
order
z~
two
+ with
c a)
parametric
and
z6,
we
have ~x a ~
aB : on
V
8x
~xB
N V 6.
(resp.
+ • ~Y~ D~Z-~6' Such
cdxdy).
a differential A differential
(or a c k - d i f f e r e n t i a l ) , are of class Basic as
follows:
~(x,y)
~ + b ~Y~ b8 = a ~ Y 8 ~YB
k : 0,
(resp.
on
i,...,
R
) = c~(xB'Y~)
is e x p r e s s e d ~
cB
symbolically
is said
if all
the
as
adx + bdy
to be of c l a s s coefficients
Ck
of
C k.
operations
on f i r s t
order
differentials
~ = adx + bdy
are
10
(a)
multiplication
(b)
complex
(c)
conjugate
differentia3:
(d)
exterior
differentiation:
is of class (e) for
b.dy 3
e x t e r i o r product: j = i, 2.
~b/ax
7B.
order
for
Let are
be a first
y
function
assumed
value
of the
each
being
arc.
borhood,
V
R.
result ~
independent arc
on
with
The defined
being
y
integration similarly.
value
again
borhood,
then
the
of line
ease
~3.
3
:
a . d x +
if
dm = 0,
(~f/~x)dx +
follows, Let
arc
variable
and
local
y
arcs
and
~ = a d x + bdy is i n c l u d e d
z = x + iy the
and
in
is
integral
fy m
subdivision
order
coordinate
of s u b a r c s and we
neigh-
yj
so that
The
integral
set
we choose.
by l i n e a r i t y . C0-differential
be a s i n g u l a r
coordinate
is d e f i n e d
number
parametrization
Yj
1-chain
A
and
in a s i n g l e
neighborhood
of the
let
(t))dt,
variables
a finite
of a s e c o n d
~ = edxdy
2-simplex
neighborhood
V
by a d i f f e r e n t i a b l e
with
map
in
local
(t,u)
is
R.
If vari-
÷ z(t,u),
we d e f i n e
ff A the
in w h a t
0 £ t £ i, t h e n
D
to any
Namely,
0 £ u £ t £ i, t h e n
parametrization.
(=
smooth.
If the
included
coordinate
in a s i n g l e
z = x + iy
R.
if
to be c l o s e d
~ : df
+ b(z(t))
into
independent
extended
it is i n c l u d e d able
when
C 2.
and
local
of b o t h
is not
we d i v i d e
is t h e n
if
Here
Y
of
is said
exact
= x(t) + iy(t),
is in a s i n g l e
the
~a/~y)dxdy
formula
If the
then
yj
f~ = (fa)dx + (fb)dy;
a2bl)dXdy
-
of c l a s s
(a(z(t))at(t)
the
~
f
cl-differential
by the
(alb 2
:
to be p i e c e w i s e
neighborhood t ÷ z(t)
is d e f i n e d
~i~2
be an arc on
order
by
d~ = ( $ b / ~ x -
It is c a l l e d
some
always
a coordinate defined
f:
9" = -bdx + ady;
cl-differential
= ~a/ay.
($f/~y)dy)
1-chains
functions
~ = a d x + [dy;
CI;
A first i.e.
by n u m e r i c a l
conjugation:
being When
we h a v e
m =
ff O £ u £ t £ 1
independent A only
integrals,
is not
.
c v z ) ~
of the
the
choice
included
to a p p l y
dtdu,
a suitable
result
of
local
in a s i n g l e
being
variables
coordinate
subdivision
independent
of
to
A
and neighas
in
subdivision.
11
The integral of
~
over any singular
arity, where each simplex definitions
any
first
8.
The Class 8A.
order
Let
+ Ibl 2) dxdy
cl-differential
on
R
and
any
singular
and its Subclasses
~
be a first order cl-differential.
II~II = II ~ * F I : FI(R)
with
function
co
is a second order cl-differential.
We denote by
2-chain
×,
~*
= (lal 2
Then
We set
= II (lal2+ IbI2)dxdy"
the totality
11~ll < ~.
(2) defines
With these
formula
F
(2)
co
is assumed to be differentiable.
we have the Stokes
for
2-chain is then defined by line-
Then
a norm.
F1
of first order cl-differentials
is a linear space,
Indeed,
in which the
this norm is induced
from the
inner product (3)
(~I'~2)
for
~i' ~2
in
F I.
For a set
the set of conjugate in
FI
(resp.
if
analytic)
We denote by
d~ = 0
differentials
FI
(resp.
8B. face
FI(R)
belongs
the bomder in
C2
R
Theorem. (resp.
the class of closed
is the interior of a compact bordered
sur-
(resp.
F I.
R
is the set of are of class
have the obvious meaning.
C I up
We say
e
and that
with
f = 0
~ on
F~0(R) belongs
~R.
(3), which defines
FI(R) *) in
FI(R)
whose coeffieients
FI(R)
to the class
F~0(R) C
It is
dif-
on
and
DR
inner product
are closed.
exact)
C
f
FI
to the class
first order differentials m
~*
A*
A differential
The set of all harmonic (resp. FI). is denoted by F hi a
Then we use the following notation:
to the border. that
and
A.
co* = -i~. in
F I)
~
we denote by
in
e
belonging
Suppose that
R.
of differentials of elements
if both
and
C
ferentials
A
differentials
is called harmonic
called analytic
= IS ~I~2"
(resp. FI(R).
if
~ • F~(R)
and
~ = 0
along
to
FI~(R) if ~ = df for some eu i The class F (R) is equipped with the the o r t h o g o n a l i t y
F~0(R)) ([AS],
relation there.
is the orthoeomplement Ch. V, 5A)
of
FI(R)*e
12
8C.
If
R
is an o p e n
Riemann
F~0(R)
(resp.
compact
support.
In this
Theorem.
FI e0 in
is o r t h o g o n a l
of
F e0 I *
norm
FIe0 : F~0(R))
FI .
ease
([AS],
8D.
We d e n o t e
(2),
so that
by F
the
F
fundamental
Theorem.
the
If
result
BE. shall
Among
use the
direct
basic
sum in the
(4)
and
formulae
following
to h a v e
hood
define
respect Fe
to the
CI(FI), e
=
Fe0 the
Fh
is the
%
c* '
following Fhl
such
([AS],
decomposition
denotes
F
the
that
Ch.
of
V,
9A)
F, we
orthogonal
= re0
re0 ~{
•
we h a v e
If a f i r s t V
order
Cl(rl).
:
([AS],
Ch.
V,
10C)
C
if a.
cl-differential,
of a p o i n t
a singularity
of
FI = cO with
and D i f f e r e n t i a l s
neighborhood
harmonic)
We
with
there exists a ~i in i Fh can be i d e n t i f i e d .
C
9A.
FI
class
in w h i c h
r
Cycles
F~)
is the o r t h o c o m p l e m e n t
of
space.
the
~ rc
(5)
9.
by
(resp.
F:
r = Fe0
As a c o n s e q u e n c e ,
FI c
for o r t h o g o n a l
later,
space
we d e n o t e FI c
: (Fe*) ± , w h e r e the c l o s u r e and in the space F. We set Fh = F c n
, then
Fh
in
Fc0
concerning
~ E Fc~Fc*
and
completion
is a H i l b e r t
~lll = 0; n a m e l y ,
lJw-
F I* e 6C)
V,
= CI(F ~0 ) , F c : (Fe0*) ± , and orthocomplementation are t a k e n The
then
~
we have
to
Ch.
surface,
set of
~
at
a
a.
is a n a l y t i c
It is c a l l e d
in The
R
say
except
singularity
(resp.
removable
R
is d e f i n e d
a, t h e n
is c a l l e d
harmonic) if
~,
at
in some
~
analytic
deleted
is c o n t i n u e d
in a is said (resp.
neighbor-
to the
point
a
as a c l - d i f f e r e n t i a l . Take
a parametric
consider
a holomorphic
fdz
some
for
local
variable
disk
function
The
set
~a(~)
order
on f
on
about
a point
V \ {a}. V \ {a},
a
in
So we h a v e i.e.
in t e r m s
R
= inf{k:
c k ~ 0}
is i n d e p e n d e n t
of the
[
ckzk,
and call choice
9 =
0 < Iz[ < 1. it the
of local
order
of
variables.
~
at
and
of the
we h a v e
f(z) : We
< i}
differential
holomorphie z
V = {Izl
a.
Moreover,
13
the c o e f f i c i e n t the
C_l , the r e s i d u e
local v a r i a b l e s
and is d e n o t e d
Resa(~) for
any
point
cycle a.
0.
The
ential
on
R
V
by
a
Res a (~). = ~
is
subset
with
In fact,
number
1
removable
of
we h a v e
with
if
and
If
~
only
if
such t h a t
the
Va(~) cl-differ -
singularities exists
to
may be con-
is a c l o s e d
R, t h e n t h e r e
singularities
respect
singularities
of a n a l y t i c
of
independent
y
fact:
with a finite number
T
a, is a l s o
with prescribed
of the f o l l o w i n g
differential
at
winding
at
off a compact
~
= C_l
having
differentials
by m e a n s
holomorphie monic
in
singularity
Analytic
structed
Ch.
y
of
and is
a unique
T - ~ E Fe0
har-
([AS],
V, 17D).
9B. p, q
We c o n s t r u c t
be two d i s t i n c t
Suppose metric
first that t h e s e disk
positive Let
v
V = {Izl
numbers
e ~ i
define
p,
rl, r 2
= d(ev)
we use the r e s u l t T - ~ E Fe0.
q
q
for
and
and
which
c
and
to c y c l e s
an arc
I~lJ,
I~2[
of the f u n c t i o n let
e
E 0
on
and c h o o s e
log{(z-~2)/(Z-~l)}
R \ {Izl
on
< r2}.
= 0
R
such
F u r t h e r we
otherwise
y
in
p
for
R.
Then
~
with
differential
not p a s s i n g
T = 2~i(c x y).
I
Let q.
< r I < r 2 < i.
be a C 2 - f u n c t i o n
Izl < I, and
1-cycle
R. to
~ = { ( z - ~2 )-i - ( z - ~ l ) - l } d z
by s e t t i n g
for any
on p
in a s i n g l e p a r a -
~2 = z(q),
in 9A to find a u n i q u e h a r m o n i c
Thus,
joining
are c o n t a i n e d
satisfy
and
rI £
related c
~i = z(p),
branch
{IzI £ r I}
a differential
R
Set
r I < Izl < i
on
Izl < rl,
in
< i}.
be a s i n g l e - v a l u e d
in the a n n u l u s that
some d i f f e r e n t i a l s points
and
q, we h a v e
([AS],
Ch. V, 19C)
Y If metric
p,
j = i,..., within Tj T and
q
disk,
and
c
n, so t h a t
a parametric
for e v e r y
are not n e c e s s a r i l y
t h e n we d i v i d e
j
is a h a r m o n i c
each
number
of s u b a r c s
cj,
ej
joins a p o i n t
Pj-I
to a p o i n t
pj
For e v e r y
P0 = p
and set
differential
T - ~ E Fe0.
in a single p a r a -
into a f i n i t e
disk with
as a b o v e
contained
c
with
1-cycle
and
Pn = q"
~ = [j ~j
and
singularities y
We d e f i n e T = [j ~j.
o n l y at
not p a s s i n g
p
~j
and
any of the
and
Then q, pj's,
we h a v e
I
T = I "f
The d i f f e r e n t i a l
y T
Q = [ I ~. = [ 2~i(c. x y ) = J Y J j is seen to d e p e n d
2~i(cx7).
o n l y on the h o m o l o g y
class
of
c.
14
We w r i t e
T(c)
~(c) Then,
in p l a c e
¢(e)
= ~ ( c ) + ~--~-~. at
p
The
We
can
We
with
e
has
iT--~*)/2.
differentials
only
-i
set
: (T--~+
analytic
¢(c)
construction
our
works
~(e)
definition
Suppose
Moreover,
to
we
~(c)
residues
by l i n e a r i t y .
C F h.
and
are
see that q
is a cycle.
T(c)
~(c)
differentials
extend
belongs
Further
on
R
two
singularities,
i
respectively,
and
and
T(c)
simple and
~(e)
holomorphic.
above
1-chains c
and
and
is e v e r y w h e r e
resulting
T.
: (T(c) + i T ( c ) * ) / 2
both
poles
of
Fe0 ,
that
of
T(c), has
~
belongs
in the
~(c)
%(e) this
since
T(e)
even
and
case
are %(c)
no
p = q
compact
to
F h N Fc0
the
and
to a r b i t r a r y
case.
has
then
holomorphic.
~(e)
singularities
is the
and
everywhere
if and
Then
support
¢(c) and
only
E Fa
since
if
and T(e)-
(= Fh0 , by d e f i n i t i o n ) .
By s e t t i n g
~(c) = !~T(e), we get the Theorem.
following If
harmonic
c
is a c y c l e
differential
on
o(c)
R, t h e n
in
Fh0
there
such
exists
a unique
real
that
(~,~(c)~) : Ic for
each
~
in
F . e
(6)
If
c
(~(c),~(y)*)
and
y
= I
are
~(c)
any
cycles
on
= c x y.
R, t h e n
([AS],
Ch.
V,
20)
Y iO.
Riemann-Roch 10A.
Here
Fix a c a n o n i c a l intersection n = i,..., harmonic
we
consider
basis
numbers g
(see
~(A n) m
a compact
of 1 - c y c l e s vanish
2B).
differentials
IB and
Theorem
except
By our
Riemann
An,
Bn,
the
cases
observation
and we h a v e
= A n × B m : @mn'
for all
IA
~(Bn) m
surface
n = i,...,
R
of g e n u s
g.
g,
for w h i c h
all
A n × B n = -B n x A n = i, in 9B m,
~(An),
~(B n)
n
= Bn × A m : -@mn'
are
15
S
A
Theorem.
(a)
a(A n)
and t h e r e f o r e (b) periods,
dim
a(An)
: I
o(B n) B
m
and
O(Bn) ,
= 0.
m
n = i,...,
g,
form a basis
for
Fh
F h = 2g.
dim
F a = g~ and
i.e.
(fA 1 ¢ .....
every fA
~
in
9).
Fa
([AS],
is d e t e r m i n e d Ch.
V,
by
its A-
24A-B)
g 10B.
A divisor
D
on
(7)
R
is a f o r m a l
finite
sum
D = n l a I + --- + nkak,
where
a. are p o i n t s J is c a l l e d a p r i n c i p a l funetion
at the
f,
i.e.
point
a,
in
R
and
divisor
D = (f)
n.
are
= ~aER
Va (f)a'
to be
inf{k:
is d e f i n e d
integers.
if it c o m e s
from
Such
a nonzero
where
Va(f),
c k ~ 0}
a divisor
D
meromorphic the
with
order
f(z)
of
f
=
~k ek(z - a)k" Let
D
divisors) tively. the
R.
The
makes
that
R. by
R
deg
function
We also
is a n o t h e r
(~)
on
for all
R
functions
f
dimension
of
divisor
meromorphic
of the
sueh
belongs
to
Hence
addi-
group
form
(7)
function
sphere,
that
we
deg
on
on see
is a
= (~'/~)
of
D2
L(D)
that
(7)
(f) by
defined
e'/e
E DO.
the
D I- D 2 space
by If
Thus,
(~)'s
belong
class.
integral
if
n.j => 0 For
is i n t e g r a l .
of all m e r o m o r p h i c
is a m u l t i p l e dim D, w h i c h
~
in 9A.
is a m e r o m o r p h i e
canonical
is e a l l e d
if the
differential
of
D.
depends
The
only
complex
on the
D.
divisor
~(D)
class
of the
Riemann
was
then
called
form
by
is d e n o t e d
D
in
differentials
a fixed
class
denote
R
L(D)
we t a k e
Z = (an).
we
~a(~)
differential, (e') - (~)
D
D
principal written
D/D 0 .
of a m e r o m o r p h i e
divisor
divisor
therefore
where
is a m u l t i p l e
of
of the
and
divisor
D
every
DO
ma (~)a'
on
class
For
group
so t h a t
DI
surface
in
group
meromorphic
the
same
divisor
nonconstant
= [aER
A divisor j.
D
meromorphie
and t h e
10C.
quotient
define
~'
covering
every
the
D, of a d i v i s o r
every
(resp.
Abelian
is c a l l e d
deg
Since
divisors
is a free
D/D 0
degree,
for
set of all
DO)
group
a complete
D = 0
formula
every
The
on t h e
funetion
(resp.
[j n..3
the
to one
D O ) be the
D
quotient
surface
is d e f i n e d R
(resp.
on
nonzero if and dim
e
D
we d e n o t e
such
meromorphic only
~(D)
that
(~)
by
~(D)
(~/~0)
= dim
( D - Z).
space
is a m u l t i p l e
differential
if
the
s0
on
is a m u l t i p l e
of
of D.
If
R, t h e n of
D- Z
with
16
Theorem
(Riemann-Roch).
divsor
Z
For
every
D
in
D
and
every
canonical
we h a v e
(8)
dim D = dim
(-D-Z)
- deg
D - g + i. ([AS],
10D. = dim
By s e t t i n g
Fa = g
D = -Z
(see Th.
10A),
69) for
in
canonical
Theorem. pole
There
at a n y
other
Proof.
any
(8)
that
This,
together
with
(8),
implies
function
point
We c a n p r e s c r i b e
in
R.
([AS],
further,
be a n y
dim
~(0)
in
Ch.
J
subset such
from
we h a v e
V,
f
which
has
the
a simple
location
of
28B)
we n e e d
infinite
a I .... , ag
funetions,
fact
27A)
Z = 2g- 2
Z.
as well.
J
the
a meromorphic
al,... , ag
Take
by
f
Let
points
constant + i
of
To p r o c e e d
Theorem. tinct
exists
prescribed
poles
10E.
divisor
using
V,
we have
deg each
(8) a n d
Ch.
J.
1 ~ dim
of
R.
that
Then
dim
Sinee
there
exist
9(al+.-.+ag) L ( - ~Ij~s-
(-~j~l- a~)j : d i m
dis-
= 0.
a.)~o c o n t a i n s ~(~j~l- a~)j + s - g
and t h e r e f o r e s
(i0)
d i m ~(
We now prove nothing first
the
to p r o v e ,
theorem
for
~(0)
then dim
by
_> g - s .
induction.
= F a = {0}.
If
g = 0, t h e n
Suppose
that
there
g > 0.
is
We n o t e
that dim
for
[ a.) j=l ]
each
a
in
g ~ dim
R.
~n fact,
(a 0 - Z)
= dim
(a 0 - Z) - deg
meromorphic the point conformally
( a - Z)
onto
~(a)
~ g- i
if t h i s
were
not
~(a 0) ~ d i m
(-a 0) - g + i = 2.
function a 0.
= dim
f
on
As n o t i e e d the
R
with
in 10B,
Riemann
Thus
sphere
F a = g. there
only
this
the
case
By
(8)
would
implies
that
g
some
dim
a0,
(-a 0) =
be a n o n c o n s t a n t
one pole--a
and thus
for
simple f
should
pole--at
would be
map
zero,
R
a
contradiction. Thus, take
for
a nonzero
s = i, w e h a v e
d i m ~ ( a I)
= g - I.
~i
Since
zeros
in
~(al).
the
of
If ~i
g > i, t h e n w e is f i n i t e
in
17
number
and
J
is i n f i n i t e ,
we can find
a2
Then
d i m ~ ( a l + a 2) ~ d i m 9(a I) - i = g - 2.
gives
us
d i m ~ ( a l + a 2) : g - 2.
f i n i s h t h e proof.
10F.
Let
..., ag aj,
in
91,... , %g R
g.
ii.
Cj : fjdz
Then
Cauchy IIA.
{Aj, Bj: R 0 : R\
and
Kernels Let
R
in w h i e h
the
is c l e a r
of
dim ~(al+...+a (fj(zk))
}l(a2) (i0),
~ 0.
this
this a r g u m e n t
to
F a.
g
from the d e f i n i t i o n s .
Take d i s t i n c t
disk
{Vj,
) = 0
z}
points
al,
for each p o i n t
if and only if
~ 0,
z k : z(ak).
on C o m p a c t
Bordered
Surfaces
be a c o m p a c t R i e m a n n
j = i,..., {%gl(Aj
which
one p a r a m e t r i c
det where
with
We h a v e o n l y to r e p e a t
be a b a s i s
and c h o o s e
j = i,...,
J
[]
We add one m o r e r e s u l t ,
Theorem.
in
Combined with
g}
be a c a n o n i c a l
UBj)}.
R0
surface basis
can be a s s u m e d
single boundary
contour
of g e n u s
g
of 1 - c y c l e s
on
and let R.
We set
to h a v e a c a n o n i c a l
form~
is of the f o r m
A I B I A ~ I B ~ I . . . A g B A - I B -I gg g' where
A[I (resp. ] g i v i n g the o p p o s i t e Let an are
tial and Fa
p, q e
in
¢(c) q.
B[ I) is the c u r v e o b t a i n e d f r o m ] o r i e n t a t i o n ([AS], Ch. I, 4OD).
be d i s t i n c t R0
on
joining
R
in 9B imply t h a t
p
q
and
with resides ¢ ( c ) - 91
is d e n o t e d
by
-i
p'
and
p'
A. and B.. Take ] ] an a n a l y t i c d i f f e r e n -
singularities
¢(c).
o n l y at
differential
The p r o p e r t i e s
of
_, r e s p e c t i v e l y - - a n d
has
p
¢i
in
¢(e)
has o n l y two p o l e s - - s i m p l e
is seen to be i n d e p e n d e n t
be a s i m p l e q'.
and
and
B.) by 3
not on any
to find a u n i q u e as
(resp.
poles
at
zero A-
of the c h o i c e
of
c
and
~p,q.
Then
is an a n a l y t i c at
R
and d e f i n e
(~(c) has
¢ ( e ) - 91
= ~p,q, y
So
10A,(b)
Next we t a k e d i s t i n c t
Let
q
the same A - p e r i o d s
noticed
periods.
in
to
as in 9B.
T h e n we u s e Th.
w h i c h has
points p
A. J
p, q, p' , q '
m = Cp,
q,
arc j o i n i n g ~
Let
p
to
is s i n g l e - v a l u e d
differential
q'.
points
Z0
on
R0 \ y
be the t o t a l
and
~ :
q
within
on
in
fz
R0 \ y
R0
and
set
9. R0
and not p a s s i n g
and t h e r e f o r e
with possible
~
singularities
sum of r e s i d u e s
(see 9A) of
only ~m
18 +
o v e r the r e g i o n (resp.
R 0 \ y.
right-hand)
Denoting
b a n k of
2~iE 0 = [ ] Since
¢(z +) - ¢(z-)
e q u a l to periods y'
%
joining
p'
¢~ + r ~R 0
We a l s o
and
~
to
E0 = R e s p , ( } m )
within
q
and
y
~y'
y'
Let
[
We d e n o t e
liB.
by
conjugate
of
R
@P,q
be a c o m p a c t R' (see
function
there
g' p o i n t s
dh
exist
has n e i t h e r
zeros
is
all the A-
if we t a k e any arc
- ~(p')
= [
%p,
y,
arcs on
R0
,q
,.
with
~y =
= I y CP',q''
bordered
= RU DRU~ [AS],
surface with nonvoid
the d o u b l e
Ch.
II,
3E).
In o r d e r to d e f i n e the C a u c h y k e r n e l meromorphic
because
side
Then
I y,
DR.
= ~(q')
be n o n i n t e r s e c t i n g
: q' - p'.
y, we h a v e
R 0 \ y, t h e n we h a v e
,(~)
Theorem.
Let
/3R0 {~ = 0
On the o t h e r hand,
the f o l l o w i n g
and
on
s e c o n d t e r m of the r i g h t - h a n d
So we h a v e p r o v e d
q- p
z
z ) the l e f t - h a n d
(¢(z+) - ¢(z-))w.
see that
+ Res
(resp.
J.y
vanish. q'
z
at the p o i n t
= 2~i, the
2%i fy ~. of
y
by
h
on
R', w h i c h
al,... , ag, nor p o l e s
in
at
of
R, w h e r e
boundary
R
is the
Let
g'
for
R, we t a k e a n o n c o n s t a n t
be the g e n u s
is h e l d fixed. R
Then,
of
R'.
by Th.
10E,
such that the d i f f e r e n t i a l
al,... , ag,
and
such that
d i m ~ R , ( a l + - . . + a g , ) = 0, where Let
~R,(.) {Aj, Bj:
such t h a t IIA.
denotes
the
space
j = l,...,,g'}
R 8' = R' \ { u j g I ( A j U B j ) }
We m a y also a s s u m e
that
dh
as w e l l as all the p o i n t s
Th.
1OA we c h o o s e
fA
9(-)
~n = 6mn
for
a basis
for the s u r f a c e
be a c a n o n i c a l
R 0'
R'
(see 10C).
basis
of 1 - c y c l e s
on
is a c a n o n i c a l
f o r m in the
sense of
contains
al,... , ag,
{~n: n = I,...,
m, n = i .... , g'
all the
zeros
and p o l e s
in its i n t e r i o r . g'}
of
R'
Fa(R')
We fix one p a r a m e t r i c
of
By use of such t h a t disk
m
{Vj, z} terms
of the
we w r i t e det
around
each of the p o i n t s
local v a r i a b l e s
z k = z(a k)
(hj(Zk))
~ 0.
for
Since
chosen
al,... , ag, as
k = i,..., d h ( a k) ~ 0
and e x p r e s s
}n = h n ( Z ) d z g', for
on e a c h
t h e n we have, k = I,...,
by Th.
%n
in
Vj.
If
10F,
g', we see that
19 @j(ak)/dh(a k) : hj(Zk)/dd-~hz(Zk) are well-defined
and that the matrix
$j (ak) ] j,k:l ..... g' is nonsingular.
So a basis
{~ n
:
n = i,...,
g'}
of
F (R')
is deter-
a
mined by the formulas ' ¢:(a~) ~ k:l dh(a k)
:
(li)
$
CJ for
j : i,...,
from
g'.
If we take three distinct
and draw disjoint
such that
2y' = p - p'
is holomorphic
R~ \ y".
p ~ q, q"
shows that
and
we set
z
F(p,q), q
and
by u s i n g
:
(12),
, q
in R~
p,
p'
IIA implies that
,, Sp, ,p'
defined by either
side of this equa-
and holomorphic
is holomorphic
Differentiation local variables
@q,,,q(p) = f(z,q",~)dz
3 Then,
is distinct
within the region
points
7"
in
jointly
of
is locally holomorphic C
which
in the form
R 0' \ y'
in F(p,q)
q ~ p'.
Cq,,q(p)
Denoting by tively,
in
It follows that
and
~y" = q - q", then Th.
p, Sq",q
we see that the function
p
y'
writing this
(12)
when
arcs
and
Sy, ~q,,,q : Sy,, ~p,,p.
tion,
q" E R N R 0'
We now fix a point
al, .. ., ag,.
R~ \ {q"}
~k
F
in
for
p
in
in p
and
with respect q
p
when and
q to
q ~ p, q".
q, respec-
and also
J we h a v e
3
J
fA +IIp •
IA
p'
.
q)d p!
J
=I
A. ~ ]
the last equality vanish.
As
p
1
q" Cp,,p d~ =
I
A. Cp''P = 0, ]
sign being valid because
is arbitrary,
we conclude
all the A-periods that,
of
for every fixed
$p,,p p
in
20
the region
R N R~,
fA ~q~q,,
(13)
'q
=
0.
J
A similar computation
shows that
Ip'
B. ]
'
B. ]
As we shall see below in IIC, an application
'P" of Th.
IIA easily
shows
that
f
(14) for
j = I,...,
g'.
@p, : -2~i @j B. 'P p' 3 Thus we have arrived at the following:
fB. ~q~q"'q :-2~i%j
(15) for
j = i,...,
g'
We finally set ~(p,q) Since
q"
and all
everywhere on
R
on
+i
Cauehy kernel, ~(p,q)
aj
at the point
we claim that,
q.
of the differential (13) follows
=
B. J
in
jointly
and
q ÷ ~q~(p,q)
(14) and
~q(~q"
'q
in
p
p, the function p
q q
has a simple pole
R 0'
in
along
A~~
easily that the period along any
by use of (ii),
~qm(p,q)
is holomorphic
To finish the construction
To see this , we fix
First,
B. J
p ÷ ~q,,,q(p)
for every fixed
the periods Secondly,
%q,,,q(aj)
is holomorphic
Moreover,
is single-valued. from
j:l R,
%q,,,q(p)
p ~ q.
~ ' ~q,,, dh q(aj)~j(p).
-
belong to
R, while
except at
with residue
= @q,,,q(p)
of the q ÷
and compute and A. J
B~. vanishes.
(15) we get
(P)) -
k=l
dh
(ak)mk(P)
~' ~j = -2~i[~j(p)
-
~-~(ak)~ k(p)]
: O.
k=l Hence,
~qW(p,q)
valued function.
has only null periods
and so
Summing up these observations,
which is the main objective
of this section.
q ÷ ~(p,q)
is a single-
we get the following,
21
Theorem. Riemann
There
(BI) tial
exists
surface
on
R
a differential
such
for e v e r y R
with
(B2)
q
only
R,
p
in
and
set
of
q ÷ f(z0, q)
is a m e r o m o r p h i c
with
residue
IIC.
within
the
verify
ourselves region
point,
distinct
b,
fB ~ p ' , p
in
To p r o e e e d
Aj,
Bj
except
B"
b"
A I.
= B \ B'
(i)
vertex
differen-
residue
variable
z
+i;
in a
z 0 = z(p);
having
a simple
let
V
then
pole
at
3B"
B,
at a s i n g l e
R~, (14)
slightly say
and
(ii)
is equal
B \ [b} to
show
~i"
be a p a r a m e t r i c
take
of
to
BI
curve, AI
of the p o l y g o n of
of g e n e r a l i t y ,
move
with
side
loss
p'
does
the
end p o i n t s
first
intersects
= -2~i 'P
CI(V)
We
closed
only
~p,
Without
a simple
left-hand
B
We t h e n
we h a v e
j = i.
B
the
containing
be the
case
we h a v e
further,
closure
B, r e s p e c t i v e l y , and
with
with
R
(14).
to o b t a i n
Then
f its
q
a local
on
equation
f r o m any
R~.
and t h e r e f o r e
such t h a t
is a m e r o m o r p h i c
pole--at
= f(z,q)dz
function
to the
R' \ y'
the c o n d i t i o n s :
entirely
simple
~(p,q)
the
satisfying
lies
bordered
+i.
We now
we r e s t r i c t
on a c o m p a c t
p ÷ ~(p,q)
R, we c h o o s e
neighborhood
p
p
in
one p o l e - - a
for e v e r y
~(p,q)
that
not m e e t small
point B'
arcs b
= b " - b'
and
A'
and
so that
disk
y'
the
B'
of
AI
and
in
= b' - b".
fact
at
all
contained
~B'
F r o m the
centered also
V.
b cycles and
Let
Thus,
B = B' + B"
b'
setting
follows
that
B
We n o w c o m p u t e First
we note
from
y'
'P
the two that
So Th.
the IIA
B'
integrals arc
B"
implies
to deal
a modified deformation the
same
with
polygon
the
V, the
end p o i n t s
such
of arc
that
' R 0. A' A"
number
over
member
polygon
R~
separately. and
is d i s j o i n t
p, ~b',b"" B',
on the
In fact is c h a n g e d
curve
+i
Setting
= (AIXA') + A" , we c o n s t r u c t
with our
other
by m e a n s
is d i s j o i n t
is a c l o s e d Ai
of w i n d i n g
'P
right-hand
in the
b' ~ P ' ' P =
integral
in p l a c e
within
on the lies
B"
that
B" ~ P ' ' P = In o r d e r
'P
to a n o t h e r from respect
hand,
we use
of a c o n t i n u o u s
B'
arc and
A"
with
A' - A "
to the p o i n t
new polygon,
' out of R I,
b".
22
fA~ ~p,,p
analytic
differential
on
residue
+i
and
AI
' A I.
R 0' just by replacing the arc y', we have
by
R'
V
= fAl ~p,,p having
-i, respectively,
A{, A2,... , Ag,.
the cycles
Since
does not intersect
: 0.
Thus,
Let
simple poles and having by Th.
Cb", ' b'
at
b'
IIA applied
be the
and
null periods
with
b"
with
along all
to the polygon
R~, we have
I
B' CP' ,p = I .¥, Cb",b'
and hence
B
'P
B'
B"
Our construction of Cb",b' larities and has null period
'P
'y'
'
shows that @b' ,b '' + ¢b",b' has no singualong A2,...Ag,. As for the period along
AI, we have
f
!
f
AI ((~b',b" + Cb",b' ) =
=f Since the differentials we eonclude
in
that
,
AI Cb" ,b'
A' -A" ~b" ,b'
F a (R') T
f
=
A I @b",b'
~b',b" + ~b",b'
:
f
A~ Cb" ,b'
-2wi.
are determined
by their A-periods,
-2~i~i , as was to be proved.
[]
NOTES Most results and Chapters information results
come from Chapters
i, 3, 4 of Constantinescu can be obtained
in 10E,
from Kusunoki
and Cornea
from sources
10F and in Subsection
[42]
I, II, V of Ahlfors
(see also Hurwitz
[CC],
indicated
and Sario
so that more
respectively.
ii (Cauchy kernels) and Courant
[AS] The
are taken
[35] for this matter).
CHAPTER II.
M U L T I P L I C A T I V E A N A L Y T I C FUNCTIONS
In our later d i s c u s s i o n of Hardy classes an important role will be played by a certain family of m u l t i p l e - v a l u e d multiplicative
analytic functions.
analytic functions having
analytic functions called
These are defined as m u l t i p l e - v a l u e d
s i n g l e - v a l u e d modulus.
The first objective
of this chapter is to give a precise d e f i n i t i o n to such functions. fact, we will define t h e m in terms of two equivalent notions: bundles and characters
of the f u n d a m e n t a l group.
that, on a compact b o r d e r e d Riemann surface, n o n v a n i s h i n g bounded h o l o m o r p h i c observe the order structure
sections.
In
line
We shall then show
every line bundle admits The second purpose
is to
in the space of h a r m o n i c functions,
leading
to the so-called i n n e r - o u t e r f a c t o r i z a t i o n of m u l t i p l i e a t i v e analytic functions.
§i.
M U L T I P L I C A T I V E A N A L Y T I C FUNCTIONS
i.
The First C o h o m o l o g y Group IA.
Let
{Vi: i E I} {~i~}
over
modulus one, with
R
be a Riemann surface.
of V
R, we denote by with values
i.e.
V. N V. ~ ~ l 3
~ij
in
~
of complex numbers of
is a s s i g n e d to every pair
i, j
in
I
6ij<jk : ~ik V inv.3 N V k I ~.
Two l-cocycles
said to be e q u i v a l e n t i
in the group ~
V =
the t o t a l i t y of l-cocycles
in such a way that
(i) if
For every open covering
ZI(v;~)
in
I
such that
{~ij}
{~ij} , in
and
if there exists an element ~j
= 8~l~ij@j
if
Vi AVj
@i ~ ~.
is then defined to be the set of e q u i v a l e n c e classes
in
ZI(v;~) T
The set in
HI(v;~)
ZI(v;~),
which forms a group with respect to the p o i n t w i s e m u l t i p l i c a t i o n , {~ij]{~ij} = {~ij~ij}. Next, take any two open coverings {V~,:
i' @ I ~ }
fining map
~.
of
R
such that
V'
V = {Vi: i E I} is a r e f i n e m e n t of
We may regard the refining map
~
are
for each
and V
i.e.
V' with re-
as a map from
I'
24
into
I
so that
ZI(v;~).
If
the c o v e r i n g to p r e s e r v e
]'
=D V'i' A V!]' ~ ~
V'.
choice
of r e f i n i n g
that
varies
of
with
lB.
Theorem.
Proof.
The p r o o f
definitions. consists in
V of
admits
coverings
V, we m e a n
a finite
Vi(v) N V i ( v + I )
is c a l l e d
obtained order;
from
e.g.
y
of
c
if t h e r e
for e v e r y When
~.
(a) Let
~ E HI(R;~) c
of
~
and
R
case,
faithful
in a s i m p l y R
if
covering
So we r e s t r i c t
elements
c
on
..a m
of
V2,
it is
ourselves
covering,
m-l.
in
V
if it is changing
{VI,V2,V3}.
the On
we m e a n a p a r t i t i o n
say
oi,... , am, of
c
with
c : al..-o m
y, each s u b p a r t i t i o n
so
has an ob-
is said to c o v e r c
say
A c h a i n of
without of
R
arcs,
V
VI,
of e l e m e n t s
~ : I,...,
of a p a r t i t i o n •
(i)
and that e v e r y o p e n
y = {Vi(1),...,Vi(m)}
c = oI
some
connected
By a c h a i n of a g i v e n
of an arc
R.
is s e p a r a b l e ,
is a s u b d i v i s i o n
to
of
(it) for each t r i p l e
Since
we say that of
F0(R)
We b e g i n w i t h
is c a l l e d
of c o n s e c u t i v e
is a d a p t e d
and
group
steps.
~ = {Vi(1) , .... V i ( m ) }
First we d e f i n e
and
with
some of the
a partition
to some s u b d i v i s i o n
limit of this
isomorphic
is f a i t h f u l .
A subpartition
In this
c : ~l..-Om
adapted
of
of a c h a i n
number
A chain
exists
when
is c a n o n i c a l l y
for e v e r y
by r e p e a t i n g
c : a l a 2 - - - a m.
s y s t e m of g r o u p s
y : {Vj(1),...,Vi(m)}
~ @
by a p a r t i t i o n
vious m e a n i n g . c
sequence
into a f i n i t e
that
V" This
group
is i n c l u d e d
{VI,VI,V2,V3,V3,V3}
the o t h e r hand,
if
cohomology
a faithful
which
a subdivision
on the
the f i r s t
sets and
in the proof.
such t h a t V
V
open
it is c o n n e c t e d . R
Moreover,
The d i r e c t
is c a l l e d
into s e v e r a l
V IUV 2 UV 3
has a r e f i n e m e n t
to f a i t h f u l
does not d e p e n d
of the f u n d a m e n t a l
connected
whenever
R.
is seen HI(v;~)
: I(V",V')o I(V',V).
a direct
HI(R;T)
An o p e n c o v e r i n g
R
I(V',V)
I(V',V):
over
~.
is d i v i d e d
not h a r d to see that covering
in
F0(R)*
the u n i o n
{~ij } + {~i'j" }
I(V",V)
of
and
is defined.
a l-eocycle
we get a m a p
forms
The g r o u p
of s i m p l y
subset
relation,
HI(R;T)
group
'
and is a g r o u p h o m o m o r p h i s m .
coefficients
the c h a r a c t e r
{{i,j,}
of
t h e n we h a v e
forms
I(V',V)}
by
I'
Then
o v e r all o p e n c o v e r i n g s
is d e n o t e d
'
in
~(i'),u(j')
V', t h e n we h a v e
{HI(v;T);
be any e l e m e n t
j'
and t h e r e f o r e
see t h a t the m a p
maps
of
system R
.
{~ij} i'
Since the c o r r e s p o n d e n c e
We also
is a r e f i n e m e n t
Let
for some
the e q u i v a l e n c e
÷ HI(v''~), .
V3
= Vu(i, ). ~ ~
t~,j ' = ~ ( i ' ) , ~ ( j ' )
We set
V
A V[
i'
V (i,) N V ~(j')
means
~(Vi,)
V!
an arc
=C Vi(v)
o
is a d a p t e d of
to
al-''o m
y. is
y.
a homomorphism
e 6 F0(R).
~, r e s p e c t i v e l y .
of
Choose
HI(R;T)
into
any r e p r e s e n t a t i v e s
Namely,
{~}
F0(R)~. {~ij}
is a l - c o c y c l e
25
over a covering
V : {Vi: i E I}
from the origin
0.
covers
Let
and
c
is a closed curve issuing
y = {Vi(1),...,Vi(m)}
be a chain of
V, which
c, and set m
(2)
F(e;Y;{6ij})
with
i(m+l)
and
: i(1).
: ~ ~i(~)i(~+l) ~:i
We have to show that the product
(b)
does not depend on the choice of
F(c;y;{~ij})
representative covering
c.
{~ij}.
To see this,
Y1
is a subdivision
If
~ii = i, we see that {Vj(1),...,Vj(m)} to both y therefore
and
F(C;Yl;{~ij})
let
only on
of
y, then,
~ : i,..., m
with
i(m+l)
Next,
: i(1)
and
of
for
V
using the property
c = oi---o m
Vi(v) A V j (v)
~
y, fixing the
be another chain of
= F(c;y;{~ij}).
and if a partition YI' then
YI
vi(~) A V i ( ~ + l ) A V j ( ~ ) n V j ( v + l ) for
depends
~.
e
if
YI =
is adapted
~ : i, .. . , m
and
~
j(m+l)
: j(1).
Thus,
in
view of (i), we get m
F(C;Yl;{$ij))
= ]-F ~j(~)j(~+l) 9:1 m
: ~ [6j(v)i(v)~i(~)i(v+l)$i(v+l)j(~+l) ] ~:i m
= I T ~i(~)i(~+l) v=l Finally,
let
YI
be any chain of
subdivisions
y'
and
tition
c = oi--.o ~
F(C;Yl;{~ij})
YI' of
a covering valent,
c
y
{~i,j,}
of
V
and
{@i":
c.
simultaneously.
V'
Since
{~ij}
Thus we get
in place of of
and
~
associated
{~,j,}
V" = {V'~,: i" E I"}, which
with refining maps
i" E I"}
to which a par-
= F(c;y;{~ij}) ,
F(c;{~ij})
be another r e p r e s e n t a t i v e i' E I'}.
Then we can find
YI' respectively,
= F(c;y';{~ij})
So we may write
V' : {V~,:
and a system
covering
is adapted
there exist a covering
refinement
V and
= F(c;y~;{~ij})
as was to be proved. F(o;Y;{~ij}). (c) Let
of
= F(c;Y;{~ij})"
with values
in
~ T
and
: 8i"$~(i")~(j")@~'~
is a common
~', respectively,
such that
!
6~'(i")z'(j")
with
are equi-
28
for each pair {V~,,
i",
V"
j" }
(i) .... ' i " ( m ) for simplicity, i(v)
in
I"
with
be a chain
V'~,,nv'~,, ~ @.
of
V"
= ~(i"(v)),
covering
i'(v)
Now let
y"
the curve
= ~'(i"(v))
c.
for
: Write,
v = i,...,
m.
Then, B(y") = {Vi(1) .... ,Vi(m)} (resp. ~'(y") : { V i , ( 1 ) , . . . , V i , ( m ) } ) is a chain of V (resp. V') c o v e r i n g the curve. Then, u s i n g the convention
i(m+l)
= i(1)
etc.
as before,
we have m
F(e;{E~,j,})
= F(c;~'(T");IE~,j,})
= ]-m v=l
E~'(v)i'(v+l)
m
]-~ v:l
:
(@i,,(~)~i(~)i(~+l)@i,,(~+l~ I)
m
: T~ ~i(~)i(v+l) v=l : F(e;B(T");{~ij}) This m e a n s {~ij}.
that
F(c;{~ij})
So we may w r i t e (d)
Let
eI
and
If the d e f o r m a t i o n covered
by the
depends
F(c;~) c2
cI
chain,
say
and
..., c k'
issuing
for e v e r y chain.
that
~2 ~
{~ij}, using
is d e n o t e d
in
any
in
F0(R).
then they
are
= F(c2;{).
ci = el,
of c l o s e d
c k' = e 2
are c o v e r e d = F(c~;~) by
~
c{,
and such that, by the
.....
only on the h o m o t o p y
paths
F(c~;~)
class
and
same
~.
~
of
= c.
This
F(~;6). seen,
Thus
HI(R;T).
Given
{qi j} the
F0(R).
~
small,
sequence
in (2) is d e t e r m i n e d
by
As is e a s i l y in
(f)
expression
depends
of
= F(e2;Y;{~ij})
such that
of
so that
c' and e' v v+l F(Cl~ ~) = F(c~;~)
F(c;~)
(e) fixed
0
class
F(e;{~ij}).
is very V
k-l,
Hence,
quantity and
from
v = i,...,
the
on the e o h o m o l o g y of
we can find a finite
It follows
F(e2;~). Namely,
case,
c2
y, of
F(el; ~) = F ( C l ; Y ; { 6 i j } ) In the g e n e r a l
only
instead
be two r e p r e s e n t a t i v e s
between
same
: F(c;{~ij}).
This
<, q
associated
same n o t a t i o n F(~;[n)
F(~I~2; ~) = F ( ~ I ; ~ ) F ( ~ 2 ; ~)
F(.;~)
is a c h a r a c t e r
character
from with
as in
is d e n o t e d
HI(R;~)
the
F0(R)
by
F t.
same c o v e r i n g
V : {Vi:
(a), we have
m ~i(v)i(v+l)ni(v)i(v+l)
= F(~;[)F(~;n).
~I
for every
we find r e p r e s e n t a t i v e s
= F(c;y;{[ij~ij})
= ~ v:l
for any
of
i e I}.
So,
27 It follows that the map F0(R)*. (g)
~ ÷ F~
is a h o m o m o r p h i s m
We now define a h o m o m o r p h i s m
of
F0(R)*
will turn out to be the inverse of the map Let i E I} from
F
be any character
of Vi
R, we choose, and a curve
of
F0(R).
for every
ei
union for
HI(R;T)
into
into
HI(R; T), which
~ ÷ F$. Given any covering
i E I
V = {Vi:
once for all, a point
joining the origin
V i NV.] ~ 9, then we take a curve,
of
0
to the point
eij , joining
z.m
to
z.]
z. i
z i.
If
within the
V. UV.. The curve c.. is unique up to homotopy equivalence, i ] 11 V. U V. is included in a simply connected subset of R. We set i ] -i $ij : F(c.e..c.i l] ] )
for every pair eocycle over included to
i, j V.
in
I
In fact,
It follows
(cicijcjl).(cjCjkC k -
-i)
that
as was to be proved. of
sequently
into
(
V i ~V.] A V k ~ ~, then subset of R and so cieikc k-i
is a l-
V i UVj UV k elk
is homotopic
is
is homotopie
to the composite
that
-I -i = F(cl.e..c. i] ] )F(ejcj kCk ) : ~ij ~jk '
Since the m u l t i p l i c a t i o n
we see that the map
F ÷ ~F
in
F0(R)*
is defined to be
is a h o m o m o r p h i s m
of
F0(R)*
HI(R;~).
~ij = F(cicijc~l).j
and let
F0(R)* Let
c
v = i,..., m.
within
Vi(v).
subset of
Since
c = ~l--.~m
Then,
R, we see that
~ c
V
To show that F = and cij, and then
covering
of
c
with
point of ~ by z@v to zi(~)
join
Vi(v) U V i ( v + I )
It follows that the curve
c i.
zi,
be a chain of
Denote the initial z~ +I : z~.
~ = ~F"
i e I},
be any closed curve issuing from
y = {Vi(1),...,Vi(m)}
i,..., m, and set
and set
V : {Vi:
so that there exists a partition for
Then
It is a routine matter to verify that distinct
(h) Take any F in F~ , we choose, as in (g), set
I ~.
V, z. or c. only result in equivalent cocycles and coni i that the above definition gives a unique element, say 6F'
HI(R;T).
pointwise,
V i NVj
and therefore
~ik : F(cicikCkl)
in
if
in a simply connected
oijcjk.
choices
with
the curve
is homotopio
to
z~ for v = by a curve c'v
in a simply connected c~ci(~)i(~+l) c'm+l-i "
to
c{ Ci(l]l( ci(1)ci(1)i(2)ci(2) -i )--'(ei(m)Ci(m)i(1)ci(1) -l)ci( l)Cl,-I Thus we have
F~(e)
= ~i(1)i(2).--~i(m)i(1)
m
c,
~v ~ Vi(v)
is included
is homotopic
0
: ~ F(ci(v)ci(v)i(v+l)Ci(v+ v=l
i]i)
28
T -1
F(ci(1)e I
=
y
celci(1) I) = F(ei(1)c i l)F(c)F(clci(1) I)
= F(c) , as was to be proved. (i) that
Finally,
~ = ~F"
take any
Let
{~ij}
~
in
HI(R;T)
and set
be a representative
F = F$.
l-oocycle of
~
We show associ-
ated with a covering V = {Vi: i E I}. Again take zi, c i and cij as in (g). For every j in I, let us choose a fixed chain yj = {Vi(l,j),...,Vi(mj,j )} is the same for all V.i NV.] ~ ~.
which covers
j, say
i(0).
cj.
Here we assume that
Take any pair
i, j
in
I
i(l,j) with
Then
(~F)jk = F(cjcjkCkl) = ~i(l,j)i(2,j)'''~i(mj,j),j~jk~k,i(mk,k)'''~i(2,k)i(l,k). Writing @j = ~i(l,j)2(j,j)...~i(mj,j),j, we have (~F)jk = 8jSj k0k I for j, k in I. Namely, {(~F)jk } equivalent to {~ij}. Hence, ~F = ~" This completes the proof.
2.
Line Bundles and Multiplicative 2A.
Analytic
We now consider line bundles over
is []
Functions R.
We do not define them
as topological spaces with oertain structure but just say that every element in H I ( R ; T ) determines a line bundle (precisely, a unitary flat complex line bundle)
over
(AI) Every l-oocycle a line bundle ~;
R.
({~ij},
Using representatives, {Vi})i,jC I
in
we say:
zl({vi};~)
defines
(A2) Two l-coeycles ({~ij }' {V'})',jell z and ( { ~ j } , {V~})i,j~i, define the same line bundle, if there exists a common refinement {V"}e~EI" of {V.}l and {V~} with refining maps ~: I" ÷ I and + , { ~ ,'( ~ ) ~ , ( ~ )} I" I' respectively, such that {~(~)~(B)} and equivalent {@ } el, ,
l-eocyeles in
~
over
{V"} r~ ; namely,
there exists a system
satisfying ~ ', ( ~ ) ~ ' ( B )
(3) for every pair
B': are
~, 6
For a line bundle
in
I" ~
= @~
with
over
1~(a)~(B)eB
V"~AV~
~ ~.
R, we define a section
f
of
~
over
29
R
as follows:
for
when a representative
~, the corresponding
{Vi})ie I
({6ij},
representative
of complex-valued
functions
of
{Vi})i,je I
f
fi'
is chosen
is a collection
fi
being defined
({fi },
on
V i,
such that (4)
fi(z)
' } ' {V~}) i,jel' is another VoINV.] ~ ~. If ({~ij and if {~ij} and {~ij} are connected by the
on V I. NV.3 whenever representative of ~ relation
(3)
is defined ({~j},
then
({fl},
{Vi})iCI,
to be the representative
{Vi})i,jEi,
when we have f ,,( ~ )
(5) on
: ~ijfj(z)
V".
The relations
modulus any
Ifi(z) I
i
(4) and
with of
f!
f
a function
with respect
for every = 8~if(
being
on
V!
to the system
~ e I"
~)
(5) imply that,
for every
is the same for any representative
z E R, the
{fi }
of
f
and
with
z E V.. The common value is ealled the modulus of f i and is denoted by If(z)I. A section f of ~ is called holomorphic (resp. meromorphic) if every fi is holomorphie (resp. meromorphie) on V I• for a representative
({fi }, {Vi})ie I.
choice
of representatives.
set of holomorphie 2B. morphic
(resp.
sections
Theorem.
Let
F0(R)
HI(R;~) section
of
~
~
analytic
0, called
to
F0(R)*. and let
~
Let
from
issuing
0
of
over
~
fi(0)
over
the
R. or mero-
For this purpose,
we take
and have the following
R
and
be any branch of
of the
M(R,~))
of holomorphic
~.
the origin,
independent (resp.
F = F~
under the canonical
fi(0)
curve
Proof.
sections
f = ({fi }, {Vi})
continuation
c
~(R,~)
continuation
be a line bundle
Then the analytic
equal to
is clearly
by
of the given line bundle
corresponding onto
We denote meromorphic)
We next diseuss
once for all a point
of
The definition
of
be any meromorphic
of
f
with
is possible
and the resulting
the eharaeter
isomorphism
function
0 E Vi(0).
along
each closed
element
at
0
is
F~(e)fi(0). Let
y = {Vi(1),...,Vi(m)}
curve
e
with
direct
analytic
tion element is exactly F~(c)fi(0)
i(1)
= i(0).
continuation
to be obtained
be a chain of
The formula of
fi
to
by continuing
{V i}
(4) shows that Vj.
It follows
fi(0)
~i(1)i(2)...~i(m_l)i(m)~i(m)i(0)fi(0), in view of the definition (1). []
eovering ~ijfj
that the func-
analytieally which
the is the
along
is equal to
c
30
As
far as a n a l y t i c
HI(R;~)
and the
tified,
so that
2C.
a
on
can a l w a y s
log u
Let
if t h e r e
phic) bundle the
~
The
that
2D.
A
~
such
defined
saw
curve
e
equal
to
sense,
bundle
f.
~.
0
M0(R,~)
in
M0(R, ~)
whose
principal
u
for
on
R
every
a meromorphic definition,
a locally
is an l.m.m.,
function
(resp.
If(z)I
then
call
on
l.a.m.) (resp.
on
we
R
if and
holomor-
R.
The
line
the
bundle
(or
f0'
and
called
f
origin
forms
have
point
the
is
R.
of
f.
f0 + go"
we call
if the
R
a
the p r i n -
branch along element
F0(R).
Let
us d e n o t e
at
0.
any
closed
at
0
is
In this
functions
sum of two
multi-
are
of
as the m u l t i p l i c a t i v e
on
R, w h i c h
for all,
functions
function
meromorphic
space
and
principal
as a c h a r a c t e r
is
over
To e v e r y
once
analytically
resulting
f
~f.
0, w h i c h
same
is c a l l e d
is an l.m.m, bundle
meromorphic
character
a linear
is d e f i n e d
of
R
For any m u l t i -
by
we a s s o c i a t e ,
at the
~f
the
on
Here,
Ifl line
is d e n o t e d
R, the
the
f
extension.
can be c o n t i n u e d 0
regarding
branch
function
a unique
and
in
straightforward.
its m o d u l u s
set of all m u l t i p l i c a t i v e
f, g
u
real-valued
=
analytic
f
if t h e y f0
from
is also
of
say
2B,
~f(c)f0,
the
in this
is c a l l e d
u, w h i c h
Two m u l t i p l i c a t i v e
same
issuing
M0(R,~)
If,
is s i n g l e - v a l u e d .
f,
function
branch,
in Th.
~f
by
2C, d e t e r m i n e s
fix a p o i n t
to be the
As we
acter
line
of
if, and
and a m e r o m o r p h i c u(z)
Ifl
function
by Th.
meromorphic
branch
function
a
If
it is r a t h e r
its m a x i m a l
meromorphic
single-valued cipal
F0(R).
of
is an l.m.m. ~
meromorphic
to be
Let us
u
that
for
always
plicative
u
extended
uniquely
(multiple-valued)
the
V.
in
u.
if its m o d u l u s
is c a l l e d
on
$
can be iden-
of
"l.m.m.") V
"l.a.m.").
bundle
is o m i t t e d ,
and t h e r e f o r e ,
real-valued to
bundle
F0(R)*
0 < u < ~.
multiplicative
plicative
to
Then
a line
of
of
assumed
Ifl
a line in
a character
to be h o l o m o r p h i c ,
is d e t e r m i n e d
proof
u =
be a n o n n e g a t i v e
f
character)
extended
(abbreviated
vanishing.
section
to d e n o t e
a neighborhood
wherever
exist
F~
exists
(abbreviated
u
identically
only
be u s e d
such
is h a r m o n i c
concerned,
modulus
be c h o s e n
modulus
Theorem. not
V
are
character
a nonnegative
R, t h e r e
f
analytic
will
meromorphic in
function f
$
We call
a locally point
functions
corresponding
by
of char-
functions
meromorphic
function
31
2E.
So far, our sections
values.
of a line bundle
Besides these, we can define a section
are first order differentials. the numerical ~i
on
Vi
ones:
The definition
in 2A.
differential,
(resp. meromorphic)
differential
(resp. meromorphic)
denoted by
3.
F~(R,~)
Existence 3A.
and
Z
R
g
and
cycles
in
(resp.
with
R, where
Yk'
{Aj, Bj:
only with
all others.
Let
Bj
fi
~i
[.
~-i
Ck
~.
Let
g}
R
is
is homologous
to
Yk
among these cycles, Aj) and every
for
7
on
~¥(q)
: I
R
Y
with
j :
sequence
A.
(resp.
is disjoint on
in
k : i,...,
every
Ck
g
basis of l-
is a canonical
be the Cauchy differential
For any arc
R
B.)
from
defined by
we set
~(P'q)"
of
~y
for
y = Aj, B.j R \ Aj,
and
C k-
so that the
disjoint
from
A..
we have
I
d~A.
B.
j = i,...,
g.
at the intersection of
over
Aj, Bj
be a canonical
~A. is single-valued and holomorphic on B differential d~A. has no periods along any cycles
Bj!
[
surface with genus
(i)
for
by a differential
The set of all holo-
Riemann
j = i,...,
We shall look into the properties
Moreover,
similar to
is a ho]omorphic
sections of
k : i,...,
(resp.
~(p,q)
Th. liB, Ch. I.
whose values
is called a holomorphic
section of
k = i,...,
Here we may assume that,
intersects
~
~
Sections
components
Ck
of
F~{(R,~)).
the sense of Ch. I, 2B and Z-I.
then
be a compact bordered
boundary
i,...,
~
is entirely
If every
differential
of Holomorphie
Let
take only numerical
i.e. we have only to replace
in the definition
(resp. meromorphic) mcrphic
[
A.~
and
In fact,
pj
of
let
Aj
= 2~i
j
]
{V, z}
and
Bj, respectively,
be a parametric
Bj
and take
containing
pj
small
disk centered
ares
Aj'
and contained
in
and V.
Then we have
~A'(q) ]
The s e c o n d on
R
off
term
of the
= I
A!
~'(P'q) + I
right-hand
Aj \ Aj' , s o t h a t
side
A.\A!
is
~(P'q)"
single-valued
and holomorphic
32
Bj
Bj
]
A! 3
B! ]
B!-B? q A[ 3 3 3 is a continuous deformation
where
B? 3 has the same end points
A! ]
B[, within V, such that BY 3 3 as B! and is disjoint from A! and such that 3 ] is a closed curve of winding number +i with respect to the
BV 3 3 terminal point of B[-
senting
p
and
where
R(z,%)
of
A!. In terms of local variables 3 q, respectively, in the parametric w(z,~)
z2
B.\B[ ] 3
in two variables.
~
repre-
V,
Denoting by
zI
and
' we thus have Aj,
the initial and the terminal points of
~(p,~)
and
= [(z- 6)-i + R(z,~)]dz,
is holomorphic
I
z disk
= log [(z 2 - ~)/(z I - ~)] + RI(~),
A[ ] with some holomorphie
I
d~A" B. ]
function
= I
3
RI(~).
{( 1 B!-B:'
]
i z l ) d ~ + dRl}
~-z2
]
So we get
= 2~i,
-
as desired. (ii)
Similarly,
the one along
the only nonzero period of
I (iii) Yk'
Finally,
k = i,...,
not with other
Cj
let
Yk'
is seen to be
daB. = -2~i. 3
A.
on
d~B. ]
A.: 3
be an arc from a point on
h-l,
intersecting
and
yj,
j ~ k
with and
Ck
y~
to a point
at a single point and
j =< ~-i.
We set
~'Ck(q) =
,(q). Supposing that Yk is positively oriented with respect Yk we see that the only nonzero period of d ~ k occurs along Ck:
f Ck for
k = i,...,
prescribed
=
-2~i
Z-I.
These observations Theorem.
d~k
to
prove the following
There exists a function holomorphic periods
along cycles
on
in the canonical
R
and having any
basis.
R,
33
3B. tions
We are now able
with
Theorem. has
Every
holomorphic
in
Aj,
R, w h e r e
tified
with
f o r all
~j,
there of
§2.
h
set
section
for
Basic
Tc
0.
~j
OF H A R M O N I C
~
We then
h
for
i.e.
of 1-cycles ~
boundary
c a n be
iden-
Choose, the
once
origin
#
sense,
e. ] a real
define
is
By t h e p r e c e d i n g
on
R
every
it is an i n v e r t i b l e
<, as was
and
A! joining ] In an o b v i o u s
= exp(2~i{j).
to
g IB,
Fo(R).
sueh that j : I,...,
bounded
to be p r o v e d .
the 2g+Z-l.
holomorphic
[]
FUNCTIONS
C(R,~)
be t h e
on a R i e m a n n convergence
linear
surface
space R.
on c o m p a c t
o f all r e a l - v a l u e d
We give
subsets
of
the
space
= HP(R)
denote
the
set o f all n o n n e g a t i v e
HP
is a c o n e
HP
and
every v
Theorem.
in t h e
nonnegative
in
HP.
The
cone
HP
sense
real
is
that
number
locally
is
R.
subset,
R.
C(R,~)
C(R,~)
dense
on
Y
then
basis
genus
group
an a r e
surface
sections,
bounded.
By Th.
function
is e q u a l
bundle
STRUCTURE
of u n i f o r m
and
~(ej)
Aj
Let
countable HP
2g+~-l,
j, b y
Riemann
also
has R.
c. : A ! A . A ! -I ] ] ] ] curve issuing from
along
functions
Let
R on
fundamental
a holomorphic
line
are
set
every
func-
Structure
4A. uous
j = i,...,
bordered
be a c a n o n i c a l
that
bundle
of the
f = exp(2~ih),
LATTICE
4.
as a b o v e
holomorphic
holomorphie
f-i
2g+~-l,
exists
of the
multiplieative or c h a r a c t e r .
bounded
such that
be a l i n e
A. and ] as a c l o s e d
theorem
If we
~
every
number
bundle
on a compact
j = i,...,
on
considered
period
f
a character
for
to a point
bundle
we a s s u m e
Let
line
(or i n v e r t i b l e )
sections
Let
contours.
u
line
nonvanishing
Proof.
to c o n s t r u c t
any prescribed
(i) ~
(ii)
with
Since
contintopology
R
has
a
to be m e t r i z a b l e . harmonic
eu E HP
and
compact
seen
the
functions
for e v e r y u + v E HP
respect
to t h e
u
in
for any
topology
C"
Proof. pact
By u s e of t h e H a r n a c k
subset
stant
E
C > 0
of
R
inequality
and every
depending
only
on
sup{u(z): for
any
u
in
HP.
So,
point E
and
it is s e e n a
in a
that,
R, t h e r e
and
for
exists
every
com-
a con-
satisfying
z e E} S Cu(a)
for every
fixed
a
in
R
and
every
fixed
real
84
numbers
0 ~ a ~ 6, t h e
set of f u n c t i o n s
equicontinuous
on e v e r y
subset
with respect
of
follows
HP
at once.
Corollary.
a
HP(a)
4B.
compact
HP'
C(R,~).
sented
as t h e
The c o n e Namely, This HP'.
defines
HP'
in
lower
uA v
Ch.
I, 4C.
HP' above
(resp.
(resp. cone
the
has
~ ~ u(a)
~ 6]
is
therefore
is a c o m p a c t
From
the
this
theorem
itself
= i)
lower
element
bound)
of
HP
which
HP'
if
ones
pair the
space
HP'
u, v
we
in
see t h a t
upper
from
bound
In p a r t i c u l a r ,
to the o r d e r
of
greatest
is b o u n d e d
least
way.
E HP.
we d e f i n e d
which the
usual
structure
every and
R.
v-u
or otherwise
has
be r e p r e on
in the
uv v
HP'
with respect
can
space
Thus,
the
in t h e
functions
linear
HP of
HP'
in the
a lattice
in
exactly
in
R
bound
subset
of
if a n d o n l y
lattice.
are
every
~
the
upper
compactness
i.e.
by some
least
which
of l o c a l
forms
a vector
the
on
u ~ v with
span
harmonic
relation
we d e f i n e
HP',
complete,
linear
of f u n c t i o n s
is c o m p a t i b l e
in
below)
the r e a l
space
becomes
greatest
HP
u(a)
of t w o n o n n e g a t i v e
HP',
HP'
By use
is o r d e r
T c.
= {u ~ HP:
an o r d e r i n g
in
relation
of f u n c t i o n s bound
set
the
denotes
It is the
In fact,
R
and
and metrizable.
u, v
ordering
R
topology
in
difference
HP for
{u E HP:
of
to the
= HP(R;a)
: HP'(R)
space
subset
[]
For e v e r y
is c o n v e x ,
compact
defined
the by
HP.
4C.
Let
E
be a l o c a l l y
a convex
cone
C
in
that
the r a y s
H
all
not p a s s i n g
The
set
B
also B
suppose
A point
that
x
in
E
vertex
from The and
having
result
at t h e C
is c a l l e d
convex
and this
in t h i s
origin
a base
property respect
0
of
of
B
if a n d
is
E.
Suppose hyperplane by
C.
define
We c a n
a point
We
x
in
if it h a s
the
for called
following
B.
y - x e C.
only
y = ~x
sometimes
is t h e
and take
is d e n o t e d
whenever
imply
space
a closed
it is s e e n t h a t
set
y ~ x
C NH
x S y
Then
linear
intersect
intersection
by s e t t i n g
of t h e
y C C
topological
0) in
is c o m p a c t .
point
C
0.
in
B
property:
fundamental
with
convex
relation
is an e x t r e m e
following
The
through
is t h e n
an o r d e r i n g
E
(issuing
convex
some
~ ~ 0.
minimal.
theorem
due to
Choquet: Theorem.
Suppose
metrizable.
Then
that the
the
base
following
B
of a c o n v e x
hold:
cone
C
is c o m p a c t
and
3B (a) of
B
The
and
on
B
sure
E
every
on
integral
B
of e x t r e m e
x
in
supported
Z
that
set
such
is d e f i n e d
for e v e r y
B
by
points
is the
E, i.e.
that in the
continuous
= i
sense linear
B
is a n o n v o i d
barycenter
there
~(E)
of
of a p r o b a b i l i t y
exists and
G~-subset
a probability
x : fE y dz(y),
of the w e a k
topology
functional
~
on
where
of
E
measure
Borel
mea-
the
E, m e a n i n g
we h a v e
~(x)
=
fE ~(Y) d~(y). (b) fined
If
by
C
is a l a t t i c e
C, t h e n
probability
every
measure
~
Our o b s e r v a t i o n the
requirements
Corollary. points nonvoid
a
of a u n i q u e
in
R
measure
= rE(a) v(z) d~(v)
4D.
We c o n s i d e r
disjoint
discrete
union
of the
of
R.
define
uI ~ u 2
if
Ul(Z)
R.
relation
~
space
S/~
same
HP'(R\
tical
in
HP'(R\
The
sum
SP' SP'
Z)
= Ul(Z) + u2(z) u2(z)
outside
Theorem. ations
SP' defined
in e v e r y The if
u
proof
a logarithmic
So e v e r y ui
(the
for some
every
z
Z).
SP'
subset
lattice
It i n d u c e s SP'
is s t r a i g h t f o r w a r d H P ' ( R \ Z) singularity
with of
is a
= i,
i.e.
In p a r t i c u l a r ,
we
Z
u2
discrete
two
only
with
the say
S
over in
the
all
S
subset
and
we Z
of
quotient
elements
if they
is r e g a r d e d
of)
runs
Ul,
S
Let
in the
are
iden-
as a s u b s p a c e i = i,
function uI ~ u2
of
2, in
(u I + u2)(z) if
Ul(Z)
R.
with
respect
original
to the vector
pointwise lattice
oper-
structure
complete.
and
discrete u
E(a)
barycenter
~(E(a))
in
H P ' ( R \ Z i)
the
is o r d e r
some
if and
of
all
set of e x t r e m e Then
Z), w h e r e
We
satisfies following
singularities.
Clearly
class
HP
R.
relation
H P ' ( R \ Z) in
with
of e l e m e n t s
outside
in
deone
the
is the
HP(a).
with
HP'(R\
the
= I}. HP(a)
in
R \ (Z I U Z 2 ) .
discrete
above.
of
= SP'(R).
being
in
in
z
pair
equivalence
is a v e c t o r
HP'(R\
is in
identical
Z).
as
HP(a)
on
cone
E(a) u(a)
~
= u2(z)
are
by
functions
SP'
the
u
space
relation
of an at m o s t
so we h a v e
every
For e v e r y
by
u I + u2,
is d e f i n e d
denote
is an e q u i v a l e n c e
is d e n o t e d
that and
topology
for
harmonic
subsets
The
and
ordering
E.
= {u e HP:
in the m e t r i c
u(z)
be the
and
HP(a)
probability
by
theorem
HP(a)
to t h e
is the b a r y c e n t e r
4B shows
Choquet
set
of
u = rE(a) y d , ( v ) have
be
respect
B
in 4A and
convex
G6-subset
with
in
supported
in the
Let
of the
x
is o m i t t e d . Z, every
or a r e m o v a b l e
We note point
one.
in
finally Z
that,
is e i t h e r
36
5.
0rthogonal 5A.
lute v
Decomposition
For
value
u
(in
in
SP'
SP')
are o r t h o g o n a l
u • v.
If
u l±u2,
then
u
Typical
examples
if
in the
of
we u.
set
lu| A Iv|
SP'
as
= uv
u, v
= 0.
be
(-u) in
If t h i s
is e x p r e s s e d
expression are
lul
Let
as
is c a l l e d
and
SP'.
call We
is t h e
case,
u = uI + u2
in
an o r t h o g o n a l
it the
abso-
say t h a t
u
and
then we write SP'
with
decomposition
of
u.
follows: +
(a) which
For each
we call
the
u
in
positive +
We then have (b) all
u
in
is a b a n d
SP' of
SP',
And we have
uI + u2 and
the
u 2 ~ 0.
of
SP ~ This
Q(R))
are
onto
and
is an e a s y
~uasibounded
u
Q(R)
Theorem.
has
only removable
has
the
are
SP ~ ,
parts
of
For every
assume
as
u ~ 0
Y±,
v
form
u ~ 0
the
(resp. bands
of t h e
Prl(u)
then
above
in
to
ym.
= Y± + Y±±. Namely,
implies
if
both
function
u =
uI ~ 0 i
on
Functions
SP'
and
SP'
projections are b o t h
general
and
the
Y±,
theory
prQ(u)
are
is t h e
pr I
and
prQ
positive. of v e c t o r called
lat-
the
inner
u, r e s p e c t i v e l y .
u
in
SP ~
so t h a t
its q u a s i b o u n d e d the
inner
part
part
prQ(u)
Prl(u)
of
If w e
set
u. without
loss
of g e n e r a l i t y .
u = u An, n = i, 2,..., t h e n u a r e b o u n d e d a b o v e a n d so a r e h a r n n m o n i c on R. The sequence {u n} is m o n o t o n i c a l l y i n c r e a s i n g a n d is majorized exists If
and
by the
superharmonic
is h a r m o n i c
s E I(R),
then
function
everywhere
lUnl A Isl
R,
in
quasibounded). of
The
ym
in
belongs
SP'
constant
Then
and has
bounded
SP'
set o f
Y.
SP'
some
is p o s i t i v e .
respectively,
singularities,
singularities
of
in
= I(R) ± = {I} ±i.
bands.
Q(R),
element
of
then
Q(R)
consequence in
summand
inner
to be t h e
lattice
of the
of o n l y
and
called
and
I(R)
We may
each
.
yl
for
Y'
in t h e
= (-u) v 0,
± u
subspace
subset
u 2 E Y±±,
sum of these
For any
to e v e r y
u
u, r e s p e c t i v e l y . -
u
lul =< lvl
Y'
and of
we d e f i n e
sum decomposition
I(R)
direct
same
of
= {i} ±
and the
Proof.
bound
Y
tices.
5B.
and
consists
onto
SP'
and
is a l i n e a r
When
Both
orthogonal
~
0
parts +
+ u-
orthogonal
and
I(R)
(resp.
Theorem.
are
of
u I ~ Y±
then we write I(R)
Y
projection
with
= uv
negative
: u
for a n y n o n v o i d
a direct
u
+
lul
u ~ SP'
upper
set
and the
,
i.e.
if
(ii)
least
Moreover,
which
(i)
and
the
- u
subset
SP',
properties: u E Y±;
any
we
-
u : u
For
SP'
: Un
on A Isl
u.
R.
We ~
So
limn÷ ~ u n
claim that
n h Isl
:
O.
(= v,
say)
v = prQ(u). So
u
n
e
Q(R).
u
37
Since
Q(R)
have
is c o m p l e t e ,
( u - v) A i = 0.
u
v S u- u n
w+
(u A n )
for
÷
0.
This
prQ(u).
n = i,
S n + I
w S U n + l - - U n.
5C.
2,...
{u n}
that
argument u
in
prQ(u)
5D.
We
apply
l.m.m°
u
belongs
to
(resp.
Q(R)).
Let
prQ(lOg
u)
b y Th.
harmonic
on
R
the
: lim
of
u, r e s p e c t i v e l y .
uI
5B,
and
bounded
characteristic
Suppose
that
branch
this
factors Finally
bounded u S i uI
and
is c a l l e d
bounded u
in
0.
(see
2C).
characteristic outer)
harmonic
are
called
UQ
prQ(lOg
These
if
if
An log u
log u E I(R)
characteristic.
and
Prl(lOg
= exp(prQ(lOg
the
u)
inner
has
function
and
u)
Then is
u)).
the
outer
factors
no s i n g u l a r i t i e s ,
f
on
R
corresponding
fl
(resp.
function the
fQ)
the outer
one
l.m.m,
0
fl
and
uI =
denotes
and
are
is s a i d
to be of
u =
Ill.
be a m u l t i p l i c a t i v e
such that
suffix
functions
of m o d u l u s
on
an i n n e r
is b o u n d e d .
of c o m m o n R.
inner
say t h a t u2/u I
characteristic J
l.m.m.'s
of b o u n d e d
and
Let
speak
l,a.m.'s
we
to
fQ
called
IflI, the
are the
UQ
=
principal
determined inner
and
f, r e s p e c t i v e l y .
we w i l l
then
v =
following
(resp.
u))
if so is the
factor
Hence,
[]
set
meromorphic
any bounded
u2
the ease, uI
of
inner for
We
holomorphic)
point
up to a c o n s t a n t outer
results
= (fl)0(fQ)0 , where
at t h e
we h a v e
Un+ I- u n
l.a.m.
occurs.
(resp.
u - v E I(R).
the
w+ un
Thus
we have
observations.
we
w
[(-m) v ( n A u),].
everywhere
UQ
an
A multiplicative
f0
lim
l.m.m,
is.
Since
is a l w a y s
and
shows
that
= U n + I.
sequence,
so
these
inner
be a n y
log u
functions
IfQl
and
It f o l l o w s ( n + i)
hand,
Then,
we have
preceding
u
The
meromorphie
also
It is c a l l e d
wherever
UQ
R
SP'
u I = exp(Prl(lOg
factor
w £ i.
w + u n =< u A
from
On the o t h e r
w = ( u - v) A i.
is s a i d to be of b o u n d e d
SP'.
is,
set
and
on
is c l e a r
For every
v E Q(R).
we
is a c o n v e r g e n t
w : 0
theorem
above
see t h a t
therefore
Since
The
Theorem.
and
means
The
we
To see t h i s ,
uI
l.a.m,
on
R
Then,
u.
divides
is n e c e s s a r i l y factor
inner
factors.
We b e g i n w i t h
of
the
For two bounded u2
if
a bounded
u 2.
such that
Let us
trivial
Let the
A = {log UT:
J
u 2 / u I S i. inner
consider
remark inner
that l.a.m.'s
If t h i s
l.a.m.,
is
so t h a t
be a set of l . a . m . ' s
inner
factor
u E J)
forms
uI
of
of every
a subset
of
38
I(R),
which
is a b a n d in
is b o u n d e d
of
SP'(R),
Then
u0
SP'(R), which
above the
l.a.m,
uI
with
u
in
J;
UI
with
u
in
J, t h e n
the
sreatest
satisfies factor
uniquely common
the
has
on
(ii)
such
uI
divides
in
(i)
inner
u 0.
of
necessarily
J.
Set
u0
It is s e e n This
then
I(R)
say
v0,
u 0 = exp v 0.
divides uI that u0
If a b o u n d e d
(ii),
Since
bound,
l.a.m,
two p r o p e r t i e s .
factor
0.
upper I(R).
that
if a b o u n d e d
by these
inner
element
R
function
least
every
divides
all
such a
u0
is c a l l e d
inner
it is c a l l e d
l.a.m,
! common
u0 inner
J.
A parallel functions
and
(i) but n o t
of
constant
A
is a n o n p o s i t i v e
is an i n n e r
is d e t e r m i n e d
by the
set
on
description
R.
But t h e
is p o s s i b l e
details
for multiplieative
look obvious
and
are
meromorphic
thus
omitted.
NOTES Gunning dles
[13]
on R i e m a n n
tions.
The
Some Chapter
discussion
basic
facts
theorem
E47]
contains with
we r e f e r
for c o h o m o l o g y Weyl
in 3A is a d a p t e d
and
the reader
a discussion a proof
source
See a l s o
on v e c t o r
2 of Constantinescu
tion
together
is o u r m a i n
surfaces.
4D.
groups
[CC].
and
for m u l t i p l i c a t i v e Kusunoki
of harmonic
to P h e l p s '
on h a r m o n i c
of T h e o r e m
from
lattices Cornea
[68]
lecture
note
with
func-
[42]. functions
For C h o q u e t ' s
functions
line bun-
are
in
representa-
[53].
Neville
singularities,
CHAPTER
Compactifieation on n o n c o m p a c t a right
way
in the
of M a r t i n ' s . the m o s t unit
As we
case
A naive
surfaces
and
chapter
we d e f i n e
discuss
boundary
compactification.
book
of C o n s t a n t i n e s c u
some
ingredients later
relation shown
use. between
idea
with.
Among we are
of the
several going
is that
open
unit
problems
indeed
suggests
kinds
of
to m a k e
it p r o v i d e s disk:
the
use
us w i t h
closed
Martin's
under
behavior results
Cornea
of h a r m o n i c
in
~§i and
[CC],
6, 13 a n d here
eompactification
are
harmonic
covering
[CC]
standard.
related
be f o u n d
out
Riemann
and r e o r g a n i z e
§3 we d i s c u s s
covering
on M a r t i n ' s
to
in the
for c o n v e n i e n c e
In
and
measures
of o p e n
functions
2 can
but we p i c k 14 of
compactification
that
this
Martin's
maps.
of the
It is
boundaries
are
maps.
chapter
R
will
denote
an o p e n
Riemann
surface.
COMPACTIFICATION
Definition IA.
in the
Let
every
be a set of c o n t i n u o u s real
space
usual
IQ
points
to in
find
a way
f(z) R
that
the
in the
sense in
compact
line
[-~,
+~].
C
with
that,
Since
for any
of
We t h e n
t(z)
of
For
R
z E R CK
points
at these
IQ
is e q u i p p e d
of
with
distinct values
set
theorem I
in
values
define
which
a map
functions
two
distinct
the
Tychonoff
Define
coordinate
taking
with
support.
f E Q UCK,
classical
space.
f E Q u c K.
R
C K = CK(R,~) with
If
f-th
on
R
By the
Hausdorff
functions
and
on
of all
for any
a function
+~]
be the
topology.
is a c o m p a c t
in such
equal
If
product
weak
[-~,
functions
let
cartesian
the
line
continuous
f E Q UCK
as the with
Q
extended
real-valued
can
and
The r e s u l t s
Throughout
§i.
Most
of C h a p t e r s
in p a r t i c u l a r
preserved
IQ
for a t t a c k i n g
vague
surfaces,
for our c h o i c e
compactification
this
i.
dealing
tool
this
disk. In this
our
see,
to R i e m a n n
reason
COMPACTIFICATION
a powerful
shall
we are
fitted
natural
MARTIN
is o f t e n
spaces.
compactification
III.
the into is
separate in
R, we
points,
the
40
map
1
is an i n j e c t i o n
I Q.
So we
space
IQ
space
I Q.
compact
can
identify
under
and
Q-compactification
the
f-th
pology in
f E Q
implies
[-~,
identified tion
f
z
to
tinuous
I Q.
IB.
Let,
a point
Let
ga(Z)
(Ch.
I,
We use
the
with
Q = QM
noted
by
that
of
R*
tended
by the
z @ R,
is c a l l e d
0),
which
kb
is a p o s i t i v e
in
2.
sure
R
in the
I Q,
RE
is a
We call
we d e n o t e
definition
for
z e R
is a c o n t i n u o u s
is dense
for all,
in
RE,
the
by
of the on
IQ
and
RE
f
thus
Ff(y)
= yf
product
to-
with
since
extension
Green
function
on
the
R
be a h y p e r b o l i c fixed
that
values
we h a v e
of the
has
func-
a unique
= i.
con-
R
with
be the
the The
A = A(R)
surface
the o r i g i n pole
is s y m m e t r i c family
parameter
at
of
a
= R* \ R
of
functions
dense
through of
and
is c a l l e d
a countable
R.
a C R
runs
R
and
of
in b o t h
Q-compaetification
compactification
contains
the
subset,
R
is deMartin it f o l l o w s
space. member
compact
symbol
b ÷ k(b,a)
space
b ÷ k(b,a),
fixed
b E R*
function
written
harmonic
for
QM
Riemann
is c a l l e d
g(a,z)
Let
Martin
metric
and
R, w h e r e
k(b,0)
Martin
÷ k(b,z)
R
is h e l d
~ g(z,a).
For e v e r y
is s o m e t i m e s
(b,z) [0,
= f(z)
Ff
to the
same
R*.
y E IQ
is c o n t i n u o u s
in IA e v e r y
by c o n t i n u i t y
over
into
compact
R
subset.
Ff
difference
is a c o m p a c t
is d e n o t e d
every
in p a s s i n g
Since
remark
dense
function
= k(b,a)
The
of
space
The
be the
is c a l l e d
ranges
tion
and
g(a,z)
R.
By the
For
convention
R*.
boundary
compact
R
R E.
We n o t e
b ÷ g(b,a)/g(b,0)
of the
of
of the
closure
y.
Since
= g(a,z)
i.e.
I(R)
be the
point
l(z),
once
subspaee
RE
as an o p e n
Ff(~(z))
to
is a h o m e o m o r p h i s m
R.
0 E R, w h i c h
6A).
variables,
R.
the
with
extension
take
R
of
Since
the
Let
subspace
of the
that
+~].
with
be fixed.
coordinate
in fact,
I.
includes
the
Let
R
the m a p
As a c l o s e d
space
and,
as
function
with
R*. where the pole
in
The
QM
the
b
(and w i t h
If
b E ~, t h e n
the
on
R.
We
that
function
b
see
also
on
R* x R
now
z ÷ k(b,z),
k b.
is a c o n t i n u o u s
function
variable
function at
can be ex-
extended
origin
function the
with
func-
values
+~].
Integral
Representation
2A.
Theorem.
~,
supported
For any by
A,
u E HP(R)
such
that
there
exists
a nonnegative
mea-
41
k(b,z)d~(b) = I J4
u(z) for
every
Proof.
z E R.
Let
{Rn:
n = i,
2,...}
be a r e g u l a r
exhaustion
of
R
with
0 ~ RI ( T h e o r e m IA, Ch. I). T h e n by T h e o r e m 6E, Ch. I, the f u n c t i o n R uE with E n = C I ( R n) is a p o t e n t i a l on R and is equal to u on n s u p p o r t e d by ~R n such R n • So t h e r e e x i s t s a n o n n e g a t i v e m e a s u r e ~n that
u(z) : u~ (z) = I g(b'z)d~n(b) n for
every
z E R
.
By s e t t i n g
z ER
n
.
n
We fix
u(z) Clearly, set
~n
{~n }
there
= I g(b,z)d~n(b)
bounded
and in the
a subsequence
to a n o n n e g a t i v e
every
see that
4C.
z E R.
measure
the m e a s u r e
2B.
We
Let
b E A.
with
kb(0)
HP(0)
are
combine
on
two
every
there
function
belong
to
QM"
k(b',a)
points exists
in
CK
of and
We
that set
kb
A = j(A).
j
R*.
~R n
observation kb
and
since
the m a p
converging
that
the m a p
£
Since
b ~ b'
is a c o m p a c t
If,
and
into
let
that
is HP(0)
b, b' of
~ f(b'). above
4A-
function
A
÷ k(b,z) A
such
shown.
kb(0)
Ch.
topology
A, the
cannot
[]
both
of
f(b)
a @ R
4.
harmonic
(b,z)
of the
to be
n ÷ ~, we
of
In fact,
boundary
a point
HP(0).
with
that
Since
for w h i c h
on the
exists
as
boundary
j: b ÷ k b
definition K
A
with
HP(0).
The
into
to
is a p o s i t i v e
to
k b ~ kb, , as was
Then
The
so t h a t
{~n }
It f o l l o w s
tends
injection.
A.
kb,
of
by the M a r t i n g
f E QMUC
there
4
on
2,...}
is an
vanishes
and t h e r e f o r e
see also
on
belongs
that
in
of m e a s u r e s
i = i,
~
spaces
an
Namely,
is a h o m e o m o r p h i s m
= u(0).
function
Moreover,
for w h i c h
R*,
boundary
see
n
= I k(b,z)d~(b)
kb
metric
large
Sd~ n = f g(b,0)d~n(b)
preceding
the
all
, we h a v e
space
is c a r r i e d
our
Then
dis-tinct
that
~
4 x R, we
is c o n t i n u o u s .
says
the
= i, so that compact
continuous
any
Since
consider
= I k(b,z)dZn(b).
{~n(i):
u(z)
for
and
= g(b,O)d~n(b)
is n o n n e g a t i v e
is thus
exists
vaguely
z E R
d~n(b)
be R*
Since f
must k(b,a)
So the m a p
= kb,(0)
j
= i, we
be p r o p o r t i o n a l .
subset
of
HP(0)
and
it
42
follows
from Theorem
ability
measure
~
2A t h a t , on
~
for each
such
u(z)
for
every
of
HP(0).
z @ R.
set o f e x t r e m e the
totality
on
R.
Points
4C,
Ch.
II,
Theorem. (b) sure
~
This
We d e f i n e
of the
b E A in
thus
shows
(a)
The
For
every
supported
that
~
convex
kb
called
the
following
AI
AI
contain
inverse HP(0).
exists
there
The
a prob-
A
extreme
under
set
in
A.
(and a l s o
a unique
points
j
A1
harmonic
points
of
exists
all
image
is a m i n i m a l
the m i n i m a l
is a G 6 - s u b s e t
u E HP(R) by
set
are
set
should
as the
for which
A1
there
v(z)d~(v)
A 1 = £1(R)
points
of
[J
:
means
u E HP(0),
that
of the
is e x a c t l y function Corollary
of
R*).
nonnegative
mea-
such that
u : I
k b d~(b), AI
where
the
HP(R).
integral
converges
In p a r t i c u l a r ,
with
every
topology
of
= [ J
kb(Z)d~(b) A1
z E R. +
Let using
to the m e t r i c
we h a v e
u(z)
for
respect
u E HP'(R).
the a b o v e
Writing
result,
we
u = u
_ -u
+ with
u
, u- E H P ( R )
and
see t h a t
u : J
k b d~(b) A1
for
some
finite
statement mined
(b)
Borel
above
uniquely
by
u.
the canonical
measure
2C.
M ( A I)
Let
It is a l i n e a r £ ~
for
subset the
E
measure
shows
space
This for
~, ~ E M ( A I) of
A I.
correspondence
on
A I.
is d e n o t e d
~
set of f i n i t e a n d has
if a n d o n l y
if
gives
a linear
is o b v i o u s l y
order-preserving.
and only
~u
are mutually
and
~v
result
~
is a l s o
on
by
real
Zu
Borel
a natural
M(AI) , which if
uniqueness A1 and
in t h e deter-
is c a l l e d
u.
In v i e w o f the r e m a r k u ÷ ~u
The
such a measure
measure
be the over
~
that
~(E)
~ ~(E)
at the
singular.
u ± v
on
for e v e r y
of in
A I.
relation,
end of 2B, w e
isomorphism So
measures
ordering
i.e.
Borel
see t h a t
HP'(R) HP'(R)
onto if
43
Let
X = XR
be the measure
stant
function
sure
(on the b o u n d a r y
u ~ HP'(R) defined
identically
is called
in Ch.
II,
equal
~i ) of
R
singular
if
5A.
in
M(A I)
to
i.
corresponding
We call
X
at the point
0.
A harmonic
u E I(R) N H P , ( R ) ,
Our o b s e r v a t i o n
in Ch.
II,
to the con-
the h a r m o n i c
where
mea-
function
I(R)
5A shows
the
was follow-
ing Theorem.
The c o r r e s p o n d e n c e
isomorphism
of
HP'(R)
if and only
if
~u
respect
AI
every
gives
M(AI).
u
is a b s o l u t e l y
to the m e a s u r e
Thus on
onto
u ÷ ~u
is q u a s i b o u n d e d
continuous
(resp.
linear
(resp.
singular)
singular)
with
X-
u E Q(R)
such that
an o r d e r - p r e s e r v i n g
determines
d~ u = f*d X
or,
u : I
a unique
X-summable
function,
f*,
equivalently,
f*(b)kb
dx(b)"
A1 Indeed,
kb(a)dx(b) ,
at the point A I.
a.e.
We will
an extended
consider
function
functions
s
let
on
R
is bounded
s
lim infRgz÷ b s(z)
and
= -~(-f).
H[f]
(i)
S(f) and
are Perron
are n o n v o i d
~ H[f]. and
H[f]
is called
the
pactifieation
R*
3B. following
that
on
A1
when
for
R*.
it is
Let
Let
S(f)
f
be
be the class
such that
for every both
(resp.
s' E [(f)
families;
(iii)
= H[f].
The common
solution
Riesz's
and
H[f]
if both
(resp.
supremum)
(ii)
~(f)
are h a r m o n i c S(f)
is denoted
problem
function
theorem
are n o n v o i d
s" E S(f);
function
of the Diriehlet
S(f)
infimum
and
resolutive,
the b o u n d a r y
and
Then we have the f o l -
H[f]
f
b e A.
~(f)
S(f)).
We call
with
problem
be the p o i n t w i s e
for any
We r e f o r m u l a t e form.
R
X.
A = A(R). R
~ f(b)
S(f)
s' ~ s"
H[f]
a.e.
of
on the b o u n d a r y
below,
H[f])
in
on
on
Suppose
(resp.
of functions
lowing:
is satisfied
the D i r i c h l e t
(A2)
S(f)
measure
among m e a s u r e s
to the measure
(AI)
We set
and
as basic
Problem
real-valued
of s u p e r h a r m o n i e
R
X
with respect
The Dirichlet 3A.
and
a E R, is seen to be the h a r m o n i c
We regard
So we say that a c o n d i t i o n
satisfied
3.
a.
S(f)
by
H[f]
for the M a r t i n
f.
(Theorem
6F,
Ch.
on
and
I) in the
com-
44
Theorem.
Let
u
a closed
subset
positive
measure
be a p o s i t i v e of
R. M
superharmonie
Suppose
supported
that
u(0)
by the
function
< +~.
closure
on
Then
E*
of
of
U
R
and
there E
E
exists
in
R*
a
such
that
uR(z)
for
every
mined
Here,
the r e s t r i c t i o n
~IR
to
R
is d e t e r -
uniquely.
Proof.
Let
subsets s(z)
z E R.
: I k(b,z)du(b)
{E
of
= lim
E n÷~
: n = i,
2,... }
n such that u R (z)
U ~
n=l
for
: E.
En
z E R.
n superharmonic
nonnegative
be a n o n d e e r e a s i n g We h a v e
It is e a s y to
function
and
s(z)
sequence
uR
n
< uR
n+l
see t h a t
R < UE(Z).
of c o m p a c t < u R.
s(z)
Since
Set
is a
uR
> u n
q.e.
on
En
__> u(z) s
for
q.e.
every
on e v e r y
n
by T h e o r e m
En
6E-(b),
and therefore
on
Ch. E.
I, we
see t h a t
It f o l l o w s
s(z)
that
uR <
and hence R R u E = s = lim u E n÷~ n
(i)
By T h e o r e m
6E-(c),
Ch.
I,
all
u~
are
So e v e r y
potentials.
E
n
car-
n
ries
a positive
measure
~n
such that
R (a) uE
= I g(a,z)d~
n (z).
n
Since
we h a v e
(2)
] g(0,z)d~n(Z)
: u~
(0) ~ u(0)
< +~,
n
~n
has
no m a s s
get a f i n i t e
at t h e
measure
point
on
0.
E
Setting
dMn(Z)
= g ( 0 , z ) d m n ( Z ) , we
satisfying n
uE
(a) n
From
(2)
sures
on
sary,
we m a y
on
(3)
E*
follows the
that
compact assume
{~n: set that
We t h e r e f o r e
I k(z,a)du(z)
n
E*. {~n }
=
f
k(z,a)d~n(Z).
= 1, Thus,
2,...}
forms
passing
converges
to
vaguely
a bounded a
to
have
: lim N÷~
set
subsequence
| m i n { k ( z , a ) , N} d ~ ( z ) J
a positive
of if
meaneees-
measure
45
= lim lim 5 min{k(z,a), N} dPn(Z) N+~
n÷~
< lim f k(z,a)dPn(Z) n÷~ : lim UER ( a ) : n ÷~ n On the other hand, large that
K
a E R
be held fixed and then take
= {z E R: g(a,z)
a potential which (Theorem
let
uER(a).
is harmonic
~ e}
is compact.
except at points
6B, Ch. I) a positive measure
1
on
in
Since
e > 0
~K , there
~K
so
min{ga,~}
is
exists
such that
min{g(a,z), e} = f g(z,b) dl (b). Setting
z = a, we see that
f dl
f
(4)
By Fubini's
(b) : i.
theorem we have
flf
We note that I
is continuous ting
n ÷ ~
k(z,b)dl
min{~(z,a), ~} g(z,0)
(b) :
and finite throughout in (4) and using
R*
as a function
in
z.
So let-
(i), we get
(5) = I min{~(z,a), ~} dp(z)
g(z,0)
R uE
Since
is lower semicontinuous ~
are shrinking to the point
a
as
f dX
: i
to
eonvergenee
f k(z,a) d~(z)
desired
integral
Theorem
6B, Ch.
Corollary. that
Let
b ~ E*.
as
~ + +~.
(b).
Combining Finally,
these with
unicity of
(3), we get the
B[R
follows
from
[]
b E AI(R) Set
1
theorem shows that the last member of (5) tends
expression. I.
of
~ ÷ +~, we see that
u~(a) £ lim inf f u~(b)dl The monotone
and the supports
and let
E = E* h R .
Then
E*
be a closed
(kb) R E
subset of
is a potential.
R*
such
46
Proof.
By the p r e c e d i n g
(6)
(kb)~(a)
for some p o s i t i v e v(a) kb
t h e o r e m we h a v e
measure
: S k ( z , a ) d~'(z) is m i n i m a l ,
kb(a)
for
we h a v e
~ 0, t h e n we set
that way.
Thus
3C. write
~ = 0
subset
u
e
~' : pI A
with
support
of
does not con-
point
kb
(kb) ~
is a p o t e n t i a l .
harmonic
is a p o s i t i v e b ÷ (kb)~(a)_
be w r i t t e n
function
measure
If
expression
v
cannot
and
Since
0 ~ ~ ~ i.
a contradictory
the c l o s e d
~
We set
on
[]
on
R
A.
is i n t e g r a b l e
in
and
If
E
for e v e r y
and
a
of
R \ E, t h e n
If
a E R \ E
a, then,
and h a v e
R, t h e n
uER(a) = I If
E*.
0 ~ v £ (kb) ~ ~ k b.
be a p o s i t i v e
where
of
(7)
Proof.
Then
and t h e r e f o r e
Let
by
for some
In fact,
u = fA kb d~(b), a E R
a E R.
v = ~k b
so t h a t the e x t r e m e
Theorem.
is a c l o s e d fixed
b
k(z,a)dD(z)
supported
dv = ~-id~'
= ~ k(z,a) d~(z).
t a i n the p o i n t
p
f
=
is an i n t e r i o r u~(a) and
as we h a v e
uR(a)
= u(a)
if
G
k
point and
of
E
or a r e g u l a r
(kb)~(a)
is the c o n n e c t e d
seen in T h e o r e m
: f u(z)d~G(z):
([CC],
(kb)ER(a)d~(b)"
fA(f
Ch.
of
44-45)
boundary
= kb(a) , so that
component
6E-(a),
pp.
R \ E
point
(7) holds. containing
I,
kb(Z)d~aG(Z)] d~(b)
A Finally, Theorem E.
let 5B,
a E E Ch.
be an i r r e g u l a r
I, the
singleton
{a]
boundary forms
point
of
a connected
R \ E.
Then,
component
So we can find a s e q u e n c e
by
of
{G : n = i, 2,...} of J o r d a n d o m a i n s in n N n=l ~ C R \ E, CI(Gn+I) = C G n and CI(G n ) = R such that a E Gn, ~Gn = {a]. Let ~ be the h a r m o n i c m e a s u r e of G at the p o i n t a. Then n n we h a v e
(kb)R(a)
= lim I ( k b ) R ( z ) d ~ n ( Z ) n -~
and t h e r e f o r e
the f u n c t i o n
b ÷ (kb)R(a)s
= nlim f -~
is m e a s u r a b l e .
Hence,
47
n÷ ~ ~ A
[lim I ( k b ) ~ ( z ) d ~ n ( Z ) ] dB (b)
: IA "n÷~ : I
(kb)~(a)dz(b)' A
as was to be proved.
3D.
[]
We are n o w in a p o s i t i o n
to p r o v e
the m a i n r e s u l t
of this
section. Theorem. cation
boundary of
R
The M a r t i n
in the A
Let
f
The h a r m o n i c
is g i v e n by
be a n y r e a l - v a l u e d
it to a c o n t i n u o u s f.
a
We m a y a s s u m e
function that
R*
is a r e s o l u t i v e
every real-valued
is r e s o l u t i v e .
at the p o i n t
Proof.
compactifieation
sense t h a t
on
measure,
kb(a)dx(b). continuous
R*, w h i c h
0 ~ f ~ 1
continuous
on
with
function
on the
support
([CC],
is d e n o t e d
R*.
eompactifi-
function
p.
on
in
AI,
140) A.
We e x t e n d
by the same l e t t e r
For e v e r y
n = i, 2,...
we
set
A i = {b e Al: E9 : {a e R*: 1
( i - ~) =< f(b) f(a)
<
( i + 7)},
< i - i} U {a e R*: = n
f(a)
> i + i],= n
E. : E g A R , l l and
ui = I
kb dx(b) A. 1
for
i = 0, i,...,
by C o r o l l a r y Theorem
n.
3B
For e v e r y
( k b ) ~. 1 3C we see t h a t
is
(ui)R Ei is a l s o a p o t e n t i a l . f < (i + l)/n
on
Since
fixed
i
a potential
: I
A. 1
(kb)~
we see
for
.i
(ui) ~. = u i i R \ E~, we h a v e
any
A iNE~
b E Ai .
= ~
and so
By u s e
of
dx(b) q.e.
on
Ei
and
(i - l)/n
<
48
i - l(u i q.e.
on
R
R - (Ui)E) 1
i + i =< fu i =< - - U n
R i + (Ui)E. 1
and t h e r e f o r e n
n n i - l(u i (u i R i + I n )E. ) ~ f ~ [ --n--ui + [ i=0 l i:0 i=0 q.e.
on
R.
So we f i n d a p o s i t i v e
superharmonic
R (Ui)E. 1
function
s'
on
R
such that n n ~ i+ lu. + [ --£-- i i=0 i:0
f < =
on
R
for any
to the class As
E > 0
e > 0. S(f)
n
i=0 n + ~
)E.
l
+ ~s'
shows that the r i g h t - h a n d
and t h e r e f o r e
is a r b i t r a r y
It is a s i m p l e m a t t e r
as
This
(u i R
majorizes
member
the f u n c t i o n
and
[i=0n (Ui)E.R is a p o t e n t i a l , 1 n ~[f] ~ ~ +__~lu. i " i=0 n l
belongs
H[f]
on
R.
we h a v e
to see that
i+ lu. = n l i=0
A. i
i + I k b dx(b ) ÷ I kbf(b)dx(b) n AI
and h e n c e f ]
~[f]
kbf(b)dx(b)" A1
Similarly,
we h a v e f H[f] ~ ]
kbf(b)dx(b)" A1
By c o m b i n i n g Corollary.
these
inequalities
A function
X-summable.
If this
f
on
r : J )
is r e s o l u t i v e
result.
if a n d o n l y
[] if
f
we have
f(b)kb(a)dx(b) A1
a E R.
The p r o o f omitted
AI
is the case,
H[f](a) for e v e r y
we get the d e s i r e d
(cf.
is s i m i l a r to t h a t of the c l a s s i c a l
Ch.
I, 5D).
case and is thus
is
49
§2.
4.
FINE LIMITS
D e f i n i t i o n of Fine Limits 4A,
Let
b E A I.
b a l a y a g e d function is a potential.
A subset
(kb) ~
u
of
is different
R
is called thin at
from
In fact, by Riesz's t h e o r e m
superharmonic function function
E
if the
In this case
(Theorem 6F, Ch.
(kb)RE
I), the
is the sum of a n o n n e g a t i v e h a r m o n i c
(kb) ~
and a p o t e n t i a l
k b.
b
U.
Since
u ~ k b, the m i n i m a l i t y of
kb
implies that u = ~k b with 0 ~ ~ ~ i. If ~ > 0, then (kb) ~ = ~k b + R U ~ ~(kb) E + U q.e. on E and t h e r e f o r e everywhere on R. But this leads to a c o n t r a d i e t i o n If
E
R (kb)Et~,
and
E'
(kb) ~ = k b.
are thin at
b, then so is the union E U E ' , for ~ R Let G(b) be is m a j o r i z e d by the p o t e n t i a l (k b) + (kb)E,.
the c o l l e c t i o n of sets of the form seen that
G(b)
is a filter,
and
G(b)
is closed under finite
V NR
E G(b)
R \ E
E
intersection.
for any n e i g h b o r h o o d
We see further that,
with
thin at
i.e. every m e m b e r of
V
of
and
i, 2,
G2
E ~ R
be two components b e l o n g i n g to
R \ Gj
is thin at
b
so that
3B says that
is thin at G(b).
G(b).
R (kb)RkGj
We have
in the space
has a unique c o n n e c t e d component that belongs to GI
b.
is n o n e m p t y
Corollary
b E 41
if a closed set
G(b)
R*. b,
R \ E
In fact,
Then,
let
for each
is a potential.
j :
So
R R + R k b ~ (kb) R ~ (kb)R\Gl (kb)R\G 2 and thus
4B. b E 41
kb
should be a potential,
Let
f
be a map from
G(b)
= N~CI(f(D)):
is a filter,
taken outside any compact effective if
f
be the set of b E D(f)
X
we denote by
subset of
for w h i c h f(b)
the fine limit of
For any open set G E G(b).
X
For any
implies that
R.
f
f^(b)
b.
41(G)
X G ~ R
R.
is a singleton.
the point c o n t a i n e d at
f^(b)
So the d e f i n i t i o n of
is defined off some compact subset of b ~ AI
function, then we take as
with
X.
and depends only on the values of
The f u n c t i o n
is called the fine b o u n d a r y function for
line.
space
D e G(b)~.
the compactness of
a nonvoid compact subset of
f(b)
into a compact
we set f^(b)
Since
R
a contradiction.
f.
If
in
f^(b)
Let
is
f is
D(f)
For every
f^(b)
and call
f
defined on
f
is a n u m e r i c a l
D(f)
the Riemann sphere or the extended real we denote by
is a Borel subset of
41(G) 41 •
the set of
b ~ 41
To see this, we may
B0
assume Then
that
G
is c o n n e c t e d .
G • G(b)
if and
= f kb(Z) d ~ ( z ) £ × R, we AI(G)
and
see that
only
the m a p R (kb)R\G(a)
measurable
Let
X
be a c o m p a c t
function
from
R
into
and
Proof.
therefore
For
of c e n t e r X
each x
and
in
A.
We
can
shows
It is easy
the
the
right.
k = i, set
=
desired to
b
there
a convergent
closed,
we h a v e
k
that
such
have
the
we
latter
as was
be any
exists
Analysis
by
W(f)
5A.
functions set then
supremum) are also W(f)
f
Perron that
that
f^(b)
So
f
be a c o n t i n u o u s
D(f)
+ X
is m e a s -
£ I.
([CC],
denote
the
subset
of
n = i,
p.
147)
open X.
2,...}
ball Since
which
is
W(f)) R
on
Since
A.
there
For
every
to the
k = i,
2,...}
x.
Since
exists
f-l(B(Xn;k-l))
an
e
and
the r e v e r s e
A
is
index we
E G(b),
As
b • D(f)
shows
in
belongs
by
~ Cl(B(x;e)). Hence
This
side.
{Xn(k):
Then
is a B o r e l
is i n c l u d e d
b
is d e n o t e d
c > 0.
f^(b)
(8)
that
is c o m p a c t ,
= {x}.
in
of
right-hand
such
limit
any
so
side
is a r b i f(b)
: x,
inclusion,
Behavior
the
such s) in
h[f]
families,
and
set
that R.
(resp.
real-valued
s ~ f
(resp.
If both h[f])
[(f)
as the
in
W(f)
(resp.
h[f]
and
We ~[f]
call
function
of s u p e r h a r m o n i e
both
~ [[f].
are n o n v o i d
Al(f-l(B(Xn;k-l)))
[]
of f u n c t i o n s
h[f]
X
be an e x t e n d e d
on
we d e f i n e
of
{Xn:
in the
~ B(x;~). and
contained
(resp. s
let f:
be a c l o s e d
left-hand
whose
Take
of B o u n d a r y
(depending
and
B(x~r)
n = n(k)
• G(b)
shown.
Let
on
function.
Al(f-l(B(Xn;k-l))),
point
an
B ( X n ( k ) ; k -I)
being
5.
fixed.
(kb)~\G(a)
is c o n t i n u o u s
measurable
subset
for e a c h
Since
x E A.
conclude
to be
space
let A
U n=l
the
subsequence
f-l(B(x;c))
trary,
A k=l
result,
Al(f-l(B(Xn;k-l)).
has
Let
is h e l d Since
A I.
a sequence
see t h a t
So let
2,...
r.
÷ kb(Z)
function
r > 0
find
f-l(A)
set.
the
which
< kb(a).
claim
(8)
which
of
is a Borel
and
radius we
(b,z)
metric
Then
D(f)
x • X
is s e p a r a b l e ,
dense
X.
a • G
is a B o r e l
subset
Theorem.
urable
any
(kb)R\ R G (a)
since
b ÷
is a B o r e l
Take if
f
= hill.
W(f)
pointwise
W(f)).
infimum
Since
W(f)
if b o t h
is the
We d e n o t e
a compact
are n o n v o i d ,
are h a r m o n i c
harmonizable If this
R.
subharmonic)
s ~ f) o u t s i d e and
h[f]
on
(resp.
case,
on
(resp. and R.
W(f)
W(f) We
see
and
we d e n o t e
the
51
common
function
by
h[f].
if it is h a r m o n i z a b l e denote
by
Wiener
functions
not
W(R)
assume
Theorem. there on
the
and
a compact
f
f r o m the
K s =C R.
set
Let
f
n = i,
By the
2,...}
a*
K
C R n
function
such
that
i,
2,...}
s
=
n
:
Theorem
IA,
Ch.
Then, u(a)
for
u- U ~ f ~ u+ U
with
s O be t h e
in
K
sO = U2
any
such that some
u + U' ~ f
u - U" ~ f
on
set R
p.
on
R,
54)
u = h[f]. h[f],
outside function
It is a l m o s t
there
exists
a
< ~,
.
n
sum
[n=l (Sn - u)
we h a v e
We c h o o s e
K]. C = Rn
R (s n - U ) C I ( R
[ n:l
a compact
a regular
is
set
for
exhaustion
j = i,...
2n
(see
6E-(c),
~ u(a)
~ f
Ch.
on
R
I.
U'
and,
K'.
Similarly,
and,
for any
j = I,
(s n
be a n y 2,...,
positive we have
- u R (a) ) C I ( R n)
n the Ifl
compact on
Since
set
m
s (a) ~ f(a).
outside of
Let
with
+ m -I 2m~2j n=m+2j
majorant
If we
), n
U 2 = (s O ) ~ I ( R 3 ).
CI(R2).
compact
a harmonic
([CC],
So t h e
a E Rm+2j \ Rm+ j
superharmonic
on
and
such that
R.
such that
by Theorem
u + m-iUl
by s e t t i n g
u.
For every
n=m+2j
U2
E HP'(R)
n
+ m-iUl(a)
we have
h[f]
R
W(f)
m- 1 2m~2j
Namely,
of
we do
Set
is a p o t e n t i a l
integer.
in t h a t
exist
of
outside
R
UI : which
[CC]
if t h e r e
with
=
of
I).
We
h[f] - U ~ f ~ h [ f ] + U
function
R.
R
R.
h [ f ] - sU ~ f £ h [ f ] + EU
definition
point
on
> f n
{Rn:
we h a v e
R
h[f]=
in
is a n y p r e s c r i b e d
a superharmonic
on
(s ( a * ) - u ( a * ) ) n
n:l where
on and
be a W i e n e r
on
on
Our definition
book
such that
Conversely,
u E HP'(R). {Sn:
R
U
R.
in t h e
s > 0,
function
on
function
majorant
f. f
on
and a potential
that
sequence
U
is a W i e n e r
functions one
of
for a n y
f
a superharmonic
function
a potential
(i)
clear
has
quasicontinuity
is a W i e n e r
Proof.
say t h a t
Ifl
set o f W i e n e r
such that,
u E HP'(R) then
the
differs
For any Wiener
exists
R
We
and
= U 1 + U2,
for a n y we can
s > 0,
R
CI(R2)
and
CI(Rm+I).
define
then
U'
Ifl =<
is a p o t e n t i a l
u + sU'
£ f
a potential
U"
u - cU" ~ f
Let
a potential
C = R3, w e h a v e
e > 0, find
set
outside
outside such that
a compact
52
set of
K". the
So
(ii) tive
U
first
= U' + U"
half
Next
of
suppose
superharmonic
identically. f RR\ R
n
see
= i,
a potential,
that
at
which
meets
the
requirement
theorem.
function
We
for
is
the
f
is
whose
once
2, . . . .
a potential
greatest
that
f
Then,
by
U,
i.e.
harmonic
> h[f]
> h[f]
Theorem
6E,
f
is
minorant > 0.
Ch.
I,
a posi-
vanishes
We
set
sn
is
sn super-
n
harmonic sn
= f
since h[f]
R,
on
u = lim
u+
on
such
R \ Rn. s
.
We
Then,
= 0.
(iii)
Finally
with
The
following
(a)
The
f f
: u.
The
belong
W(R)
u ~
f,
we
a Wiener
function
function
on
a potential
properties
R
U.
finishes
h[f]
that
is
a
Set hand,
0.
Hence,
: 0.
u-
U ~
implies
f
that
[]
consequences
f ÷ h[f]
and
n.
other
with
(ii)
R
every the
u ~
proof.
easy
on
have
such
Then
the
are
On
should
a
This
for
u ~ h[f].
is be
s n =< f
Rn,
=> S n + 1 => 0
E ~(f),
correspondence
map
to
f ÷ h[f]
of
linear
Theorem
map
of
5A.
W(R)
W(R),
then
(c) the
where
Let
f E W(R)
decomposition
be
of
harmonic
and
h[f]
= 0
if
and
if
Then
the
(d)
Let
Proof.
h[f"]
only
and
i.e.
min{f,f'}
We
number
of
only
state
easily.
the
Take
any
= ~(~i , + ~,,)~
f'
f'
and
f"
potentials + U"
on
are U'
R.
and
~.
if
f
belong
theorem
and to
(Theorem
L
=
1R L
is
a potential
{z E R:
proof
of
(d),
real
for
numbers
= m a x { ~~,- ~
f'
Let
Then
set
64)
U"
h[f']. f = u+
6F,
u
Ch.
U
I),
= h[f].
We
have
a potential.
p.
Wiener
= h[f]A
function.
a potential.
([CC],
two
and
Since
Riesz's is
is
function
h[min{f,f'}]
superharmonic
by U f
f E W(R)
balayaged
countable
Since
homomorphism,
max{f,f'}
h[f'], a
f
is
exist
a lattice
both
= h[f]v
u
rather
is
and h[max{f,f'}]
have
Sn
on
HP'(R). (b)
be
n and
and
5B.
f'
h[f]
harmonic
clearly
R
let
u E HP'(R)
is
s
Namely,
and
onto
have
on
f E W(R)
Theorem.
sn
since
n÷~ n u is h a r m o n i c
: h[f]
U
that
and
< ~" f"
Theorem
such
f'
= 1
on
L
,
~ E
an
follow
and
~.
at
most
from
5A
set
f - ~~ , 0}. = max{~,-~-T~_ 5A
< h[f']
(resp.
for for
others
functions, that
: ~]
except
the ~'
0)
f(z)
f"
shows + U' = 1
that and on
there f" L
< ,,), w e
53
i[,
J h[f'] + U'
iR L ,, < h [ f " ]
(resp.
+ U")
and therefore (g)
min{l[
As we have,
~,
in v i e w
, iR } ~ min{h[f'], ha,,
of
= h[f'] A h[f"] = h[0]
left-hand
side
h[l~ Since
,
with
~ E •
functions.
~,
of
(9)
] Ah[l~
are
arbitrary,
forms
a family
consequently
Let
be an e x t e n d e d of
If
we have
It f o l l o w s
that
iR }] = 0. ~, ' L ,,
shown
of m u t u a l l y
R
] =
that
the
orthogonal
set of all
h[l
nonnegative
]
harmonic
G
be an o p e n
to each
case
for c o u n t a b l y
set
in
continuous
connected
is a p o t e n t i a l , the
h[l RL ] =< i
v
except
real-valued
f
IFR
in p a r t i c u l a r p.
] = h[min{l~
h[l R ] = 0
Lemma.
restriction tion.
= 0,
So we get
5C. f
+ U".
: h[min{f',f"}]
is a p o t e n t i a l .
~,,
h[l
and
+ U'
(b),
h[min{h[f'],h[f"]}]
sn the
h[f"]}
when
then F
R
many
and
function
a.
set
on
F = R \ G.
R
such
component
of
~
a.e.
on
AI(G).
subset
of
R.
exists
is a c o m p a c t
G
[]
Let
that
is a W i e n e r
the func-
This
is
([CC],
150)
Proof.
Let
applied
to each connected
L
= {z E R:
a countable
dense
on
every
G'
for
If we set
and,
E S : 0
set
on
F'
define
F.
at
~ E S
Then
points
S
f~
= ~}
of
and
= {a E R:
by Theorems
and
except
subset
f(z)
with
component, ~
such
every l~(a)
we h a v e
R
by
the
belonging
~ E ~.
of
G
By T h e o r e m
in place G,
that
IG,NL
of
5B-(d)
R, we f i n d
is a p o t e n t i a l
G' ~ 1/2},
6D a n ~ 6 E - ( a ) , on
G',
Ch.
I,
setting
following:
to a polar
set;
then
F'
F~F'G,
is a n o n v o i d
is
f~ = I F , ~Lq ,~A (a)
f
a polar on
set. G'
is c o n t i n u o u s
(b)
0 ~ f
is u n b o u n d e d
on the
closed
£ 1; a n d
Let and on
R
(c)
GT
f
IG'
~ IG,NL Let
U
, which
is a p o t e n t i a l .
be a p o t e n t i a l
which
set of
irregular
54
boundary
points
of
G
and
s = i RL
set
Moreover
.
we
[U + s J 1 R U + s F + min{s-
S
Then
s
is not R,
is s u p e r h a r m o n i c larger
so that,
than
U+ s
on
R,
on
in the n o t a t i o n h[f
on
G'.
Since
G' IG,AL
on
G'
Since
h [f ] ~ s
for
G. of
R SF, s
G' 1G,AL
is l o w e r
Furthermore,
5A, we h a v e
] ~ U + s~
= U + s
and
are
tion
on
R
potentials with
h[f
on
R.
] = 0.
on
on
This
G',
F
Gt
majorizes and
we h a v e
and
means
Hence,
on
] < s
Rsince
and
f
on
therefore
that
by T h e o r e m
h[fa]
U
i r r e g u l a r b o u n d a r y p o i n t s of G, h[fa] ~ U+ s F on ~[f] R We thus c o n c l u d e that U + s~ ~ U + 1 F on R. R IF
F
semi-continuous
s
h[f
on
G' IG,AL
+
is a p o t e n t i a l
}
set
is u n b o u n d e d
F.
] = 0, for
is a W i e n e r
5A,
at
Consequently,
h[f
f
~ U + s~
f
is
U
func-
majorized
by a p o t e n t i a l . We t h e n
claim
that R
(1O) q.e
on
R.
This
is c l e a r
the
definition
G"
be a c o n n e c t e d
of
ILR This
shows Next
~ 2(1
) + fa
on
F' n L
and
and the
component
: H[I~
(i0), we
F'
IL
;G"]
which
fact
of
in turn
means
0 SA
subset
~ E S.
kbdX(b)"
To
Noting
0 < u = As
shown
x(A a)
A
above,
ILR
that
of
A1
is
=< 2(i~)
iR L
that
is
F'
in v i e w
a polar
we h a v e
;G"]
that
on
set.
of Let
G"
+ f~.
a potential
on
R.
x(A
) =
0 ~ u ~ 1
=
is a p o t e n t i a l
= 0.
set
= k b}
in 4B.
we c o n s i d e r
A : U{A
Then
we h a v e
the h a r m o n i c
and
using
Theorem
(kb)R
dx(b)
= u~
A
We f i n a l l y x(A)
(kb)RL
as n o t e d
see this,
kb d×(b)
=
= 0.
follows
Then
of
set
is a Borel
for a n y
FAF'
.
=< H [ 2 ( I ~ ) + f
A a = {b E AI(G): which
that
G \ L
outside
La
and
: a E S}.
As
~ 1L . a
u = 0. S
u =
3C, we have
a
therefore
function
Hence,
is c o u n t a b l e ,
it
55
To c o n c l u d e (k b)
< kb
c o m p o na e n t
of
longs to
G(b)
either
in
[a, +~]
the proof,
and so
R\ L
R k L
(a, +~]
or in
[-~,
Hence,
h[f]
Theorem.
(a)
function h[f]
on
Let
f
< kb
), w h i c h So,
a E S.
(see 4A).
be-
G
is c o n t a i n e d
is c o n t a i n e d
f^(b)
Then
connected Thus
is c o n n e c t e d ,
f^(b)
shows that
AI(G) \ D(f) ~ A
either
is a s i n g l e t o n ,
and c o n s e q u e n t l y
in
i.e.
X(AI(G) \ ~(f))
=
[]
connects
for a W i e n e r
R.
f(G
Take any
be the u n i q u e
G
R G (kb)R\
This
The next r e s u l t
function
Let
[-~, e).
a].
0, as was to be proved.
5D.
b • A I ( G ) \ A.
s u c h that
and the r a n g e
or in
b E 0(f).
let
• G(b).
the fine limit
function
f
and the h a r m o n i c
f.
be an e x t e n d e d
real-valued
T h e n the q u a s i b o u n d e d
continuous
part of the h a r m o n i c
Wiener function
is g i v e n by
I
~(b)kb
dx(b).
A1
(b) defined positive Proof. and
If
f
a.e.
on
is a b o u n d e d AI, t h e n
harmonic Let
f
X(A I \ ~(f))
continuous
fu
function
u
on
be a c o n t i n u o u s = 0.
R.
function
on
E, = {a • R: f(a) 1
< i-i} = n
R
and if
f
is
for any q u a s i b o u n d e d
p. 151) R
number
!(in - 7)i =< f(b)
on
function
([CC],
Take any n a t u r a l
A i : {b • N(f):
function
is a W i e n e r
such that n
0 ~ f ~ i
and set
< 2(ni + 7)i },
U {a e R; f(a)
> i + l},= n
and
ui for
i : 0, i,...,
is a p o t e n t i a l .
n.
If
Using
: I
As
kb~(b)dx(b)
b E Ai, t h e n
Theorem
(ui)R = Ei is also a p o t e n t i a l .
A.
R \ E i 6 G(b)
so t h a t
3C, we see t h a t
A. i
1
R ~(b)dx(b ) (kb)E. l
in 3D we h a v e
n i - l(u " _ ( u i ) R ) n 1 i:0 l .
< fu < = =
n n [ i+ 1 • + [ n Ul i:0 i:0
(kb)~.
( u i ) ER
i
56
q.e. R
on
R.
So t h e r e
exists
a positive
superharmonic
function
s'
on
such that n
holds
on
class
R
~
=
i=O
for any
W(f)
n
fu <
i+ lu. + --n---
E > 0.
i
[ i:0
(u i R )E.
I
The r i g h t - h a n d
+
ss'
member
thus b e l o n g s
to the
and so n
~[fu]
<
[ i + 1 ui' n i=C
=
for
[ n (ui) ~ i=0
is a p o t e n t i a l .
Similarly,
1 n
[ i - l u . < h[fu]. u-:~ l n i = Combining
these
inequalities,
we see that
fu
is h a r m o n i z a b l e
n n [ i+l : lim ~ i+lu. : lim ~ ] kb n ÷ ~ i:0 n l n+~ i=0 A. n
h[fu]
and
u(b)dx(b)
i
= I kbf(b)~(b)dx(b)" This
shows
(b) and also
(a) as w e l l
In o r d e r to show the that
f > 0.
We set
:
bounded
part of
h[f]
lim n÷~
f
n
statement = min{f,n}
for a b o u n d e d
for
f, we m a y a s s u m e
n = i, 2, . . . .
The q u a s i -
is t h e n g i v e n by
(h[f] A n) : lim h [ f n] : lim I k b f n ( b ) d x ( b ) n÷~ n÷~
= I kbf(b)dx(b)" 5E.
f.
(a) for a g e n e r a l
As a s p e c i a l
[]
case of the p r e c e d i n g
theorem,
we get the fol-
l o w i n g result. Theorem.
(a)
quasibounded
If part
u E HP'(R),
then
prQ(u)
u
of
prQ(u)
~
exists
a.e.
on
AI
and the
is g i v e n by
= I
kb~(b)dx(b)" AI
In p a r t i c u l a r , 0
a.e. (b)
on
if
u
is a s i n g u l a r h a r m o n i c
function
on
AI . If
u*
is a X - s u m m a b l e
function
on
A], t h e n
R, t h e n
~ =
57 r
u = H[u*]
=
kbU* (b)dx(b)
I
J £1
is a quasibounded Proof.
(a)
evidently
6.
This is immediate
That
u
in 2C.
It follows
§3.
on
Al"
theorem,
for
u
is
u = h[u].
~
again from Theorem
a.e.
from the preceding
is a quasibounded
So, by (a),
G = u*
harmonic
exists
a,e.
2C that
function was already
and
u* = G
in-
u : fA I kbG(b) dx(b). a.e.
[]
COVERING MAPS Correspondence 6A.
face
Let
R
of Harmonic
(R, 0) (R', 0')
~
(A2)
every point
onto
(R, 0)
is a h o l o m o r p h i c
every connected
of a hyperbolic
0 E R, called the origin of
(AI)
under
Functions
be a pair consisting
and a point
another pair
component
of
Riemann
A map
~
sur-
from
is called a covering map if
function
a E R
R.
from
R'
onto
R,
has an open neighborhood ~-I(v)
is conformally
V
such that
isomorphic
with
V
~, (A3)
~(0')
The triple
= O.
(R', 0', #)
triple of
(R, 0).
(R, 0)
which
triple
(R', 0' , ~)
(R, ~)
onto
(R',
is conformally
Let
monic,
~
(resp.
(resp.
a conformal
of the open unit disk
(R, 0)
with origin and
and
(R', 0')
(~,
0, ~R,))
isomorphism,
super- or sub-harmonic)
on
(R', 0')
f
if R'.
on f o ~
isomorphic with
R
Riemann
onto
~R = ~ ° ~R'"
a function
(R, ~)
The uni-
and the origin
be the universal
(R', 0')) such that
super- or sub-harmonic)
~
Ch. I, 18C).
be hyperbolic
a covering map of
of
~'
isomorphism and is called the
(R, ~)
IIG).
harmonic,
up to a conformal
theorem says that 0)
of
Such a surface
([AS],
Ch. III,
0, ~R )
$ = ~ o ~'
(R, 0)
(D,
(R, 0)
(R, ~, $)
one can find a covering map
satisfying
surface
is called a coverin ~
triple
in the sense that for each covering
(R, 0)
0')
a covering
of
the pair
6B.
of
uniquely
covering
formization
having these properties
There exists
is the strongest
is determined universal
(~,
function and
a Wiener function and
(b) dieated
harmonic
0
surfaces
(R, 0).
covering Since
@
Let
triple of is locally
is h o l o m o r p h i c
is holomorphic
([AS],
(resp.
(resp.
har-
58
Let
TR
be t h e
multiplicative onto
itself
F = f o ~R that
F
group
such that
on
transformations linear
S R o T = SR"
for any
~
of c o v e r
of f r a c t i o n a l
is a f u n c t i o n
Fo T = F
tion on
group
on
D,
T E
T R.
is e x p r e s s e d
If
f
which
~R'
form
every
f o SR
i.e.
T
is a f u n c t i o n
is T R - i n v a r i a n t
Conversely,
in t h e
for
transformations
D
on
R, t h e n
in t h e
sense
TR-invariant
with
the
of
func-
a function
f
R.
Theorem. into
(a)
The map
HP'(R').
and only
if
(b)
So,
uo $
Let
s
is a p o t e n t i a l (e)
Proof.
on
function (i)
We
covering
Let
is q u a s i b o u n d e d
R
for any
on
f
R'
v ~
on
first
consider (D,
i = i,
i : i,
R
(resp.
function, ¢].
the
(R',
when
of
if
0',
R.
Then
on
R'.
then
$)
s
f o $
is the
is
uni-
(R, 0).
2, a n d w e
Since
HP'(R)
R'. on
is a p o t e n t i a l
is a W i e n e r
ease
on
function
h[f] o ~ = h[fo
of
singular)
set
v = (u I o S R ) v (u 2 o %R ).
v ~ u i o %R
for
i = i,
2, w e h a v e
T E TR
vo T = v on
isomorphism
singular)
so $
0, SR )
(u I v u 2) o SR 0
voT for
if
R
and
triple
(resp.
superharmonic
if a n d o n l y
u i E HP'(R),
Clearly,
is a l a t t i c e
is q u a s i b o u n d e d
be a p o s i t i v e
If a f u n c t i o n
a Wiener
versal
u ÷ uo $
u E HP'(R)
2
and therefore
for any
such
~ uioSRoT
that
T E T R.
v o T ~ v. Thus
v : u o %R"
= uio $R
there
Since exists
It is e a s y
to
TR
is a g r o u p ,
a harmonic
see t h a t
we have
function
u ~ u Iv u 2
u and
so (u I v u 2) o $R ~ u o ¢R = v ~ Consequently,
we h a v e
(u I V U 2) o SR : (u I o SR ) v (u 2 o SR ), w h i c h
that
the
correspondence
onto
the
set of T R - i n v a r i a n t
we
see t h a t
singular) Next v
be t h e
same
u + u o SR
a harmonic
if a n d o n l y let
s
greatest
if
u o SR
be a p o s i t i v e harmonic
as a b o v e
we
harmonic
function
It is e a s y to
show that
theorem
is a p o t e n t i a l
is.
(Theorem
u
Thus
is t h e 6F,
Ch.
on
Since
HP'(R)
I o @R : i,
is q u a s i b o u n d e d (a)
shows
of
(resp.
is p r o v e d . and
let
~.
By u s i n g
the
is T R - i n v a r i a n t .
So t h e r e
exists
of v
isomorphism
HP'(~).
superharmonic
see t h a t
if a n d o n l y
in
u E HP'(R)
minorant
argument
u
is a l a t t i c e
elements
function
a nonnegative
By R i e s z ' s
(u I v u 2) o SR"
function
s o SR
R
greatest
with
on
the
harmonic
I) a p o s i t i v e
if its g r e a t e s t
on
R
property minorant
v = u o @R" of
superharmonie
harmonic
minorant
is
s. function
B9 identically
zero.
This
(b).
proves Finally
exists
So
let
f
s
is a p o t e n t i a l
be a W i e n e r
a potential
U
on
R
if and o n l y
function
such
that
on
R.
if
By T h e o r e m
So we h a v e
h[f] o ~ R - U o ~R ~ f o ~R ~ h[f] o ~R + U o ~R'
to
HP'(~)
above.
By T h e o r e m
= h[f] o CR'
whieh
(ii) take
5A
We
v ~
servations
f o @R
proves
consider
u i C HP'(R),
before
U o @R
is a p o t e n t i a l
is a W i e n e r
general
i : i,
(i),
5A t h e r e
where
by what
function
on
h[f] o ~R
we h a v e
on
~
R.
and
seen h[fo
%R ]
(e).
the
(u I v u2) o 4. in
is.
h[f] - U ~ f ~ h[f] + U
belongs
and
s o %R
2, and By u s i n g
case set
¢:
(R',
0')
÷ (R,
0).
Let us
v = (u I o ¢) v (u 2 o ~).
Then
fact
our
the
CR = ~ o @R'
and
as ob-
we h a v e
(u I V u 2) o ¢R : (u I v u 2) o ¢ o @R'
~ v o %R'
= {(u I o ¢) v (u 2 o ¢)] o CR'
= (u I o ¢ o ¢R,)v (u 2 o ¢ o ~R,) = (u I o CR)v (u 2 o CR) = (u I V u 2) o CR" Thus
we h a v e (u I v u 2) o ¢ = v : (u I o ¢) v (u 2 o @),
from which on
R
if and
o %R'' R'.
7.
(a) follows. only
U o ~R
So
(b)
metric uous
U o }R
follows.
space,
use
there on
on
so by T h e o r e m
R
and
function
on
AI(R').
We
of
R'.
notations
in
a countable
AI(R'), D(~). we h a v e
C
the restriction 6B-(c)
It f o l l o w s
And
since
CR :
is a p o t e n t i a l
(a) and
(b).
on
[]
the
fiR f o ~
from
6B.
Since C
points
R*
is a c o m p a c t
of r e a l - v a l u e d of
R*.
is a c o n t i n u o u s is also
Lemma
5C
Wiener
a continuous
~
contin-
Let
is d e f i n e d
f E C. function
Wiener a.e.
on
set
is c o u n t a b l e DO
is a p o t e n t i a l
D. Uo %
family
separates
D O : A { D ( f o ~): Since
U
Measures
which
5D-(b)
if and
(i), on
is a c o n s e q u e n c e
our
By T h e o r e m
in
if
exists R*
shown
only
of H a r m o n i c
We a g a i n
functions
(c)
fact
is a p o t e n t i a l
is a p o t e n t i a l
Preservation 7A.
if
By the
has
In fact,
and
negligible let
each
D(f o ¢)
eomplement
b' E D O .
f e C}.
Since
in
every
has
negligible
AI(R'). f E C
We
complement
claim
that
is c o n t i n u o u s
in DO
on R ~,
80
@^(b') Since
C
separates
o n l y one point.
~
N fEC
{b • R*:
the p o i n t s
So
b' • D(@)
(ll)
R*, the r i g h t - h a n d
side can c o n t a i n
and
f($(b')) : ~ ( b ' )
for any
f • C.
Next we c o n s i d e r h(z')
for
z' • R'
w i t h the G r e e n
the f u n c t i o n values a.e.
in
on
h
AI(R').
and
Theorem. maps Proof.
= D(~)
is a B o r e l
into
Theorem
above
that
R
such that
G(b'),
$(b')
• ~(R). 7B.
i.e.
(a)
see
If
By T h e o r e m
6B-(b)
It is a l s o c o n t i n u o u s h
exists
with
and v a n i s h e s
of
h(b')
£1(R'),
= 0}.
XR,(D0(%))
= I, and
$
and
$ ~
D(h)
is a B o r e l
Take any
~ > 0
Since
h(b')
D(%)
are B o r e l set in
b' • D0(%).
sets and t h a t
AI(R').
If
$(b')
and an o p e n n e i g h b o r h o o d for
z • V.
%-I(v)
So
h(z')
is e a s i l y
~ ~ > 0, w h i c h
V
~ ~
We saw • R, t h e n of
$(b')
for a n y
z'
seen to be a m e m b e r
is a c o n t r a d i c t i o n .
in
Hence,
[]
$
XR,($-I(A)) (b)
R.
5D-(a),
• D(h):
N0(~)
= i.
The m a i n r e s u l t
Theorem.
{b'
subset
So
gR(0,z)
%-I(v).
we thus
N
4B shows that
XR,(D0(~))
to
R'
for
&(R).
find a c o n s t a n t
belonging
on
gR
so, by T h e o r e m
is B o r e l m e a s u r a b l e .
we w o u l d
function
We d e f i n e
N0(%)
DO(~)
the f u n c t i o n
: gR(0,%(z'))
is a p o t e n t i a l
[0, +~]
DO(~)
in
in
A = f o @(b')}.
f(b)
in this
part
is the f o l l o w i n g
is a m e a s u r e - p r e s e r v i n g = XR(A)
for any
f* • L I ( d x R ), t h e n
m a p of
XR-measurable
DO(~) subset
f* o $ • L I ( d x R , ) ,
into A
A(R), of
A(R).
Llf*liI = llf* o SUl,
and (12)
H [ f * ] o ¢ = H [ f * o $],
where
il-JJ1
fining
the
Proof.
(i
and extend
denotes solution Let
f*
the L l - n o r m and of the D i r i c h l e t
H[-] problem
be any r e a l - v a l u e d
it to a c o n t i n u o u s
denotes
function
as g i v e n
continuous f
on
the o p e r a t i o n
R*.
de-
in 3A.
function
on
By a d j o i n i n g
A(R) f
to
61
the class
C
complement
in
to
u s e d a b o v e we see that AI(R')
D0(~) N D ( f o
~).
is q u a s i b o u n d e d
and
D ( f o %) N D 0 ( # )
f*($(b'))
Since
f o #
with boundary
= f~(b')
values
~
(13)
H [ f * ] o 9 = h[f] o % = h[f o ~] : H [ ~ ] (12) h o l d s
function which
next that
is b o u n d e d
belonging h [ f O %]
h[f o ~] :
6B
for any c o n t i n u o u s
Suppose
b'
function,
and t h e r e f o r e
So we h a v e by T h e o r e m
(ii)
for any
is a b o u n d e d W i e n e r
H[~].
Hence
has a n e g l i g i b l e
f*
= H[f* o $].
function
on
f*
A(R)
on
A(R).
is a l o w e r
b e l o w and X R - S u m m a b l e .
semieontinuous
We take a n o n d e c r e a s -
ing s e q u e n c e converging
{f*: n = i, 2,...} of c o n t i n u o u s f u n c t i o n s on A(R) n p o i n t w i s e to f*. Since HI-] is a l a t t i c e i s o m o r p h i s m
the space
LI(dxR;~)
XR,-)
summable
bounded
(reap.
functions
harmonic
LI(dxR,;~))
onto the
functions
on
x[f*]
space
R
(reap.
: H[sup
since
f * o $ = SUPn
(13)
and
Theorem
H[f*] o * : ( V n
(reap. of q u a s i -
M[f~]
n
(f~o,)l
: v HEf~o*l
n of
XR-
Q(R'))
(f~ o $),
H~e~o Sj : ~Esup By u s e
(reap.
R'), we h a v e
f~] : v
n and,
of r e a l - v a l u e d Q(R)
of
n
6B we g e t
H[f*]) o , = V n n
= HLsup
(H[f~] o 0) =
V n
H[f* o $] n
(f~o $)I = H~f*o SJ.
n So
(12) h o l d s
continuous (iii) A(R).
for our
function Let
of u p p e r g~
exist
is b o u n d e d
functions
h~)
for any u p p e r
above
semi-
and X R - s u m m a b l e .
defined
XR-summable
sequence
{g~:
and a n o n i n c r e a s i n g
semicontinuous is b o u n d e d
(12) h o l d s
above
a nondecreasing
of l o w e r
(reap.
Similarly,
be any e v e r y w h e r e
semicontinuous
n = i, 2,...} every
which
f*
Then there
f*.
functions (reap.
on
function
sequence A(R)
below),
on
n : i, 2,...} {h~:
such that
g~ ~ f* ~ h~
and
lim S
n÷~ It f o l l o w s
that
and
=< H [ f * ]
H[g*]
{H[gn]}
f f°
lim f
is n o n d e c r e a s i n g ,
=< H[h~'~]n for
n : i,
n dXR"
n÷~
2,...
{H[hn]} .
is n o n i n c r e a s i n g
Moreover
62
~[h~](O)
- H[g~](O)
: I (h~- g~) d×R ÷ o.
So we have V n Applying and
4, w h i c h
h~
H[g~]
= H[f*]
is a lattice
A n
HEh*]. n
isomorphism,
and usin Z (12) for
g~
we get V n
H[g~o
$] =
=
v n
(H[g~] o %) = H[f*] o % =
A
(H[h*o
Furthermore,
since
see f i n a l l y
H[f*] o % = H[f* o 2]-
function (iv)
characteristic function
on
A(R),
A ~ A(R) function
of the
f~, that
H[g~ o 2] ~ H[f* o $] ~ H [ h ~ o
f*
Let
set
provided
A.
$-I(A).
Then,
(H[h*]n o ~)
f = J f*(b)dXR(b) : H[f* o $](0')
n = i, 2 ..... we for every
is e v e r y w h e r e subset
f* o $
defined.
and let
which
follows
= H[f*](0)
XR-SUm-
f*
be the
is the c h a r a c t e r i s t i c
(12),
From this
$],
(12) holds
f*
We see by
H[f*] o ~ = H[f* o 2].
XR(A)
Hence,
be any m e a s u r a b l e of
A n
$]).
n
n
mable
=
is v a l i d
for this
that
= (H[f*] o %)(0')
= I (f* o $ ) ( b ' ) d X R , ( b ' )
= XR,($-I(A)). Hence, f* o $ holds
(a) holds. maps when
tions.
f*
This 7C.
ing map
~R:
joining
Theorem.
TR
÷ R from
1-cycles
in
0 0. R,
the c o r r e s p o n d e n c e LI(dxR,;~)
= 0.
Given
T(0)
within
Since
covering
transformations
@R(0)
different
CR(y ')
func-
maps.
First we
for a u n i v e r s a l
T E TR, we take ~.
choices
determines
null
(12)
[]
case of u n i v e r s a l
with
f* +
and that
class m o d u l o
of the theorem.
of cover
with
into
as an e q u i v a l e n c e
the p r o o f
the o r i g i n
issuing
homotopic YT' of
~
in turn that
isometrically
We now look at the the g r o u p
l-cycle
implies
is r e g a r d e d
finishes
identify y'
This
LI(dxR ;~)
Then for
a unique
y'
cover-
an arc
~R(7 ')
is a
result
element,
in
say
F0(R). The map
the f u n d a m e n t a l
T ÷ YT
group
gives
F0(R).
an i s o m o r p h i s m
([AS],
Ch.
I, 19A)
of the group
TR
onto
83
7D. that
Using the notations
D0(%R)
theorems
R' = ~
and
~ = %R' we see
Besides the properties
mentioned
Let
LP(dXR)
0 < p S ~.
isometrically
Lebesgue measure only if
Then the correspondence
onto the subspace
ing of all TR-invariant
elements,
LP(do) T
where
on the unit circle.
f~ ÷ f * o SR
do
of
denotes
Moreover
LP(do)
maps consist-
the normalized
f* E HP(dXR)
if and
f* o SR e HP(do).
Proof.
We first note that the Martin compaetifieation ~
is the closed unit disk,
cumference origin
in the
in 7A and 7B, we have the following
Theorem.
disk
in 7A with
is TR-invariant.
T
its Martin boundary
and the corresponding
is equal to the normalized
of the open unit
harmonic measure
Lebesgue measure
is the unit ciron
T
do(t)
at the
= do(e it) =
dt/2~. (i)
Suppose that
p = i.
H[f*] o ~R = H[f* o SR]. for the TR-invariant a TR-invariant invariant
Since
harmonic
function
function.
on
function on
function
on
R
Theorem 6B-(a)
rem 5E,
v = HEv]
~. ~.
(ii)
v o ~R = H[u*].
Consider the general
by (i), we have
Conversely,
let
with
f* E LP(dXR )
and
in
Since
H[u*]
v
of
If*l p e LI(dxR)
h* o SR = u*p f* o SR = u*
LP(do) T.
u*
If
and
Let and
v. a.e.
a.e.
Letting
Again by That
7B.
f* E LP(dXR). I11f*lp O SRUl :
lif*o Smllp = llf*llp.
u* ~ 0, then we find, a.e.
is quasiSo, by Theo-
u* = ~ o SR
0 < p < ~.
be a T R-
7C, we find a harmonic
function
and hence
by (i), an
f* = (h*) I/p, we have
The result for an arbitrary
as a linear combination
The rest is now obvious.
to)
is a TR-invari-
is quasibounded.
f* o SR E hP(do)
is then deduced by writing elements
v
case
u* e LP(do) T.
h* E LI(dxR )
u* E Ll(da) H[u*]
is an isometry was shown in Theorem
If* O SR Ip : If*l p O SR'
li!f*IPllI
let
function
for the fine boundary
f* ÷ f* o SR
function
H[f*] o ~R' it is (equivalent
In view of Theorem
implies that
by (12), we have
is the fine boundary
Conversely,
v O ~R : H[~] o ~R : H[~ o SR ]
the map
Since
f* o SR function
such that
bounded, (12)
f* E LI(dXR ), then,
Then the harmonic
ant harmonic v
If
u*
of four positive
[]
NOTES The results
on Martin eompactifieation
13, 14 of Constantineseu
and Cornea
[CC].
improved version of those given in Hasumi
are adapted The results
[17].
from Chapters in §3 form an
6,
CHAPTER
Some on the
basic
unit
results
disk
and
boundary
behavior
surfaces
are
deduced
maps
given
covering h~--the
§i.
i.
harmonic
HARDY
IA.
Let
with
ON THE
~ by
0
be the g~(a,z)
being
can be e x t e n d e d the unit
that
ference
UNIT
DISK
open
unit
Martin disk
both T
(or
0
For any
CI(~)
with and
~). with
z = re ie 0
H~(~) let
the
For each pole
at
t)
following,
0 e p < ~
f(z)
on
denotes
the
functions or,
The h a r m o n i c
in the
For
N(~)
Hp into
results the
on
dual
of
B-topology.
are
point
e it
be the f(z)
equivalently,
on
~ space
let such
of b o u n d e d
Nevanlinna D
HP(~) that
such
Lebesgue or
denote If(z)I p analytic
class
~n
that
log+If(z)l
log Ifl • s P ' ( ~ )
(Ch.
usual
the We
unit
Martin
b ÷
CI(~),
see circum-
function
Poisson
kernel
(on
of
2
(8-t) + r
d~(e It)
topology.
the the
d x ~ ( e it)
normalized by
with
to the
by
function
is i d e n t i f i e d Euclidean
on func-
given
disk
equal
l-r
are
the
closed
e it • T
measure
plane
unit
is e x a c t l y
=
g~
so the M a r t i n
z • •
~
usual
function
and
complex
to the
of
AI(D)
is seen to be the
is d e n o t e d ,
IB.
look
on R i e m a n n
by u s i n g
to the
a I}
fixed
I- 2rcos
functions
Results
The G r e e n
of the
continuously
P(r,8-
origin
classes
we d e t e r m i n e
respect
disk.
compactification
A(~)
z ~ k~(elt,z)
with
Hardy
We m a i n l y
disk
Finally,
H~--with
the o r i g i n
= g~(b,z)/g~(b,0).
closed
§3.
unit
= log { I i - ~ z l / I z -
k~(b,z)
also
classes.
for the
Ill,
of
k~(b,z)
so that
in such
concerning
surfaces.
Definitions
is g i v e n tions
in Ch.
CLASSES
here
Riemann
from those
version
HARDY
recalled
on g e n e r a l
of f u n c t i o n s
CLASSES
Basic
are
IV.
~)
measure
~
at the
dt/2~,
which
d~(t).
the has
space
of a n a l y t i c
a harmonic
functions
~ , i.e.
II,
2
the has
5D).
on
space
majorant. ~.
a harmonic Then
Further,
of a n a l y t i c majorant
6S
N(D) for
0 < p < q < ~.
~ HP(~)
For
~ Hq(~)
f ~ HP(~),
l[fU
~ H~(~)
0 < p < ~, we
set
= ( ( L H M ( I f l P ) ( 0 ) ) I/p, P
where set
LHM
stands
IIfJl : s u p { I f ( z ) l :
subharmonic and
for any
therefore
it has
IC.
Along
that
Lemma.
If
f(z)
If(z)l p
has
Proof.
We
harmonic
Since
u
¢
f
¢o f
The least
rf(z)] p
any
0 < p <
majorant
is
provided
harmonic
if
any
on
functions h~(~)
Iz- z01 v
analogous
hP(~), f(z)
I ~ p on
denotes
the
com-
~.
¢(x,y)
is a c o n v e x
function
If(z)I p
on
is s u b h a r -
i £ p < ~.
v = Im(f),
Let
consider let
In p a r t i c u l a r ,
and
~ r0
so t h a t
be any
u
closed
and disk
v
are r e a l
in the
domain
are h a r m o n i c ,
I
=
we
Namely,
majorant,
and
and
f(z 0)
T
(U(Zo+roeit)'v(zo+roeit))d°(t)"
= ¢(u(z0),v(z0))
is seen
that lemma
harmonic
as b e f o r e sup {If(z)l
r0
e it-))da(t)
(¢o f)(z0+r0eit)do(t).
to be
subharmonic.
(x 2 + y 2 ) p / 2
is a c o n v e x
then
that,
implies
majorant
+
¢(u(z0+r0eit),v(z0
= I
fact
harmonic
we
that
and
HP(D)
functions
and
I
the
D
f E H~(D)
is convex,
¢o
Hence
on
least
classes
subharmonic.
(u(z0)'v(z0))
Since
in p a s s i n g
f
functions.
a harmonic
harmonic
u = Re(f)
functions.
f(z).
the H a r d y
harmonic
set
the
For
majorant.
has
is
majorant.
We note
function
is h a r m o n i c
¢o f
for any
z e D}.
of c o m p l e x - v a l u e d
bounded
then
monic
space
harmonic
of h a r m o n i c
If(z)I p
plex-valued
~2,
with
consisting
< ~, be the such
that
least
analytic
a superharmonic
classes
of
for the
whenever
The
in case it has
latter
function
fact
if
i ~ p < ~,
a harmonic
follows
i ~ p < ~. Ill p
has
majorant.
llfJl = ( ( L H M ( I f l P ) ) ( 0 ) ) 1/p for i ~ p < ~ and P : z E ~}. A complex-valued harmonic function
from [] the
We d e f i n e llfll = f
is c a l l e d
66
quasibounded
if b o t h
by
h~(~)
the
2.
Some C l a s s i c a l 2A.
along
Re(f)
Theorem.
(a) values
Let
f* @ LP(do).
every
For
If(z)l p
is the P o i s s o n
to
f*
ie
The m a p 11fllp
LP(do).
is a norm,
We d e n o t e
to
hl(~).
HP(D)
has r a d i a l
limits
integral
If
on
f ÷ f*
{fr:
LP(da)
as
of
= JI
Then
f
for a l m o s t 0 e r e i} r ÷ I- 0
admits
all
radial
e i0 @ T
with
and the
and
fr(e ie)
=
LHM of
If*I p, i.e.
F(r,e-
t) If*(eit) IPdd(t )
it is q u a s i b o u n d e d .
If
f ~ O, t h e n
~. is an i n j e c t i o n
11f*llp, w h e r e
of
HP(~)
llf*llp d e n o t e s
into
the u s u a l
i =< p ~ ~, t h e n the f u n c t i o n a l If.If p HP(~) into a B a n a c h space.
LP(do)
n o r m of the defined
in IB
which makes
We d e n o t e HP(~)
belonging
0 < p ~ ~.
the net
and t h e r e f o r e
is s u m m a b l e
(b)
space
E ~,
with
in
(LHM( If IP)) (z)
satisfying
in
= l i m r ÷ I 0f(re le)
0 e p e ~
converges
log If*I
function
f E HP(D)
f*(e i6)
f(re ie)
z = re
are q u a s i b o u n d e d .
elements
all radii.
boundary
for
Im(f)
Results
We show t h a t
almost
and
set of q u a s i b o u n d e d
by
HP(d~)
is i s o m e t r i c a l l y
the
set of
isomorphic
The p r o o f w i l l be s t a t e d
in 2B-2E,
0 < p < ~, for the ease
p = ~
f*
with
with
f E HP(D),
HP(do)
under
so that
the m a p
f + f*.
w h e r e we o n l y deal w i t h the case
is e a s i l y
covered
by the d i s c u s s i o n
to
follow.
2B. let
uf
First be the
r 2 < ... < i f(r e it) n
for
be a f i x e d
n = i, 2, . . . .
IT
Ifn(eit)12do(t) So
and c o m p a c t
{fn ) Hilbert
with respect
has a c o n v e r g e n t J = i, 2,...}
case
majorant
sequence
for
is a s e p a r a b l e
{fn(j):
the s p e c i a l
least harmonic
n = i, 2, . . . .
L2(d~)
{fn )
consider
p = 2.
of
tending
Let
Ifl 2 to
i
on
f E H2(~) D.
Let
and set
and
0 < rI <
fn(e it)
=
Then,
~ S
uf(rneit)da(t)
= uf(0)
is a b o u n d e d
sequence
space,
closed ball
every
to the w e a k t o p o l o g y
subsequence. and a f u n c t i o n
Namely,
in
L2(do).
and t h e r e f o r e there
F E L2(d~)
exist
Since
is m e t r i z a b l e the
sequence
a subsequence
such t h a t
@7
S for any
k E L2(do)
re i@ E D,
as
fn(j)k do ÷ I j + ~.
Setting
Fk do k(e it) = P(r,@- t)
with
z :
we have f(rn(j)z)
: I
fn(j)(eit)p(r,@ -t)do(t)
+ I
F(eit)p(r,@ -t)do(t)
and therefore f(z) = I
F(eit)p(r,@ -t)do(t).
Fatou's theorem (Theorem AI.2, Appendix) then implies that, for almost i@ every e , f(re l@) tends to F(e i@) as r tends increasingly to i. For any such 8, define f*(e i@) = F(ei@), so that f* E L2(do) and f*(e i@) = lim f(re ie) a.e. We thus have r+l-0 f(z) : for
z = re i0 6 ~.
(I)
I f~(eit)p(r,O -t)do(t)
By use of the Schwarz inequality
If(z)12 =< S
If*(eit)[2p(r,% -t)do(t). T
The right-hand side, say (2)
u, gives a harmonic majorant of
if[2
and so
If(z)r 2 ~ uf(z) ~ u(z)
on ~. Since u is seen to be quasibounded, so is uf. Thus uf is equal to the Poisson integral of its radial boundary function. Taking radial limits in (2), we have If*(eit)I2 ~ u~(e it) ~ u*(e it) = If*(eit)I2
a.e. and therefore
u = uf.
IIfI'~ = (LHM(IfI2))(0)
: S
It follows that If*'2d° = 'f*'~"
T Namely, f + f* gives an isometry of H2(D) into L2(do). from (I) that the L2-convergence of f*'s implies the almost convergence of f(z)'s on ~. Hence, H2(~) is a Hilbert which is canonically isometrically isomorphic with a subspace L2(do).
It follows uniform space, of
68
2C. order
Suppose that
m ~ 0
f ~ H2(~)
with
f ~ 0.
at the origin, then we set
If
f
has a zero of
f0(z) = f(z)/z m.
Then
f0(0)
0, f0 E H2(D) and indeed If0(z)I 2 ~ uf(z). Let al, a2,.., be the zeros of f0' repeated according to multiplicity and ordered so that 0 < fall ~ la21 ~ . . . .
By Jensen's
r
[
formula
(ef. Rudin [59], p. 330)
+ IT l°g[f0 (reit) Ido(t)
l°g;~--~I k : -loglf0(0)
lak I
+ IT If0 (reit)12d°(t)
-loglf0(0) Letting
r ÷ I - 0, we get
(3)
[ k ~: l l ° g (i/lakl)
~ k=l
lakl
< ~
which is equivalent to:
is convergent.
This in turn implies that the Blaschke product with zeros B(z) = ]~ k=l converges almost uniformly on IB(z)l ~ i
on
D
To see this,
and
~
lakl
ak
ak
{a k}
z
i - ak z
and is an inner function,
IB*(elt) I = i
a.e. on
i.e.
~.
let
B (z) denote the n-th partial product of B(z). n Then, every B n is analytic on the closed unit disk and IB~(elt) I ~ I on T. Moreover, for m > n, lIBm_ Bnll22 : IT IB~ (~it) - B*(eit)I2do(t)n
: 2 IT (i- Re( B~(eit)/B*(eit) n )do(t)
: 2(1 - Re[
(B*(emt)/B*(emt))do(t)]) m n . .
i = 2(1-
Re[B
: 2(i-
77
m
(0)/B
n
(0)])
m
JakJ) ÷ 0
k=n+l as n ÷ ~, because of (3). The sequence {Bn(Z)} is thus a Cauchy sequence in H2(D). By our observation in 2B, there exists an element F E H2(~) such that B + F in H2(~) and B* ÷ F* in L2(d~). n n
69
F, we c o n c l u d e
Since B c o n v e r g e almost u n i f o r m l y to n So, there exists a s u b s e q u e n c e of B*
which
n
Hence,
IB*I
2D.
= i
a.e.
Continuing
n = i, 2,...
for B(z)
almost
h(z)
on Let
and
h(z) on
so that
n
of 2C, we set
= f0(z)/B(z).
h (z) converge n is a n a l y t i c on D.
Then,
for any
IBn(Z) I ~ I
for
B n (z)
almost
1 - 6 ~
Izl ~ i.
uf(z)/(l-
g)2
majorized
on
that
Since
everywhere D
lh(z)l 2 ~ uf(z).
(4)
lhn(Z)l 2
on
by the
B*.
Izl ~ i
D.
same Hence,
As
E
a
~ > 0
e) 2 lhn(Z)l 2
is a r b i t r a r y ,
for every
h e H2(~)
n.
lhn(Z)l 2
From this
is
follows
with
lh*(eit) I : I f ~ ( e i t ) I / I B * ( e i t ) : If* (elt) I
exists
to
to
and so
is s u b h a r m o n i c ,
uf(z)
converge
uniformly
0 < e < i, there
I- ~ ~
lhn(Z)l 2 ~ Ifo(Z)12/(l - E) 2 =< u f ( z ) / ( l for
to
h n (z) = f 0 ( z ) / B n (z)
Since
~,
h
be fixed. i- e ~
F : B.
a.e.
~.
the d i s c u s s i o n
uniformly
D,
such that
on
that
converges
I :
[f~(eit) I
a.e.
We thus have f(z)
(5) where
h(z)
has no zeros
Finally, lh(z)I2/2
in
we show that
~ uf(z)/2
is a n o n n e g a t i v e
harmonic
directly),
exists
z = re ie E D.
the a b s o l u t e l y v*
function
=
Fatou's Since
2E.
Hence,
Turning
by
f
in
log lh(z)l
~,
~.
theorem
part
(4),
By T h e o r e m
measure
d~
on
2A, Ch. T
III
(or
such that
P(r,8 - t)dp(e It) then
says that
of the m e a s u r e
v*(e it)
- log lh*(eit) I + If~(eit)12 be summable.
Since
has no zeros
on
a nonnegative
continuous
is summable.
is integrable.
h(z)
= - log lh(z)l + uf(z)/2
v(z) for
~. log If*l
and since v(z)
there
= zmB(z)h(z),
and
: -log since
case,
d~(e It)
f* e L2(d~),
:
log lh*(eit)I
is summable.
let us take any
is
and t h e r e f o r e
lh*(eit) I + u } ( e i t ) / 2
log If*(eit) I
to the g e n e r a l
v*(eit)do(t)
f E HP(~),
must
70
f ~ 0, with
0 < p < ~.
be the h a r m o n i c
Let
u
be the LHM of
of
u
on
conjugate fl(z)
Then
fl
~
and
: exp(-~(u(z) P
is a n o n v a n i s h i n g
analytic
f2 : ffl'
f2/fl. f~
Since
exist
follows
H~(D)
a.e.
that
we have
function
where
B
where
h(z) Set,
in
~
= £(z)/fl(z)
as before,
n
al,... , a n .
for
Bn
on
T.
is the finite
n = i, 2,...
[h*(eit) I =
Since
lim r÷l-0
If(z)l p
-fT If(remt)IP d~(t) I
formed
= f(z)/z m
and thus
as
in
f~ E LP(d~) h
h 0 E H2(~) shown
in 2B,
negative
and so
has no zeros such that u0
harmonic
hn(Z)
f~
and
summable.
It
We then
= zmB(z)£(z),
~ 0 f(z)
of
f2' and
= zmB(z)h(z),
= f0(z)/Bn(Z),
product
in 2D then
B(reit)l
on
formed
shows
that
[hn(Z)I p
Hence
h • HP(~)
[f(r
ei t n
and
a.e.
we see that
By Fatou's
n =
of the first
: ]f*(eit)l
~,
= IT (lim n÷~
the i n t e g r a l s
lemma we have
)[P)d~(t)
f(rneit)IPd~(t)
u(O) < ~.
h* E LP(d~). in
~,
there
h = h02/P
is q u a s i b o u n d e d function
f =
~.
r ÷ i - 0.
<
Since
that
f2(z)
So we have
lim inf [
Hence,
are
and
summable.
of the zeros
t
" If*(emt)[Pdo(t)
in 2D shows
and get
and
is s u b h a r m o n l c
and
[]f2[] ~ i
lh(z)I p ~ u(z).
If(reit)I/rm
increase
O,
log If~[
Blaschke
Our a r g u m e n t
Let
11flll~ £ i
is also
f2
II£II ~ i.
has no zeros
f0(z)
where
zeros
and
(5) to
product
with
i, 2,..., u(z)
log If~l
formula
is the B l a s c h k e
has no zeros
f2 ~
= log [ f ~ l - log If~I
apply the f a c t o r i z a t i o n
with
our o b s e r v a t i o n
and that both log If*l
~.
] f l l -~
:
f2 @ H ~ ( ~ ) '
q H2(~),
on
+ i~(z))).
If] ~ u I/p ~ e×p(u/p) Setting
''|f|P
set
on
Let and
~.
are positive,
exlsts u0
be the LHM of
Since
SP'(~)
both
nonnegative.
Moreover,
since
-Prl(v 0) S 0
and thus,
in view of Fatou's
the p r o j e c t i o n s P r l ( v 0)
is q u a s i b o u n d e d , theorem
and
function lh012
v 0 = - log lh01 + u0/2
in the space
u0
an a n a l y t i c
As
is a nonpr I
p r Q ( v 0)
Prl(lOglh01) (Appendix
and are =
A.I.3),
prQ
71 [h0(z) I : exp(logrh0(z) I) = exp[Pri(logah0(z)I) + prQ(lOglh0(z)])] exp(prQ(lOglh0(z)I)) = exp[I~ P(r,e - t)log Ih~(eit) i dg(t)] for
Z : re i8
For the function
f
we get
If(z)l p ~ lh(z)JP = [h0(z)i 2 exp[[
for
I
lh~(eit)12p(r,g - t)do(t)
= I
I f * ( e i t ) e P P ( r , e - t)da(t)
z = re i0 E ~.
Just as in 2B, we infer that
(LHM(IflP))(z) for
z = re it E ~,
This means HP(~)
m(r,0 - t)log ]h~(eit)I2 d a ( t ) ]
= f
which is quasibounded,
finally that,
for
into a Banaeh space. 2F.
Theorem. (a)
Let
with
f*
belongs
(b)
If
i < p ~ ~, then
integral of
f*
If
quasibounded The map
with
part, f ÷ f*
lif]Ip
f
Since the case and set
Let
a.e.
on
T
and the
p = =
and is the Poisson
iif*iJp f
and
i < p ~ ~, and of
i ~ p < ~.
Then the following hold:
f*(e it)
is quasibounded
is an isometric hQI ( ~ )
Proof.
i
1 ~ p £ ~.
LP(do).
prQ(f), I of
if
ing to
to
Ilf*iJp
we have the following
values
p = i, then the Poisson
LP(da),
case
hP(]D)
has radial boundary
function
llfirp
II-li is a norm, which makes P This completes the proof of Theorem 2A. []
in
f ~ hP(~)
and therefore
i £ p < ~,
As for functions
f
(c)
[f* (emt) IPP(r, g - t)da(t) ,
integral
of
isomorphism of onto Ll(do).
is rather obvious,
0 < r I < r 2 < ... < I
f (e it) = f(r e It) n n
f*
is equal to the
i]prQ(f)iiI = IIf*iLI.
Then
hP(D)
onto
we only consider
be a fixed sequence
the tend-
72
I where
u
{fn } in
t u(r n eit)da(t) =< J~
is a harmonic majorant
quence in space;
ifn(ei t )IPda(t)
LP(da).
If
of
If P.
i < p < ~, then
so, by passing to a subsequence converges
LP(da)
weakly
in
LP(da),
{fn }
LP(da)
is a bounded
is a reflexive
if necessary,
se-
Banach
we may assume that
i.e. there exists an element,
f*,
such that fn(eZt)k(elt)da(t)
for any
So
: u(0) '
+
f*(eZt)k(elt)da(t)
k C LP'(da)
with p-i + p,-i = i. ie z = re E ~, we get
with any fixed = [ i
f(rnZ)
f (eit)p(r,9 - t ) d a ( t )
Setting
÷ r
f * ( e i t ) p ( r , e - t)da(t)
j
n
k(e it) = P(r,0 - t)
and therefore f(z) By Fatou's that
f
theorem,
= ]
limr÷l_ 0 f(re ie) = f*(e i9)
is quasibounded. If(z) Ip <
and the argument
bounded
let
topology Namely,
of
f
of finite
is compact
w(M(~),C(~)), d~
on
the sequence ~
k E C(~).
side gives the least
{fnda:
Borel measures contains
{fn(i)da:
n = 1, 2,...} on
~.
Since the
with respect
a convergent j = i, 2,...}
is
to the weak
subsequence. and a finite
such that
I k(eit)fn( (eit)da(t) y J) for any
shows
llfllp = I1f*llp.
and metrizable
there exist a subsequence
Borel measure
This also
If*(e it) IPP(r,9 - t)da(t)
Then the sequence
M(T)
M(T)
a.e.
inequality
Ifl p, which implies
p = i.
in the space
closed ball of
By H~ider's
in 2B shows that the right-hand
harmonic majorant Finally
f*(elt)p(r,9 - t)da(t).
By setting
÷ I
k(eit)d~(eit)
k(e it) : P(r,e - t),
z : re i0
]D,
we
get as above f(z) By Fatou's
theorem again,
=
f f*da
°
P(r,e - t)d~(e±t). is exactly the absolutely
continuous
73 part
of
d~,
so that
prQ(f)(z)
This
implies
§2.
HARDY
3.
CLASSES
Boundary 3A.
with the
at once
origin unit
p < ~,
0.
disk
Ifi p
analytic
•
rJprQ(f)liI = i]f*ilI.
of
Hp
at H a r d y The
and
the
on
hp
SURFACES
on a h y p e r b o l i c are
for the
the
sake
set of a n a l y t i c majorant.
R.
For
[]
Functions
definitions
repeated
a harmonic
functions
RIEMANN
classes
basic
denotes
has
f*(elt)p(r,0-t)d~(t).
f
ON H Y P E R B O L I C
but are
HP(R)
that
that
Behavior
We look
:
Riemann
same
as
in the
of c o m p l e t e n e s s . functions
H~(R)
f E HP(R)
surface
denotes with
f
on
the
R
case
of
For
0 <
R
such
set of b o u n d e d
0 < p < ~, we put
11flip : ( L H M ( i f B P ) ( 0 ) ) I/p, where
LHM
stands
f e H~(R)
we
set
0 < p ~ ~, are the
complex
for the
monic
field.
functions
denotes
We also
functionals
and
on
z e R}. and
define
hP(R), f
the
A complex-valued Re(f)
and
H~(R)
R
such
elements
R.
that
For
HP(R),
is an a l g e b r a
that
quasibounded.
in
hl(R).
has
bounded
function
are
f And
We d e f i n e
over
space
Ifi p
of c o m p l e x - v a l u e d harmonic
Im(f)
surface
i ~ p < ~, to be the
on
space
on the
It is c l e a r
that
functions
set of q u a s i b o u n d e d
By u s i n g
a universal
Theorems
6B and
a
har-
is c a l l e d hQI(R) the
7B,
covering Ch.
III,
map we
%R:
~
easily
÷ R
with
deduce
the
~R(0)
= 0
following
and
result
from
2A.
Theorem.
(a)
boundary
values
the LHM of
Let
f E HP(R)
f(b)
Ifl p
and t h e r e f o r e on
majorant
ll.it even on hP(R), 1 ~ p ~ ~, by m e a n s of the a b o v e P It is t r i v i a l to see that HP(R) ~ hP(R) for 1 ~ p ~ ~.
formulas.
Theorem
spaces
h~(R)
R.
if b o t h
the
linear
harmonic
majorant,
quasibounded
harmonic
llfll = s u p { I f ( z ) i :
complex
of c o m p l e x - v a l u e d harmonic
least
a.e.
with
on
is e x a c t l y
the
is q u a s i b o u n d e d .
AI
0 < p < ~. and
Poisson If
Then
f E LP(dx ). integral
f ~ 0, then
f For
admits
H[Ifl p] log
ire
fine
0 < p < of
Ifl p
is s u m m a b l e
AI . (b)
isfying makes
The map ilfiip
HP(R)
f + f
iLfilp into
is an i n j e c t i o n
If
a Banach
i < p < ~ space.
then
of
HP(R) it.ilp
into
LP(dx)
is a norm,
which
sat-
74
We d e f i n e
a subspace HP(dx)
which
is i s o m e t r i c a l l y
3B.
Similarly,
Theorem.
Let
function
f
= f.
f = H[f]
S
surjective
4.
Some
Let
is b o u n d e d the
f E hP(R),
into for
HI-]
to
f ÷ f.
the
LP(dx)
and
fine
LP(dx).
boundary Put
such
i < p ~ ~,
is the
p = i
injective
application
has
L H M ( u p)
(b)
u
(c)
(log u) V 0
(d)
S(f)
that
in w h i c h
inverse
case
of the m a p
is i s o m e t r i c
S;
as w e l l
as
on each
Analytic of the
on LHM's
covering
II,
3C)
majorant
for
i ~ p ~ =.
Functions map
~R:
of m u l t i p l i c a t i v e
(Cf.
a harmonic
HP(R)
on for
R
~
÷ R,
analytic
such
some
that
we
functions.
either
u
Then
i ~ p < ~.
is q u a s i b o u n d e d ,
The
is of b o u n d e d
inner
if
p ~ ~.
characteristic,
logu
i.e.
E SP'(R).
is q u a s i b o u n d e d . factor
is a b o u n d e d
u I = exp(Prl(lOgu))
l.a.m.
~Ulll~ : i.
Proof.
In v i e w in the
ments
(a),
see
tion
of T h e o r e m
ease
(c) are
we n o t e
- log u - h
quasibounded v 2 E Q(R). v 2 $ 0. -v I ~ 0.
that
harmonic
of T h e o r e m
Ch.
III,
we h a v e
We m a y
also
assume
almost
Ch.
minorant,
Since
the
h
Moreover,
II,
i.e.
clear
-log u
is n o n n e g a t i v e
5A,
parts,
Since
6B,
R = ~.
(b) and
(d),
quasibounded use
and ~
be an l.a.m.
up
the m a p
following
belongs
hP(R)
for
under
following:
ments
To
u
or
the
and
i.e.
setting
hA(R) ;
result
(a)
and
of
on M u l t i p l i c a t i v e
following
Theorem.
we h a v e
space
HP(R)
surjective
f E hP(R),
As a n o t h e r
the
map
41
by
f E HP(R)},
for e a c h
on
and
is i s o m e t r i c
Results
4A. prove
Then,
is n o r m - d e c r e a s i n g
S
with
2F i m p l i e s
a.e.
is a l i n e a r
on the
(c)
Theorem
is i s o m e t r i c
for any
(b)
LP(dx)
: {f e LP(dx):
i ~ p ~ ~.
S S
of
isomorphic
is d e f i n e d
Then (a)
HP(dx)
to p r o v e
f r o m our
p < ~.
discussion
is a s u p e r h a r m o n i c e.g. and
therefore this
- log u - h = v I + v 2
projections
is q u a s i b o u n d e d ,
are
positive,
we h a v e
i n f z E R Vl(Z)
belongs
into
the
with
to
having
and
v I E I(R)
vI
the
a
func-
SP'(D).
inner
we h a v e
statestate-
in 2A-2E.
Thus
By
the and
vI $ 0
in p a r t i c u l a r
= 0, for
the The
function
h = -p-I(LHM(uP)).
we d e c o m p o s e
we h a v e
only that
and
Prl(lOgu)
is inner.
=
75
Hence
u I : e x p ( - v I) ~ i
and
SUpzER
Ul(Z)
= i, as d e s i r e d •
[]
^
4B.
We a l s o
Theorem. on
AI,
If
compute
u
v E SP'(R),
then
= prQ(v)
where
Vq
Since
v = v
for
u C SP'(R).
~
exists
is t h e
a.e.
on
quasibounded
AI
part
and of
~ = Oq
a.e.
v.
+
Proof. v
is n o n n e g a t i v e .
bounded
parts
- v Now
vi
in v i e w let u s
and
Vq,
of Ch.
II,
decompose
i.e.
v
into
v = v i + Vq.
v. > 0 a n d v > 0. By T h e o r e m i = q = on R and the singularities of
vi,
if any,
be a s i n g u l a r i t y
vi
has
we h a v e where
vi(z) h(z)
tive,
we
h
v i.
= c log Izl + h(z)
see t h a t of
c ~ 0 a.
by R i e s z ' s
As
is i n n e r ,
Ch.
a
II,
therefore
suppose
inner
and
that quasi-
v ~ 0, we h a v e
v
is e v e r y w h e r e h a r m o n i c q are isolated. Let a E R
only
The
its
Since
logarithmic
in a p a r a m e t r i c
function. and
disk
singularities,
centered
function vi
is
v. being m superharmonic
at
a,
nonnegain a
v. is s u p e r h a r m o n i e o n R. l I) we h a v e v. = h + h , w h e r e l s p harmonic function and h is a p o t e n t i a l . Since p h . C o m b i n e d w i t h L e m m a 5C a n d T h e o r e m 5D, Ch. III,
theorem
is a n o n n e g a t i v e
s v.
5B,
Since
is a h a r m o n i c
neighborhood Thus,
of
5A, we m a y
so is
l
is a r b i t r a r y ,
(Theorem
6F,
Ch.
S
these
observations
AI •
So
a.e.
again
to
vi
Qq
exists
Corollary.
on
5C,
AI .
If
u
a.e.
on
that
Ch.
AI,
where
Proof•
Set
preceding ~q
a.e.
is a n o n z e r o AI
v : log
theorem with
Vq
The
We w i l l
purpose
convex complex
v
vanish
Moreover,
AI .
Hence,
and
exists
a.e.
a.e.
Vq
on
exists
and
is e q u a l
l.m.m,
of bounded
characteristic,
then
= i
and
u : UQ
u.
shows
Since that
and
UQ
= exp(prQ(lOgu)).
v E SP'(R)
Q
uI = i
a.e.
exists
by the
a.e.
Hence
we h a v e
a.e.
[]
on
assumption,
AI
and
~ = expQ
the
is e q u a l
: exp @ q
to
= ~Q.
It
B-Topology
5A. this
exist
p
and
= prQ(v).^
that
h
a.e • on
III.
u I : exp(Prl(lOgu))
is n o w t r i v i a l
5.
and
s
[]
uI on
h
and vanishes
by L e m m a
a.e.
exists
imply
we
linear field.
describe
first
spaces.
the
recall Let
Precisely
B-topology
some E
basic
f o r the
facts
be a l o c a l l y
speaking,
this
space
in the
convex
is d e f i n e d
h~(R).
theory
linear b y the
of
space
For locally over
following
the
78
conditions: (AI)
E
(A2)
is a l i n e a r
E
plication
is a H a u s d o r f f
are
the o r i g i n of
space
space
each continuous
0
has
a basis
over
the
complex
such that
in b o t h
field;
addition
variables
of n e i g h b o r h o o d s
and
jointly
consisting
scalar
and
multi-
such that
of c o n v e x
subsets
E. Let
E'
denote
space
of a l l
each
x' E E'
spondence
continuous
E
meaning
(resp.
of
E')
we
{x E E:
A
in
E'
E')
satisfying
is c a l l e d < ~
every
x E E).
and then of
only
the
totality
of p o l a r s
of
E
a basis
by
E'.
s(E',E)
The
dual
E
and
A°
of the
bounded)
that
a subset
The
strong
convex
A
of
over
0.
strong
dual
topological
linear
space
The of
w(E,E') topology (resp.
for
is subsets
for
all
if
E'
such
bounded
space and
E'
subwith
is d e n o t e d
is d e n o t e d
We c a l l
by
Identification
x' ÷ < x , x ' > E
on
semireflexive
the w e a k - ( E , E ' )
(resp.
w(E',E)),
for
(resp.
E
E".
is c a l l e d
(resp.
E')
if
gives
the
x E E
us a n a t u r a l
inclu-
E = E".
weak-(E',E))
is d e f i n e d
for
E'
of each
topology,
as t h e w e a k e s t
that makes
every
locally
functional
written
as
convex x'
E E'
x E E) c o n t i n u o u s .
Theorem. if e v e r y
A locally bounded
harmonic first
We n o w
linear
of
[37],
E
p.
on
R.
is the u s u a l
space
E
is s e m i r e f l e x i v e
is r e l a t i v e l y
if a n d o n l y
w(E,E')-compact.
(cf.
190)
l o o k at the
functions one
convex
subset
and Namioka
5B.
The
s(E',E)
E E'
(resp.
< ~
on b o u n d e d
topology
ranging
number E
is b o u n d e d
topology
the
functional
E =C E". Finally,
Kelley
of
sup{i<x,x,>I:
E
convergence
locally with
of
polar
bounded
S
of
a linear
sion
A
if
of
x E A}
a positive
a subset
is
= {0}
A
it t h e
is c a l l e d
S
bidual with
which
s u p { l < x , x ' > I : x' @ A}
of n e i g h b o r h o o d s
is c a l l e d
E
and
x' E E'}
call
corresponds hand,
E
corre-
E × E'
for a l l
and
of
weakly*
of uniform
it is the
sets
topology
E
(resp.
bounded.
that
the
(resp.
topology
words,
forms
in
in p a s s i n g
if it is w e a k l y as the
0
On the o t h e r
x' E E'
We n o t e
In o t h e r
of
bounded
for every
defined E.
U
A
x E the
For a s u b s e t
~ 1
x' E A})
linear
each Then
for all
= {0}.
I<x,x'>I
A subset
For
f o r m on
: 0
x E E}
for all
E).
E.
as t h e
x'(x).
a bilinear
A ° = {x' E E':
in
on of
{x E E: < x , x ' >
A ~ eU.
weakly
x ~ A}
in p l a c e
for all
I<x,x'> I ~ I (resp.
is d e f i n e d
functionals
defines
that
if to e a c h n e i g h b o r h o o d > 0
E, w h i c h
<x,x'>
= 0
set
of
linear
(x x') + < x , x ' >
{x' E E': < x , x ' >
(resp.
dual
we w r i t e
nondegenerate, and
the
space
h~(R)
Let us d e f i n e norm
topology,
of c o m p l e x - v a l u e d in it two k i n d s which
is g i v e n
bounded
of t o p o l o g y . by the
sup-norm
77
Ilhll
(6) for
h E h~(R).
: sup{ih(z)I:
z • R}
The second one is the B-topology
(or the strict topol-
ogy), which is the main objective of this section. this,
let
tions
f
C0(R) on
In order to define
be the space of all c o m p l e x - v a l u e d continuous
m
compact for any
i.e.
e > 0.
forms a Banaeh space with
Clearly,
C0(R)
{z • R:
func-
that vanish at infinity,
If(z)l ~ e}
is
respect to the usual a d d i t i o n and scalar m u l t i p l i c a t i o n of functions and the s u p - n o r m of the form (6). Now, for every setting
Nf(h)
f • C0(R)
= llfhll .
we define a seminorm
The totality
{Nf: f • C0(R)}
determines a locally convex t o p o l o g y for topology.
In other words,
f
ranging over
for this topology.
in
h~(R)
by
of seminorms
h~(R), which we call the B--
the c o l l e c t i o n of sets of the form
Vf = {h • h ~ ( R ) : with
Nf
llfhrl < i},
C0(R) , makes up a basis of n e i g h b o r h o o d s of
The space
h~(R)
0
e q u i p p e d with the B-topology is
denoted by h ~ ( R ) .
5C. dual of
We want to determine the dual of h~(R).
Let
Borel m e a s u r e s on
Mb(R)
R.
hB(R) , which we call the B-
be the space of all c o m p l e x - v a l u e d bounded
This forms a Banach space with respect to the
usual a d d i t i o n and scalar m u l t i p l i c a t i o n of m e a s u r e s and the total variation norm tional on
IJ~II : fR C0(R)
Id~I"
(7)
for
Each
~ e Mb(R)
determines a linear func-
by means of the formula
: I hd~ JR As we see easily by means of Riesz's r e p r e s e n t a t i o n h E C (R). 0 is identified via (7) with the dual C0(R)' the space Mb(R)
theorem,
of the Banach space N(R) and denote by
C0(R).
= {~ E Mb(R): M{(R)
the
On the other hand, we set = 0
(algebraic)
for all
h E h~(R)]
quotient space
Mb(R)/N(R).
Then
we have the following: Theorem.
The space
(algebraically)
h~(R)
is s e m i r e f l e x i v e and its dual
identified with
h~(R)'
is
M{(R).
Proof. The proof is divided into three parts. (a) First we show that the dual h~(R)'
is a l g e b r a i c a l l y equal
78 to
M{(R).
Let
is c o n t i n u o u s i, 2, ... } Un=l ~ Kn
hB(R).
of c o m p a c t and
Urysohn's R
~ E Mb(R) ; t h e n the l i n e a r
on
To see this,
subsets
such that
fn : 0
on
R.
to
on
a measure
R\ Int(Kn+l) ,
K0
=
[ n=0
= i
fn' on
defined
d~'
{Kn: n = R =
We t h e n use
n = i, 2,...,
Kn,
and
on
0 =< fn =< i
by
2-kf k
2 -n-I £ f £ 2 -n+l
denotes
by s e t t i n g
IB'J(R)
[ k=l
and in fact
where
~'
n : i, 2, . . . .
functions
T h e n the f u n c t i o n
C0(R)
n = D, i,...,
for
F : h ÷
a sequence
K n =C Int( Kn+l) ,
such that
continuous
f = belongs
R
I ~ I ( R \ I n t ( K n )) =< 4-n
l e m m a to d e f i n e
everywhere
of
functional
we c h o o s e
the e m p t y
= f-ldu.
i~'I(Kn+ I \ K n) ~
on
subset.
Then
[ n:0
Kn+ I \ K n
Finally,
for
we d e f i n e
~' E Mb(R) , b e c a u s e
2n+li~l(Kn+ I \ K ) n
co
< 2 1 ~ I ( K I) +
It f o l l o w s
that,
for every
[ n:l
2n+1-4 -n < ~.
h E h~(R),
iF (h) I : i I = l i < Jlfhll ilp'il = I[~' IINf(h) . Hence, have
F
is ~ - e o n t i n u o u s .
s h o w n that
M~(R)
S i n c e this
In o r d e r to see the r e v e r s e linear that
functional IF(h)I
functional setting
F
on
~ Nf(h) FI
= F(h).
This
IF(h) l ~ Nf(h)
= llfhll = 0.
continuous
fh~(R)
theorem space
on
FI
without
dual of
C0(R)
measure
~" E Mb(R)
Then there h • h a (R).
~ C Mb(R) , we
fh~(R)
an
for
the bound.
Fl(fh)
F2
Therefore,
the f u n c t i o n a l
= F2(fh)
= I
C0(R)
by
implies FI
is
By use of the H a h n - B a n a c h on the B a n a c h
As we r e m a r k e d
Mb(R).
which represents
of
fh = 0
such
a linear
]Fl(fh) I ~ llfhll ,
to a l i n e a r f u n c t i o n a l
with
f E C0(R)
= {fh: h E h ~ ( R ) }
is w e l l - d e f i n e d ,
changing
z
exists
8-continuous
We t h e n d e f i n e
Since we have
is i d e n t i f i e d
F(h)
we take any
in the n o r m t o p o l o g y .
can be e x t e n d e d
C0(R)
inclusion,
h~(R).
for e v e r y
on the s u b s p a c e
Fl(fh)
is true of any
~ h~(R)'
above,
the
we can find a F 2.
So we h a v e
fhd~"
R Setting
d~ : fd~",
we see that
~ • Mb(R)
and
F(h)
= fR hd~
for all
79
h • h (R). (b)
This means that
hB(R)'
the B-topology--if
subset of
sup{Nf(h):
h~(R).
and therefore
A
let
A
: M~(R),
sup{llhll
be any B-bounded
sup{lI:
for every fixed
~ E Mb(R).
: h • A}
<
subset of
via the formula
h~(R).
Then
A
As we have seen in (a)
Fh(~)
h • A} <
On the other hand,
be viewed as a linear functional, = .
say
every
h • h~(R)
Fh, on the Banach space
Since
Mb(R)
contains
can Mb(R)
all point mea-
R, we see that
IIFhll for every
Our property Mb(R)'
and therefore
embedded
in the dual
(8) then says that
By the principle
[8], p. 52), norm-bounded (e)
~ e Mb(R) , I1~11 S i} = Ilhll
= sup{II:
h E h~(R)
isometrically
A
that the Banach space Mb(R)'
A
in the space
in the space
h~(R),
h~(R)
in (b) as well as Theorem
that the ball
B : {h • h~(R):
let
{hl: I E A}
closed unit ball,
say
functions
BI, of
(Dunford and Schwartz
Mb(R)'
L~(dx )
is semireflexive.
B. for
Then,
the net
hl's
is contained
(Theorem
by means
(Dunford and Schwartz
there exist a subnet such that
{hl,}
{hl,:
converges
l' E A'} to
h*
BI
3B).
LI(dx ),
theorem
is
of
By the to prove
is w(h~(R),Mb(R))-compact.
the dual of the Banaeh space of Alaoglu's
and hence
5A, it is sufficient
IlhlI ~ i}
be any net in
of fine boundary
Mb(R).
as claimed.
Finally we will show that
consisting
is
bounded as a subset of
of uniform boundedness
is norm-bounded
ha(R)
of the Banach space
is weakly*
fact mentioned
namely,
f • C0(R) , we have
it is an easy matter to verify that
(8)
Thus,
A
: h • A}
in the weak topology w(hB(R),hB(R)').
h~(R)'
sures on
for any
in
Let
is 8-bounded.
Conversely, is bounded
is B-bounded--bounded
in the norm topology.
Then,
h • A} : sup{Ufhll
< Ilfll
as was to be proved.
h~(R)
and only it is bounded
be any norm-bounded
that
~ M{(R),
Next we show that a subset of
{hl:
Since
I • A} in the
L~(dx )
is
is w ( L ~ ( d x ) , L l ( d x ) ) - c o m p a c t {h l}
[8], p. 424).
and an element
So
h* • B I
in the topology w(L~(dx),LI(dx));
we have
I
(hl'- h*)f*dx ÷ 0
£I
for every
f* E LI(dx).
Since the map
h ÷ h
is a isometric
linear
80
map of the normed space h~(R) onto L~(dx) (Theorem 3B), there exists an h E h~(R) such that IIhll ~ I and h = h* a.e. Now we take any E Mb(R)
and set f*(b) = [ kb(Z)d~(z) JR
for any
b E A I. ;
Then,
f*
belongs to
'f*(b)'dX(b)~
;
gI
[; gI
LI(dx); in fact
kb(Z)'d~(z)l]dx(b) R
: IR[I
kb(Z)dX(b) ] Ida(z) I AI
JR
We thus have I
(hl,(z)-h(z))dg(z)
: SR[I
R
(hl,(b)-h(b))kb(Z)dX(b)]d~(z) A1
= S
(hl,(b)- h(b))f*(b)dX(b) A1
= I
(hk,(b) - h*(b))f*(b)dx(b)
+ 0.
A1 Namely, the subnet w(h~(R),Mb(R)). desired. [] 5D.
{hk,]
converges to
This implies that
B
h
with respect to the topology
is w(h~(R),Mb(R))-eompact,
Here is another characterization
of the dual of
h~(R).
Theorem. A linear functional F on h~(R) is B-continuous only if there exists a function f* E LI(dx ) such that (9)
F(h)
= [ J
for
h E h~(R).
dual Proof.
h~(R)' Let
F
hi(R)
h(b)f*(b)dx(b) F ÷ f~
onto the space
be any 8-continuous for
h E h~(R).
is
a bijection
from the
B-
Ll(d×).
linear functional on
by Theorem 5C, there exists a measure fR h(z)d~(z)
if and
£1
The c o r r e s p o n d e n c e
of
as
~ E Mb(R)
ha(R).
such that
Since Theorem 3B shows that
Then,
F(h) =
81
h(z)
: I
h(b)kb(Z)dX(b) £i
for
h E h (R), we have by use of the Fubini theorem F(h)
with
f*(b)
: fR kb(Z)d~(z)
Conversely,
let
it suffices
{h E h~(R): h~(R)
F(h)
h(b)f*(b)dx (b) AI
e LI(dx).
f* E LI(dx)
by means of the formula uous,
= I J
(9).
In order to prove that
to show that the kernel = 0], is closed
is equal to
M{(R)
h~(R).
Banach space
it is sufficient space of
Mb(R)'
Schwartz of
respect
Ker(F)
So it is enough to show that we know already that prove that {hl:
B
Ker(F) A B I @ A}
in
As before, w(L
(dx)).
Mb(R)'
B'
of If
Mb(R)' B
of the 5C, then sub-
(Dunford and is compact with
denotes
the closed unit
IIhll ~ i} = Ker(F) NB. is w(h~(R),Mb(R))-compact.
is w(h~(R),Mb(R))-compact,
Ker(F) N B
such that
if and
w(h~(R),Mb(R)) -
theorem
is w(h~(R),Mb(R))-closed.
I E A]
Since the dual of
if (and only if) the intersection
Ker(F) ~ B
converge
suppose that a
to some element
k E B
We then take fine boundary {hl,:
{hl,}
I' E A'}
converges
In partlcular,
to
of h*
As
so we have only to Thus,
in the closed unit ball
there exist a subnet
h* E B I (dx),L
{hl:
is B-continF, given by
then
the weak topology w(h~(R),Mb(R)). to form a net
h~(R)
is a W ( M b ( R ) ' , M b ( R ) ) - c l o s e d
to the topology W(Mb(R)',Mb(R)). h~(R),
on
is B-closed
in the dual
with the closed unit ball space
F
(b) of the proof of Theorem
Ker(F) N B' : {h E Ker(F):
ment
Ker(F)
In view of the Krein-Smulian
ball of the normed
net
5C,
h~(R)
[8], p. 429), this happens
Ker(F)
F
of
or, equivalently,
as in the part
to prove that
Ker(F)
in the B-topology.
by Theorem
If we embed
Mb(R)
(9) holds.
and define a functional
only if it is w ( h ~ ( R ) , M { ( R ) ) - c l o s e d closed in
Hence,
BI
of
{hl]
in
functions L~(dx ).
and an ele-
in the weak*
topology
we have
S
( h l ' - h*)f*dx ÷ 0
Since
hl, E Ker(F),
AI
for the function and therefore dition
h0 = h*
f*.
fA I h*f*d X = 0. a.e
If we determine
, then the subnet
topology w(L~(dx),LI(dx)).
fA I
{hl,}
,f*d X : F(hl,) h 0 E h~(R)
converges
to
So, as in the proof of Theorem
= 0
by the conh0
in the
5C, we have
82
hl, ÷ h 0
in the topology w(h~(R),Mb(R)).
It then follows
that
k = h0
and thus
F(k)
: F(h0):
I
h0f*dx
: I
AI namely,
k C Ker(F).
h*f*dx
= 0;
AI
Consequently,
Ker(F) N B
is w(h~(R)~Mb(R))-closed,
as was to be shown. Finally,
the map
(h: h • h~(R))
F ÷ f*
coincides
given by (9) is injective,
with
As an easy consequence
L~(dx )
3B.
[]
of the theorem we have the following
Corollary.
A subspace of
h~(R)
is B-closed
in
under the map
h ÷ h
is closed
L~(dx )
for the set
as shown in Theorem
if and only if its image
in the weak* topology
w(L~(dx),LI(dx)).
NOTES There
is a large literature
for §i is Chapters
3, 4, 5 of Hoffman
are taken from Hasumi concerning [SI].
on the
[34].
[17] and Neville
harmonic majorants
Results
fied form,
on classical
6-topology
Results
[47].
are adapted
from Rubel and Shields
Hardy classes.
from Heins
in Subsection [47].
Results
Our source
in Subsection in Subsection
3 4
[31] and Parreau
5 are taken,
in a modi-
CHAPTER
The m a i n first
theme
objective
to p r o v e
stated
every
arbitrary the
type
with
type,
deleting
we are
by M.
Parreau. at the
Unless face
and
point
§i.
i.
A few
IA.
For
principle
every
(A2)
0 • R
~ > 0
in Ch.
R
and
that
follows
that
for any
gous
zero
in the
case
~ ~ ~'
Hl(R(e',a)) Let
B(~,a)
number
the
Green
fact
indicates
same
as the
of W i d o m ' s
by
R
that
an
a surface theory, that
of by
the
one g i v e n theorem
a hyperbolic
function
is f i x e d
FUNDAMENTAL
for h a r m o n i c
in
to
from
fol-
down
defi-
earlier
are men-
and
for
R
is c a l l e d
Riemann
with
pole
the o r i g i n
sur-
at a of
R.
PROPERTIES
Definitions
property
region
we d e n o t e
= g(a,z)
and
R(~,a) The
shown
of
is
proof
It is a l s o
of p o t e n t i a l
and
chapter.
otherwise,
AND
the
The
to w r i t e
is o b t a i n e d
consequences
type
theorem
one.
Our
surfaces
but we try
sense
This
is e s s e n t i a l l y
A point
DEFINITIONS
type
in the
chapter.
of
Widom's
the o r i g i n a l
of W i d o m
this
definition
to Widom.
subset.
direct
end of this
ga(Z)
a • R.
Basic
discrete
with
TYPE
of P a r r e a u - W i d o m
The
modification.
is r e g u l a r
adopting
surfaces
than
as that
of P a r r e a u - W i d o m
which
stated
by
weaker
lines
begins
theorem.
according
some m i n o r
a certain
nition
tioned
same
surface
same
is g i v e n
OF P A R R E A U - W I D O M
notes
Riemann
fundamental
slightly
the
detail
SURFACES
is to d e f i n e
in a f o r m
almost
RIEMANN
of the p r e s e n t
H. W i d o m ' s
Parreau-Widom
lows
V.
~ 0
be the
of g e n e r a t o r s
show
R \ ~(e,a) ~ ~ 0
surface
a singular R
if and
a natural
among
singular Betti
of the
that
has
set
function every
1-chain only
and
the m a x i m u m
R(~,a)
no c o m p a c t
is a c o n n e c t e d
components.
in
R(~,a)
if it is so in
inclusion homology
number
group
we > el.
6A of the G r e e n
functions
first
a • R
: {z • R: g(a,z)
I,
we h a v e
~ HI(R)
every
relation groups
of the r e g i o n
HI(R(~,a)).
So,
It then is h o m o l o R(e,a).
In
HI(R(~,a))
(Theorem R(e,a), when
2C,
Ch. I).
i.e.
a point
the a @ R
84
is h e l d
fixed,
for all
sufficiently
isomorphic
B(e,a)
with
Definition.
is a n o n i n c r e a s i n g
large
an o p e n
disk
A hyperbolic
Parreau-Widom
type
~,
function
for the r e g i o n
for all
Riemann
(abbreviated
S
large
surface
e
and
vanishes
is c o n f o r m a l l y
e. R
is c a l l e d
to a P W - s u r f a c e
B(~,a)d~
~
in
R(e,a)
a surface
or PWS)
of
if
<
0
for
some
a ~ R.
IB. choice Let
We
of
V
first
be p a r a m e t r i c
the b o u n d a r y we can
hold
find
~G
of
every
(Theorem
6A,
taken
I).
any
ZG.
for we k n o w If we d e n o t e
on the
boundary
This
means
not
such
that
and
s0
the m i n i m u m
therefore
verge
tial as
{z E R:
Theorem.
If
a',
~ g(a,z)
inequalities
ga'
= H[ga';G]
of
g(a,z)
0 < ~ < e0 B(~,a)
~ A
and
we have
~ B(A-I~,
a')
B(a,a)d~,
R
R
at
of
is r e g u l a r ,
S
~ B(~,a)d~ 0
a E R.
Such
the
function
Green or,
for any
which
in the
con-
~ > 0.
This
w C R
z = w.
we r e p e a t
property
Z(a;R)
according
= ~{g(a,w):
is a PWS
w e Z(a~R)}
if and
only
if
to
zero
region
is a c r i t i c a l Let
of p o t e n -
tends
the
then
a surface
d~
sense
ga(Z)
equivalently,
A point at
f0 B ( ~ a ' )
to be proved.
regular
= 0
ga'
and
is c a l l e d
a.
= ~ga/~ of
as was
infinity
is c o m p a c t choice
f0 B(~,a) d~
time,
a E R
point
points
(i)
for e v e r y
some
~ga/~Z
critical
same
surface
~ ~}
of the if
integrals
at the
to the
g(a,z)
ga(Z)
of all
two
if for
tends
independent of
that
A Riemann
theory z
Since and
~0
or d i v e r g e
IC.
respec-
that
B(~,a')d~
therefore
a
same
and
for any
~0
and
a',
A-ig(a',z) the
= H[ga;G]
by
and
contain
of fact,
~G, t h e n
~ R ( A - I ~ , a ') ~ R ( A - 2 ~ , a )
B(A-2~,a).
ga
a
of the
a, a' E R.
G : R \ (CI(V U V ' ) ) .
does
A > 0
As a m a t t e r
points
centers
set
and
is i n d e p e n d e n t
distinct
with
and
is c o m p a c t
definition
two
disks
constant
z @
z E G,
Ch.
above
take
closures,
G
a positive
g(a',z) R(~,a)
disjoint
for any
for
the
V'
having
Ag(a',z)
that
In fact,
and
tively,
note
a ~ R.
is a g a i n point
be the
set
to m u l t i p l i c i t y .
88
[{g(a,w):
(2) for some
(and h e n c e
Proof.
Since
2,...}
of p o s i t i v e
level
h
bordered to
Z(a;R)
curves
We set
all)
is d i s c r e t e ,
numbers
= Cl(R(an'a))"
g ( a , z ) - a n.
gn(a,z).
extended
Let
~n(a,z)
gn'
denotes
points
in
Rn, then
deg(T)
=
readily
I~a
denote
2.
(9) in Ch.
= gn' = N n
gral
B(~,a)da
:
_anB(a n
,a) -
if
~ g(a,w) foB(~,a)da
e ~, t h e n < ~,
n ÷ ~, and thus Parreau
inequality on G r e e n
of
single-valued
R'n deg(T)
has
but
and can be
Nn
in v i e w of Ch. 2, . . . .
of
Rn . : 2 g ~ - 2,
critical
zeros and two poles, n = i,
is e q u a l
so that I, 2B
It f o l l o w s
+ [{ga(W):
f0 B ( ~ , a ) d a
inition
clature
type.
w e Z(a;R), e ~
ga(W)
Conversely,
This
B(a,a)da
< ~.
> an}. if the inte-
÷ 0
H e n c e we get the e q u a l i t y
regular
in sueh surfaces.
for the s u r f a c e s
Riemann
surfaces
to d i s c u s s As we shall
e n o u g h to c o v e r is p r o b a b l y
we are d e a l i n g
[]
for w h i c h the problems
see in 3B below,
in e s s e n c e
enough
R
Diriehlet
(i).
all s u r f a c e s
to l e g i t i m a t e
based
his defof
our n o m e n -
with.
Characterization
A remarkable
a hyperbolic
~
His a i m was
is i n d e e d g e n e r a l
Widom's 2A.
[ g(a,w)
[52] c o n s i d e r e d
lines
~dB(a,a) n
then
(2) holds.
Parreau-Widom
2.
I ~a
n
anB(an,a) as
a
conjugate
and h a v e
is c l e a r
Z(a;R).
is a c o m p a c t
on the d o u b l e
gn(a,z)
for
n = i,
that
= -anB(an,a) So,
If 2N n
gn' = B(an,a)
B(an,a)
that
R'.n
h
is s i n g l e - v a l u e d T
in
w i t h pole
the h a r m o n i c
I, 10D,
s h o u l d have
Since
every
is not n e c e s s a r i l y
the genus of T
any p o i n t
gn(a,z)
differential
{an:
to zero such that the
is r e g u l a r ,
d(gn(a,z) + i~n(a,z))
where
we c o n c l u d e
R
function
~n(a,z)
to a m e r o m o r p h i c
-
decreasing
do not c o n t a i n
Since
So we can use the f o r m u l a
2N n
= a n}
its G r e e n
the d i f f e r e n t i a l
we can find a s e q u e n c e
strictly
and
The f u n c t i o n
<
a C R.
{z E R: ga(Z)
surface
w • Z(a;R)}
Riemann
characteristic
surface
property
due to W i d o m
is a PWS if and o n l y
if it has
says that sufficiently
88
many
analytic
functions.
we n e e d
the n o t i o n
fact, in Ch.
to give
a precise analytic
statement
of this
functions
explained
II.
Given ~(R,~)
a line
bundle
of h o l o m o r p h i c
Theorem that
In o r d e r
of m u l t i p l i c a t i v e
2C,
Ch.
if(z)i p
II,
~ • HI(R,T)
sections
says
that
(0 < p < ~)
over
of the
R, we c o n s i d e r
bundle
if(z)l
6.
If
is an l.a.m,
is a s u b h a r m o n i c
on
function
the
space
f • ~(R,~), R
on
and R.
then
therefore
We
set
surface
R.
llfllp = llfllp,0 : { ( L H M ( B f B P ) ) ( 0 ) } I/p, where
LHM
stands
for the
Ifi p
has
no h a r m o n i c
least
harmonic
majorant,
then
majorant
on the
is d e f i n e d
Nfli
to be
+~.
If When
P p = ~, we
set z •
ilfil : s u p { I f ( z ) i We t h e n
define
for
every
R}.
0 < p ~
~P(R,~)
= {f • ~ ( R , ~
:
iifiL
~}.
<
P Obviously,
~P(R,~),
to the n o r m in Ch.
II,
i ~ p ~ ~,
iR-ilp, if a d d i t i o n
The
fundamental
Theorem.
The
following
multiplication
result
of W i d o m
statements
are
reads
~ {0}
for any
line
bundle
~ E HI(R,~);
(c)
~A(R,~)
~ {0}
for any
line
bundle
~ e HI(R,~).
The
original
as
is a PWS;
statement flat long
form
(b)
and
We
regular
PWS.
Lemma.
Let
Then
bundle
is g i v e n
show
First R
not
in
that
we p r o v e
there
finite
exist
R.
§§2 and
for
asserts
line
The
every
much
bundles
proof
more
but
and
also
of the a b o v e
in fact
for any
theorem
is
3.
of P a r r e a u - W i d o m
the
be a h y p e r b o l i c are
theorem
only
over
of S u r f a c e s
shall
B(~,a)
of W i d o m ' s
is v a l i d
vector
Regularization
R.
defined
equivalent:
R
numbers
respect
as follows:
~(R,~)
3A.
with
are
(b)
rather
in
scalar
space
(a)
unitary
3.
and
Banach
2D.
2B.
the
is a c o m p l e x
PWS
Type
is n a t u r a l l y
embedded
in some
following Riemann
for all
a regular
surface
~ > 0
and
hyperbolic
for w h i c h some
Riemann
the
Betti
(and h e n c e surface
all) Rt
and
a
87
a discrete cerning The
subset
Betti
regular
E
of
numbers
surface
R*
and R%
such that
R
R*
has
is c o n f o r m a l l y
is d e t e r m i n e d
the
same property
isomorphic
uniquely
by
R
with
con-
R % k E.
up to a e o n f o r m a l
isomorphism. Proof.
(a)
First
is f i n i t e . of
R
Then
satisfying (i)
sets
of
the
we assume
there the
(ii)
for e a c h
curve,
CI(V.) i
onto
Vi
is c o n t i n u o u s l y
the
{w e ~: r i < (iii)
Ji'
Betti
number
of o p e n
are m u t u a l l y
which
of
R
subsets
disjoint
itself VI,...,
Vm
noncompact
sub-
m.
Take
form a formal
parametric
disk of
maps
lwl
Ji
i, t h e n
< I}
onto
R
is a s i m p l e
(0 ~ r i < i)
the
bordered itself
closed
homeomorphism
of
C I ( V i)
unit
circle;
Riemann
is e a s i l y
hi
such that onto
surface. s e e n to be r e g -
that
union
R T = RUB.
Va, w h i c h
R.
Vi
r. = 0 for s o m e i. F o r the sake of m that r. = 0 for i = i,..., s and r. > 0 f o r i i a set of s e l e m e n t s , say B = {b(1),..., b(s)},
we assume
i = s+l,...,
of
a eonformal
to a h o m e o m o r p h i s m
is a c o m p a c t
for all assume
~V i
exists
{w e ~: r i <
extendable
R \ (u'm~l=± Vi)
simplicity,
boundary
and there
annulus
lwl ~ i}
r. > 0 i So w e m a y
structure
i, t h e
say
of
and
first number
following:
closures
hi
ular.
the
a finite
R;
analytic
If
that
exist
For
To e a c h
is c o m p a t i b l e
each
i : i,...,
point
with
the
s, we put
a E R
we a s s i g n
given
conformal
Vb(i)
= V i U {b(i)}
a
and
h*(z)
We regard follows
(Vb(i) , h~)
from our
fine a conformal structure the
of
to t h e
So the
Green
extended clearly that
the
Take the
disk
full
open
function
by c o n t i n u i t y
surface
the R
put
is e q u a l R
induces
known,
every
0 <
disk
lwl
< i}
with
of
together
the
harmonic
a E R
for
R %.
R ¢. We m a y
It de-
original function
a harmonic
pole
function
boundary
R
b(i).
c a n be c o n t i n u o u s l y
so as to h a v e R
disks
on
bounded
point
on ex-
function.
can always This
function
thus
conclude
be
is r e g u l a r .
~ > 0 R
the
parametric
Green
ideal
disk about
these
to t h e
any
(a),
z = b(i).
which
for
We now consider
in
for
R%
g(a,z)
(b)
and
z E V. I
that
{w e ~: unit
on t h e R%
on
is w e l l
unit
vanishes
surface
shown
structure As
for
as a p a r a m e t r i c
construction
R.
punctured
tended
= {~ i(z)
to
general = R(~,a). B(e,a)
c a n be c o m p l e t e d
case. Since and
Let us the
fix a point
first
so is f i n i t e .
to a r e g u l a r
surface
Betti
a E R.
number
of
As we h a v e RT
by a d d i n g
88
a finite
number
0 < 6 < e, region
the
of the
of p o i n t s surface
to
Re .
surface
t {z e R~: where this
g6(a,z)
denotes
identification
It is not
gB(a,z)
the G r e e n
for all
e,
Rt
the
is a r e g u l a r
of t h e
B
with
(R t,
hyperbolic
It is a r o u t i n e
Z)
Riemann
We are
Theorem.
Let
numbers
R
Then
boundary
are
finite
the r e g u l a r
A(R)
only
a, and,
set
surface
of
Z
R
from
which
those
of
satisfies
uniqueness
a.
With
Rf
then
the p r o p e r t y
and
surface
Let
of the
pair
following
surface
~ > 0
hyperbolic
such that
the
Riemann
for any
is at m o s t
for each
Z
for w h i c h
some
Rt
be t h e
a point
into
countable
b E [, t h e r e
there
Rt
relative
R*
exists
obtained
b E A(R)
the
(and h e n c e
subset
Betti all)
in L e m m a
3A
of the M a r t i n
belongs
to
~
if
of
and
independent
a neighborhood
R
VAA(R)
with
a uniquely
Rt
> 0.
exists
of
a hyperbolic
topology
determined
Riemann
of
choice
V
b
of
= {b}.
conformal
surface,
as a s u b s p a c e
of the
and
in t h e
On the u n i o n structure
is c o m p a t i b l e
R*,
of
with
satisfies
the
which the fol-
properties:
(BI) of
Rt R%
(B2)
is a r e g u l a r induces
If
intersection bounded
pole
[]
to p r o v e
as f o l l o w s .
compactification
R t = RU Z
ture
with
if
the
lowing
R t6
for
induced
l i m sup g ( a , z ) Rgz÷b
makes
sub-
6},
to s h o w t h e
be a h y p e r b o l i c
B(e,a)
R.
Martin
if
the
~ > 0}.
isomorphism.
in a p o s i t i o n
c a n be c o n s t r u c t e d
Then
with
0 < 6 < ~, w e put
structure
matter
up to a c o n f o r m a l
3B.
and
conformal
to s h o w that,
identified
lemma.
(c)
in
R%
> ~
function
R t : u{Rt: If we g i v e
difficult
R % m a y be c a n o n i c a l l y t~ R B d e f i n e d by
V
to the
point
to t h e
conformal
(B3)
The
b
hyperbolic
R
reduces
function
u
so as to get structure
Green
surface
the o r i g i n a l
is a n e i g h b o r h o o d
V A&(R)
harmonic
on
of
function
of
to the on
b E ~ single
VNR
a harmonic
and the
conformal in
R*
point
c a n be
conformal
structure such
b, t h e n
extended
function
on
V
of that
strucR. the
every
by c o n t i n u i t y with
respect
R t. gt(a,z)
for
Rt
with
pole
a E R
is
89
o b t a i n e d by e x t e n d i n g the Green function in
~
function 0 E R
kt(b,z)
for
Rt
with pole
in the t o p o l o g y of (B4)
b
for
and
face
0
R
Similarly,
to the points the Martin
and with respect to the origin
to the points
k(b,z)
in
~
for
R
by c o n t i n u i t y
R*.
The M a r t i n c o m p a c t i f i c a t i o n of
Rt
can be identified with
AI(R ) = AI(Rt ) U ~.
(B5) Rt
The h a r m o n i c m e a s u r e at the origin
0
dx t, supported on
at the point (B6)
Proof.
If
Let
(BI) and
AI(R t), of the sur-
is nothing but the restriction,
AI(Rt) , of the h a r m o n i c m e a s u r e R
R*.
is o b t a i n e d by extending the Martin function
with respect to the same origin
R*
g(a,z)
by c o n t i n u i t y in the t o p o l o g y of
dx, supported on
to the set
AI(R) , of the surface
0. R
is a PWS, then so is
(R t, ~)
R t.
be a pair given by Lemma 3A.
(B2) are clearly satisfied.
Then the properties
So we prove here that
Rt
has
the r e m a i n i n g properties. Property in
(B3):
The p r o p e r t y
R, the Green function
(B2) implies that,
z' ÷ g(z',z)
for
R
extended by c o n t i n u i t y to the Green f u n c t i o n So the d e f i n i t i o n of the Martin functions z E R, the function continuity,
Property on
Rt
(B4):
say
Rt
is o b t a i n e d by extending,
with
z E R, the function
z E R
also separates points of
R #.
~ = A(R) \ A(Rt).
Since E
Rt
b E Z, then the f u n c t i o n
tiple of have
gion
gt(b,z)
~ ~ AI(R)
b ÷ kt(b,z)
b ~ k(b,z) R #.
Hence,
R#
R* = R #.
is regular,
on
Since the set
separates points of
R#
and
b ÷ kt(b,z)
with
can be i d e n t i f i e d with In particular,
we
we conclude that a point
= gt(a,b)
z ÷ k(b,z)
> 0.
is equal to a constant mul-
and so is a minimal h a r m o n i c function on and t h e r e f o r e
R.
(B5):
This is clear from the above observation.
Property
(B6):
Let
Bt(~,a)
= {z E Rt: gt(a,z)
We thus
AI(R ) = ~I(R t) U ~ .
Property Rt(~,a)
by
E.
if and only if
lim g(a,z) Rgz÷b If
function on
zt ~ Rt
R, i.e.
in
function on the Martin compacti-
R t, the subfamily of functions
the Martin c o m p a c t i f i c a t i o n of
belongs to
to the points
and t h e r e f o r e the function
R
have
for each fixed
R
since
b E ~(R)
R t.
on
b ÷ kt(b,z t)
is dense in
shows that,
z is
for
Rt
can also be extended to a continuous
of functions
z E R
on
For each fixed
R #, of
with pole
z' ÷ gt(z'~z)
b ÷ k(b,z)
can be extended to a continuous
fication, R
b ÷ kt(b,z)
the f u n c t i o n
for each fixed
be the first Betti number of the re> e}, where we assume
a E R.
Then,
90
Bt(~,a)
S B(e,a)
So
is a PWS wh~enever
RT 3C.
to
R
for all
We now c o m p a r e
and
~ > 0 R
f0~ B t ( a , a ) d ~
and thus
is.
S /0 B(e,a)de.
[]
the i n t e g r a l s
of Betti
numbers
corresponding
Rt .
Theorem.
Let
critical
points
of the set
R
be a PWS and let of the f u n c t i o n
Z(a;R t)
I~ B ( ~ , a ) d ~ 0
that
a • R.
Then the
z ÷ g(a,z)
lie in
: I v Bt(~ ,a)de 0 : [{gt(a,w):
R
set
consists
Z(a;R)
of those
of
elements
and we have
+ [ {gt(a,w) : w • E}
w e Z(a;Rt)}
+ [{g¢(a,w):
w • ~}.
for n = Proof. Let E : {Wl, w2,...} and put R n = R t \ {w I ,. ..,w n} i, 2, . . . . Denote by B (~,a) the first Betti n u m b e r of the s u b r e g i o n n we have Rn(~,a) : {z E Rn: gt (a,z) > ~}. Since R n = Rn_ I \ {w n} ~B n l(a,a) = ~Bn-l( ~ _ ,a) + i
Bn(~,a)
for
e > gt(a
) 'Wn ~ < gt(a,Wn).
for
So we have
F
0 Bn(~'a)d~
:
:
Since
Bn(a,a)
the d e s i r e d
§2.
PROOF
result.
4.
stated
Analysis 4A.
section
~ Bt(a,a )d ~ 0
n~_ gt(a,wk ) . k=l
monotonically
THEOREM
B(~,a)
as
n + ~, we get
we prove
(I) the i m p l i c a t i o n
on R e g u l a r
(a) ~ (b) in W i d o m ' s
the-
Subregions
We begin with the f o l l o w i n g
[31],
to
+
in 2B.
For an i n t e r e s t i n g Heins
+ g t ( a , w n)
[]
OF W I D O M ' S
In this orem
converges
i
0 Bn-l(~'a)d~
p.
75.
proof
of this
classical
crucial
result
theorem we r e f e r
of C a u e h y - R e a d . the r e a d e r
to
91
Theorem. IA and
Let
let
(a) at a l m o s t
G
be any
i ~ p ~ ~. Every
f E HP(G)
every
b E
arc-length
measure
differential (b)
w
Let
a.e.
Then
on
on
4B. line
Let
G
connected.
which
~
union
every
is r e p r e s e n t e d
~P(G,~IG).
Since curves,
Assume
value p'
i.
= p/(p-
(3)
a.e. that
a simple
on
i < p < =
I).
Then
and
for any
inf{ll~llp,,~ ° :
Y
p'
line
we d e n o t e
the
exponent
-1
denotes
every
line
element
is bundle
to
bundle G \ C,
The
set
by the of a f i n i t e
nontangential same
symbol
vanishing residue exponent
~ E HI(R;~)
I~(a)l
inverse
CI(G).
of the
consists has
conjugate
: sup{li~(a)l: ~ • ~P(G,~-ln-lIG), where
of
function.
with
be a
CI(G) \ C
is d e n o t e d
is n o w h e r e
the
f.
a restriction
by the
a E G \ C
bundle
of
that
G
of
set of m e r o m o r p h i c
connected,
of
= 0
is e q u a l
< E HI(R,~)
the
has
(G,nlG)
•
f*
neighborhood such
f~G um
u
the r e s t r i c t i o n
ZG
f*(b) to the
neighborhood that
let
~ E ~P(G,~IG)
at a p o i n t
equation
holomorphic
the b o u n d a r y
ZG, w h i c h
Let
and
~P(G,{IG)
<0 E F M ( C I ( G ) , ~ ) pole
the
such
curves
in
respect
and
~. has
only
of a b s o l u t e of
p,
i.e.
we h a v e
: l}
IlfilIp,~ : 1}, in the
group
HI(R;T)
and
I lql l) ljq
r I1~11
We n o t e in some
that
for
1
q
for
q : ~.
is d e f i n e d
for any
<
= j/
[suP{If(z)I:
the n o r m
neighborhood
of
~G.
II-II q,~
z •
G}
I,
for any h o l o m o r p h i c
function
in some
~(G,~IG)
every
= 0
FM(CI(G),~)
denotes
in
value
in some
R
is s i m p l y
of s e c t i o n s
of a n a l y t i c
one pole,
in
by a s i n g l e - v a l u e d
symbol
Lemma.
by
61G
section
number
values
boundary
region
G \ C
boundary
of Ch.
CI(G).
satisfy
defined
defined
If
sense
with
f*~ of
f C HP(G)
of a n a l y t i c
Since
of such r e s t r i c t i o n s
boundary
~
a unique
We d e n o t e
is trivial.
G, t h e n
f~G
i ~ p ~ ~,
of
in the
f* E LP(3G)
and we have
differential
R.
R
a nontangential
that
be a r e g u l a r
over
G \ C
to
of
hold:
in a n e i g h b o r h o o d
exists
be a f i n i t e
simply over
subregion following
to the n o n t a n g e n t i a l
bundle
C
has
~G
differential-sections Let
the
such
u e LP(~G),
there
8G
~G
defined
for any h o l o m o r p h i c CI(G).
regular Then
m
given
only
92
Proof.
Take any
G.
~£P(G,<-in-ilG) and
~ •
the e o r r e s p o n d i n g
section.
So if we denote by
Ga
Then
lh(z)l
let
~P(G,g-lq-IIG)
h •
is a subharmonic
the harmonic measure of
G
be
function on
at the point
a
(Ch. I, 5D), then
(4)
lh(C)Id~(C)
[~(a)l: [h(a)l £ I ~G
max ( w G ( < ) / l ~ ( < ) ] ) ~EBG a Since
~
is n o n - v a n i s h i n g along
ferential along
~G
~G,
and therefore
[ Ihl [~lj ~G
!~l
is a strictly positive dif-
max{E~G(~( I ~ ) )/ ] ~_( ~ )
< ~.
Thus
by a p p l y i n g the H61der i n e q u a l i t y to the integral
in the last m e m b e r of
(4) we see that the e v a l u a t i o n map
is a continuous
functional on
~P(G,~-In-IIG)
norm of the functional
aa
llmall : sup{l~(a)I:
~ a : ~ + ~(a)
with respect to the norm
in
~P(G,~-Iq-IIG)
with its boundary values on
can be viewed as a subspaee of
I/F/I p' = I[a a II
~(a)
-
F • LP'($G,Iwl/2~)
By the such
1 I ~G F~I~I
~ • ~P(G,~-In-IIG).
we can find a h o l o m o r p h i c
differential
represent a.
CI(G).
in a n e i g h b o r h o o d of
simple pole at
a ~
with residue on
G \ C.
Since
w
[~/~ •
to a r e g u l a r s u b r e g i o n c o n t a i n i n g
section
v a n i s h i n g on some n e i g h b o r h o o d of
the point
~G, so that the space LP(~G,Iwl/2~).
2~i
By a p p l y i n g Theorem 3B, Ch.-II, CI(G)
We identify
and
(5) for every
The
~ • ~P(G,~-In-IIG) , ll~llp,~ =< i } ,
H a h n - B a n a e h theorem there exists a function that
ll.llp, .
is then given by
which is exactly equal to the r i g h t - h a n d side of (3). ~¢P(G,<-Iq-IIG)
linear
CI(G) i
k • ~f~(G,n-llG), which is nonLet
~
be any m e r o m o r p h i c
with only one pole which is a
(Theorem liB, Ch. I).
We may suppose that
~
Finally let
has residue
i
at
is nowhere vanishing,
~(G,~-ln-IlG) ~ ~:'P(G,g-ln-IlG)
and so, by (5), we have
If
a
is any h o l o m o r p h i e d i f f e r e n t i a l on some n e i g h b o r h o o d of
CI(G),
93 then if
~ +~ ~
has the
is r e p l a c e d
this h o l d s
same p r o p e r t y by
for all
~ + ~.
is e q u a l to the b o u n d a r y
Moreover
we h a v e i
We set
= i.
that
(6) r e m a i n s
]~G F ~ l ~ r / ~
e, T h e o r e m
function
f~
4A-(b)
to be v a l i d = 0.
Since
implies
of some
that
f0 @ HP'(G)"
:
= ~
f : f0/k.
If(a)l
9, so that
such d i f f e r e n t i a l s
F~I~I/~
fo(a)
as
It f o l l o w s
~G
Then
~G
f • ~P'(G,~IG) ,
Ifl = IFI
on
ZG
and
Hence,
inf{li~Up,,~:
~ • ~ P ' ( G , q I G ) , If(a)i
So in (3) the l e f t - h a n d Conversely, ~P(G,~-In-IIG) single-valued
if
side
is at m o s t
~ • ~ P ' ( G , n i G)
= i} =<
liFilp, =
liEali.
equal to the r i g h t - h a n d
with
Jf(a) I = 1
with
II~II = i, t h e n ~Z~ P,~ d i f f e r e n t i a l on G and so
and
side.
~ •
can be e x t e n d e d
to a
? i
~G This
shows the r e v e r s e
4C. gion
G
in
Theorem. which
The
inequality,
statement R.
Let
=
be any r e g u l a r
is h e l d fixed.
Then,
sup[inf{Uhli
p,a
g(a,.)
group
H I ( G ;T)
denotes
IIf IIp ,a :
{
The t i l d e h e r e d e n o t e s
n o t e that
in p
: h • ~(G,~),
R with
for any r e g u l a r
and t a k e a p o i n t
re-
a • G,
i ~ p £ ~,
rh(a)l
: i]]
w • Z(a;G)]],
function
for
I f ( { ) i P d g ( { , a ) ) I/P
suP{If(z)l:
Before
[]
G,
<
ranges
o v e r the
and [-2~
identical
P '~
2B is v a l i d
region
for e v e r y
the G r e e n
P'~
we show the f o l l o w i n g
= exp[[{g(a,w): where
'~
as d e s i r e d .
(b) in T h e o r e m
More precisely, G
P
proceeding
conjugate
harmonic
to the proof,
w i t h the one g i v e n Z(a,G)
z • G}
set.
i ~ p <
for
q = ~.
function.
we n o t e that the a b o v e
in 2A in case
is a f i n i t e
for
R = G
and
n o r m is
0 = a.
We also
Proof.
Consider
has a simple to
Z(a;G),
the m e r o m o r p h i c
pole at
a
the order
multiplicity
in
elements
Z(a;G).
in
differential
with r e s i d u e
of each
Z(a;G).
1
zero being
Let
dg(.,a) + idg(-,a),
and zeros
j
which
belonging
the same as the c o r r e s p o n d i n g
{Wl, w2,... , w m}
For each
at points
be an e n u m e r a t i o n
of
we set z
Aj(z) which
: exp[g(z,wj)
is m u l t i p l e - v a l u e d
fines a line bundle,
say
Ch.
set
II,
2D.
We then
but has
+ i
f
dg(',wj)], a
single-valued
<j, over
G
m ~' = (j~=l*=A j ] [ d g ( . , a ) + Clearly,
~' • FM(CI(G),~)
vanishing
on
a.
the r e s i d u e
Since
CI(G)
j•
with
of
~'
m = exp[~-
Aj(a)
-
co : r -I ~], along
i < p < ~
:i ~j"
Moreover,
simple
has a b s o l u t e g(a,wj)]
the h y p o t h e s i s
in case llfll q,a
Let
and set
it is n o w h e r e
pole--at
the
point
value
(= r, say),
of Lemma
4B.
Since
[~'I
= -dg(.,a)
q ;~ :
i1~ilq,~'
= rl/qEi~li q,~"
p' = p / ( p - i ) .
inf{ liflip, ,a : f e ~P'(G,T]), : rl/P'inf{U~lip,,
Then
Vf(a)i
Lemma
4B shows
that
: i}
: ~ e ~fP'(G,~),
1~(a)l
: i}
= rl/P'suP{i~n(a) I: ~ • ~{P(G,~-In-I),
iJ~nilp,~ = i}
: r l / P ' s u p {I h(a) I : h • ~ P ( G , ~ - I n -I),
UhUp, a : r I/p}
= sup{lh(a) I: h • ~ P ( G , ~ - I n -I), for any line b u n d l e
in
j=l
satisfies
~G, we have
a
it de-
idg(.,a)].
one p o l e - - a
at
so that
to our o b s e r v a t i o n
-]-]-j m
~ =
and has only
modulus,
according
q
over
G.
llhilp,a : r]
A similar
computation
is p o s s i b l e
for
p = I, so that we have (7)
inf{ iif ilp, ,a : f e ~fP' (G,q) = sup{lh(a)i:
for any line b u n d l e
over
If(a) i = i}
h • ~P(G,~-IT]-I), G
and for any
p
iihli
p,a
with
= r}
i ~ p < =.
Since
95
ihl p
is s u b h a r m o n i e ,
given
by
<-in-i to
(7)
is at m o s t
: nn -i : the
r, t h e n
side
of
we h a v e
h(a)
lh(a)[
equal
to
identity
: r
of
<
llhll p,a Setting
r.
Hi(G;T).
rlhfi : r. This p,a at this n. Hence
r
sup[inf{llflr p' ,a : f • ~{P'(G,n), n Writing all
p
p
in p l a c e
with
p',
we w i l l
~ = ~ii~ -I
seen
of the
case
that
so that,
by
__>r value
r
is e a s i l y
is r e a c h e d
seen
5A.
We are form.
Theorem.
Let
with
holds
for
~-lq-i
Letting
: ql'
, llhlil,a : r } If(a)I
= i}
= 6 -1
~i
h • ~(G,D),
and
f - i.
Thus
llhlll,a = i ] = r -1, to
h • ~(G,n),
lh(a)l
: r~
= i}]
[]
of N e c e s s i t y
following
p
at
to be e q u i v a l e n t
to be proved.
Proof
theorem
-i
sup[inf{llhJJl,a: n
5.
= r.
, llhlll,a : i}
: f • ~(G,~ll<-l),
inf[sup{lh(a)l: n
as was
the
equal
the r i g h t - h a n d
(7),
h e ~(G,nl)
= r-linf{IlfJl
which
that
: i}]
p = i.
= r -i sup{lh(a) I: h • ~(G,~I)
the
is i d e n t i c a l l y
If(a)l
we h a v e
dispose
sup{]h(a)J:
Here
h
means
I < p < ~.
Finally, we have
of
t h e r e f o r e the v a l u e ~-i n = in (7), we h a v e
If
and
(7) r e a c h e s
and
going
R
to p r o v e
(a) ~
be any h y p e r b o l i c
(b) of W i d o m ' s
Riemann
theorem
surface.
Then,
in the
for e v e r y
i ~ p ~ ~, sup[inf{IJfll
p,a
= exp
: h • ~P(R,$),
(I
B(a,a)da
If(a) I = i}]
),
0 where to
the
supremum
is t a k e n
{ ( L H M ( I f J P ) ) ( a ) ] I/p
if
over
all
p < oo
[ • HI(R,~), and
to
and
sup{If(z)l:
i[fH
p,a z • R}
is e q u a l if
p = =.
96
Proof.
Let
sisting
of c a n o n i c a l
{R : n : i, 2,...}
We then
denote
be a r e g u l a r
exhaustion
of
R
(Corollary
IC,
Ch.
con-
n
by
Rn(~,a)
first
gn(a,z)
the r e g i o n
Betti
number
We first p < ~
by
subregions
of
: inf{Iifll
Mn(~,a)
p,a
M(a)
definition
Rn
with pole
and by
Namely,
If(a)I
Bn(~,a)
we fix any
: i}
f • ~P(mn,~) , If(a)I
= sup{M(~,a):
Mn(a) With this
p.
for
> ~}
I).
p
a, the
with
1
<
notations:
: f • ~P(R,{),
= inf{iifiip,a:
function
gn(a,z)
R (~,a). n any finite
consider
a • RI
the Green {z • Rn:
and use the f o l l o w i n g
M({,a)
with
= i}
for
~ • HI(R;~),
for
~ • HI(Rn;T),
~ • HI(R;Y)},
: sup{Mn(~,a):
< • HI(Rn;~)}"
we c l a i m
(8)
M(a)
= lim M
(a). n
To see this,
let
~ • HI(Rn+I;~);
Mn(~IRn,a) Since Ch.
Rn
is c a n o n i c a l ,
II, that
bundle
over
surjection above
every R.
~ Mn+l(~,a)
over
HI(R;T)
inequalities
R
3B, Ch.
H I(Rn+ I;~))
Mn(a)
lim Mn(a)
so that
I, and T h e o r e m
is the r e s t r i c t i o n
n the r e s t r i e t i o n
(resp.
imply that
~I Rn • H I ( R n ;~)
~ Mn+l(a)-
we see by T h e o r e m
line bundle
In o t h e r words,
from
then
map
to
~ Mn+l(a)
IB,
of a line
~ ÷ ~IR n
HI(Rn;~).
is a So, the
£ M(a)
and c o n s e q u e n t l y
suppose
that
~ M(a).
n+~
In order
to get the r e v e r s e
inequality,
we may
lim M (a) < ~. n
n+~
~ @ HI(R;~).
Let us take any is d e f i n e d {V~}).
by means
Since
and that all
R V'
of an open
is separable,
closure
CI(V
tion of
Mn(~IRn,a)
an element
i n Ch.
covering
{V~}
we may assume
that
II,
1A, t h e
in the form {V '}
is
bundle ({~B},
countable
as well as all n o n e m p t y
Then we take a r e f i n e m e n t )
As e x p l a i n e d
{V }
is a compact implies
fn • ~ P ( R n , ~ I R n )
of the
subset that,
of
V' ~ R are simply connected. e n covering {V'} such that the V'
for each
satisfying
for each
~.
n : i, 2,...,
Ifn(a)l
: i
and
The d e f i n i there
exists
llfnllp,a
97
Mn(~IRn,a)
+ n -I.
Let
{V~ A R n } ~)
{fn }
{ V , A R n }~
to the c o v e r i n g of
~JR n.
fn~
is d e f i n e d
Let
un
be a r e p r e s e n t a t i v e of
Since
Rn
V ' AR n
each n o n e m p t y
as a s i n g l e - v a l u e d
be the LHM of
Ifn Ip
holomorphic
on
i I H fnt1$, a : -2--~,DR
of
fn
with respect
and the r e p r e s e n t a t i v e
Rn,
({~B},
is simply
function
on
connected,
V' ~ R n.
then
=
Ifn(~)iPdgn(~'a)
Un
(a).
n Take any compact equality, SUpzEK
K
included
in some R • By use of H a r n a c k ' s inn C > O, d e p e n d i n g on K, such that we have
we find a c o n s t a n t
v(z)
Applying
set
~ Cv(a)
this
for any p o s i t i v e
fact to the f u n c t i o n s
Ifj(z)l
harmonic u. ]
with
function
v
on
R n.
j ~ n, we have
c 1 / P u j ( a ) 1/p = c1/Pllfjllp,a
~ uj(z) I/p ~
< cI/P(Mj(~BRj,a)
+ i_)
=
]
c 1 / P ( l i m M~(a) + 1) < ~ for every
z @ K.
on any compact of some
such that,
uniformly
on
{fn(k),~"
k = i, 2,
belonging
to
thing
~P(R,~)
to see is that
ifn(k)(Z)I choose
{Ifj(z)l:
of
R n.
+
any
CI(V
).
{fn(k),~:
f
{f~} if(a)i
CI(V a)
Jf(z)J
uniformly is fixed
clearly = i.
lf(~)[
DR
on every
~,a) =< - 7 4
of the
compact
{fn(k):
a section
f
First we note that
subset
Then,
of
R.
for any
Next we
~ > 0
ifn(k)(Z)IPi
< e
[fn(k)(~)[Pdgm(~,a)
DR
con-
subsequenee
the only n o n t r i v i a l
majorant.
for a moment.
m
subset
represents
Here,
exists k 0 with m < n(k 0) such that Jif(z)I p DR for every k > k 0. It follows that m 1 2~
bounded
is a c o m p a c t k = i, 2,...}
be the limit
has a h a r m o n i c
m, w h i c h
is u n i f o r m l y
to find a s u b s e q u e n c e
a,
Let
with
every
process
for each
}; then Jfi p
j = n, n + l , . . . }
Since
Rn, we use a d i a g o n a l
k = i, 2,...} verges
Thus
subset
there on
+ e
m
if
< -7~
I f n ( k ) ( ~ ) J P d g n ( k ) (~'a)
+ s : llfn(k)lipP,a + s
DRn(k) < (Mn(k)(~IRn(k),a)+ As
s
and
n(k)
n--~)P
are a r b i t r a r y ,
+ s < ( M n ( k ) ( a ) + n ~ 7 ) p + e. we have,
by letting
s ÷ 0
and
n(k)
9B
_ I__[ 2~ DR
If([)IPdgm(~,a)
~ lim M (a) p. n÷~ n
m
We n o w m o v e
m
and set
1 I 27 DR
Vm(Z ) _
If(%)IPdgm(%'z) m
on
Rm
with
see that
If(z)l p ~ Vm(Z)
for all sequence is
majorized
If(a)
m : i, 2, . . . .
l :
m.
Thus,
£ Vm+l(Z)
1
and
Theorem
establishes
subregion
process.
values
of
Cl(Rn(~a))
the e q u a t i o n
(8), the d e s i r e d
4C by a l i m i t i n g
from critical
regular
and
Vm(a)
~ lim n M n ( a ) P
the limit
v(z)
R.
Since
Rn+ I.
because
This m e a n s
ular subregion o t h e r hand,
of
gn(a,z)
since
which
cycles
let
CI,...,
are
t h e y are
in
included
independent
valid.
Since
values,
(9) h o l d s
Combining convergence
each
for all
(8),
a > 0
Rn(a,a) on
dis-
is a
CI(Rn) , we
have a natural
map:
Since
Rn
subregion is a r e g -
B (e,a) < B(~,a). On the n = i n c r e a s i n g l y to g ( a , z ) , we h a v e the e q u a t i o n
= lim B (~,a). n n+co
with
k < B(~,a) Since
Rn,(e,a) ~ > 0
be any f i n i t e
R(~,a)
=
U
Bn,(~,a)
an at m o s t
finite
with a countable
set of inde-
co
n=l Rn(~'a)
Rn(e,a) , say
and thus
admits
(9), T h e o r e m s
Then
So (9) is
number
number
these
Rn,(e,a).
> k.
of c r i t i c a l
of e x c e p t i o n s .
IC and 4C, and the L e b e s g u e m o n o t o n e
we f i n a l l y h a v e
: l i m Mn(a)
from
that
in one of the r e g i o n s in
number
each
< gn+l(a,z)
in t u r n i m p l i e s
HI(R(~,a)).
gn(a,z)
theorem,
M(a)
Ck
M(a)
can be d r a w n
is seen to be a r e g u l a r
converge
B(e,a)
1-cycles
Thus
=< B n + l ( e , a ) .
Bn(e,a)
gn(a,z)
that
÷ Hl(Rn+l(e,a)),
Rn(~,a)
that
(9)
In fact,
gn(a,.).
R, we see s i m i l a r l y
~ Rn (~,a), = U n=l
pendent
conclusion
~ R n + l ( ~ , a ) , and t h e r e f o r e
is i n j e c t i v e
R(~,a)
<
of the
(8).
Take any p o s i t i v e
of any
Hl(Rn(~,a))
of
Rm
theorem,
we e a s i l y
EIfll
N o w that we h a v e
which
on
by the H a r n a c k
is s u b h a r m o n i c ,
{v (z)} is h a r m o n i c on R v(a) < lim M (a) p and If(z)l p m ' = n n by v(z) everywhere on R. Hence, we h a v e f E ~P(R,[),
lim n Mn(a) , w h i c h
have
Ifl p
< v(a) 1/p < lim M (a). This implies p,a = = n n S l i m n Mn(a). As ~ is a r b i t r a r y , we c o n c l u d e that
M(~,a)
tinct
Since
: lim e x p [ [ { g n ( a , w ) :
w e Z(a,Rn)}]
99
: lim exp n+~ This establishes The case
,a)d~)
in the case
is entirely
PROOF OF WIDOM'S
THEOREM
Review of Principal 6A.
Since
of
boundary of part
Rj.
Two partitions
say
RI,... , R£.
6(G)
P(G)
{Rj \ CI(G"):
and
Rj e P(G)}
of
R \ CI(G").
each equivalence P
6j(P)
class,
P(G')
nonvoid open sets.
P(G)
consists
denotes
of a fi-
the relative
are called equivalent
containing
CI(G)
{R~ \ CI(G"):
This relation ~,
defines
= {P(G)}
be a partition
has the same number of parts,
in every
P(G)
and
CI(G')
R~ • P(G')}
a partition
if there such that
define
is an equivalence
that
For every fixed
j,
and If
u
P(G) • P,
6(~)
the same
relation and
of the ideal boundary,
= (61(P),...,
is a harmonic
for
6(R).
say
with
£, and,
using the
j = i,...,
£.
6~(P)~ with
6£(P)).
function
defined in some
fSj(p)
*du
R. • P(G) with 3 have the same value for any
*du
denotes
*du = -($u/~y)dx + (~u/~x)dy. u
P(G)
if we arrange parts
we may always assume,
CI(G) ~ G', where
du:
called the flux of
Then each member
R. \ CI(G") = R! \ CI(G") for any 3 3 6j(P) denotes the collection of
then the integrals
P = P(G') • • ferential
of
in some suitable order,
above notation,
P • ~
disjoint
P = P(G)
R.
Let P
we denote by
in what follows.
and G"
in
R
into mutually
exists a regular region
6(R), of
in
R. in R, which is oriented negatively with respect to the 3 The union U.3 6j(P) is the positively oriented boundary of
G, which is denoted by
partition
G
has finitely many components,
nite number of parts,
(c) ~ (a)
Operators
R \ CI(G)
R \ CI(G)
[]
is to prove the implication
Given any regular region
any partition
for the ar-
does not occur here.
(II)
The objective of this section in Widom's theorem.
6.
1 < p < ~.
similar but much easier,
gument concerning harmonic majorants
§3.
B(~,a)d~). 0
the theorem
p = ~
= exp
0
over the cycle
6~(P)
the conjugate
dif-
The common value is
and is denoted by the
J
symbol
f6j(P) *du.
Finally,
P
is called the identity partition
of
6(R)
if each
100
member
P(G)
6B.
Let
set w h o s e lytic
of
P
W
be a n o p e n
boundary
curves.
consists
uous on
a linear
function CI(W),
on
LI : i,
(B2)
f ~ 0
(B3)
Lf = f the
on
F
which
that
number of the
Lf,
is a c o m p a c t
of n o n i n t e r s e c t i n g ideal
operator
assigns
a function
R \ W
boundary
associated
R
in
W
with
with
to e a c h r e a l - v a l u e d
harmonic
ana-
of
and
W
contin-
continuous
the
Lf
over
every
B.(P) ]
vanishes.
following
L W
Lf % 0,
~W,
f l u x of
Let in
such
of a f i n i t e
L
~W
R
By a n o r m a l
implies
(B4)
Theorem.
in
part.
that
(BI)
harmonic
set
B~(P)).
operator
f
such
T h e n we h a v e
of a s i n g l e
We f i x a p a r t i t i o n
B(P) = (BI(P),..., we m e a n
consists
be a n o r m a l
operator
and continuous
on
on
CI(W),
I
*ds
W
and
let
s
be a f u n c t i o n ,
such that
: 0,
~(P0 ) where
P0
denotes
a harmonic
the
function
identity
p
on
R
partition
which
of
B(R).
Then
there
exists
satisfies
p - s = L ( ( p - s)l~W) on
CI(W).
([AS],
The
Ch.
6C.
III,
number
p
normal
In o r d e r
bordered
operators
to c o n s t r u c t
surface
W
of n o n i n t e r s e c t i n g
border
B(W)
parts
~,
Every
Bj
oriented Lemma. function
is n o t
El,...,
closed
each
is o r i e n t e d
u
up to a n a d d i t i v e
continuous
harmonic
in
such operators, border,
we d i v i d e
it i n t o
and
is a u n i o n
with to
function W
6(W), curves.
of w h i c h
respect
kind,
analytic
positively
with
of s p e c i a l
whose
connected,
B%,
negatively For a n y
is u n i q u e
constant.
3A)
We n e e d
operators. compact
function
respect
called
let us f i r s t consists
at l e a s t
W
take
that
the
two n o n v o i d curves.
whereas
e
is
W. f
on
continuous
~
there
on
W
exists
with
the
a unique following
properties: (a)
u = f
(b)
u = c.]
on on
~, 8 j'
c.]
being
a
of a f i n i t e
Supposing
of component to
principal
a constant,
for
j : i,...,
~,
101
(c) The
]6j
*du
function
6D.
u
: 0
set
in
to the R
consists
of a f i n i t e
and
P
let
form
R \ W.
We u s e
regular
For WAG
let
us d e n o t e
n
on
~,
the (n)
on
a constant
and
= B(Gn) N R j .
operators
real-valued Dirichlet
following f
denotes
preceding on
WAG
W.
functions problem
cj,
The
boundary
on
f
on
on
W
~
on
=
shows
such
i
by
L (n)
be a
the n e g a t i v e l y
on the
continuous in
set
func-
WAG n
are w e l l - d e f i n e d
to the p a r t i t i o n
that
W, we the
Z(~,W).
solution
Take
on
C I ( W n Gn)
cj
on
Rj \ CI(Gn) ,
constants that
which each
any
make u
e. such
un
n
~(G
= - I
)
n
S
n
~
for the
The
set of
f.
We
continuous
is h a r m o n i c
n is d e f i n e d on CI(W) \ 8(G ). n n for a d i f f e r e n t i a l ~ on W, we h a v e
n
continuous
H[f~W]
du
n
P.
consider
up to the b o u n d a r y
L(n)f
implies
WnG
n < n'
that
to the w h o l e e
~, are f
"Un":fS For
curves
.-.
operator
for e v e r y
is h a r m o n i c
Clearly,
II~ll~ = [S w ~[*
denotes
harmonic
function
W
containing
GI ~ G2 C
the n o r m a l
let
a representative
region
conditions:
is d e n o t e d
j = I,...,
assumption e.
@
5)
boundary
analytic
has
Let
C G I.
L (n)
set w h o s e
regular
6A.
corresponding
L (n)
Un where
which
Ill,
Namely,
closed
the
lemma
n
to e x t e n d
functions
8(R),
in
by
6B.
Ch.
and CI(WNG ) such that (L(n)f)I~ = f (L(n)f)IB~(G ) n ' n ] B j ( G n ) * d ( L ( n ) f ) = 0 for j : i,..., Z, w h e r e Bj(G n)
The
In o r d e r
such
L
of
CI(G)
each
continuous
normal
with
W.
in
is a c o m p a c t
is a f i x e d
described
of
([AS],
considered
R\ W
G
boundary
satisfying f
R
is p o s i t i v e .
of n o n i n t e r s e c t i n g
partition
the n o t a t i o n
n tion
that
where
of
f
situation
such
P = P(G),
exhaustion
oriented
if
number
be a f i x e d
of the
j : i .... , ~.
is p o s i t i v e
We r e t u r n
be an open
for
n
on
up to the
Writing
n
n
Un*dUn"
we h a v e
WAG
n n
n
G
,\G n
n' n
set
'
102
= I
:
Thus,
lldUnllW
Un'*dUn'
iEdunilW2 -
- I
i[dun ' iSW" 2
are m o n o t o n i c a l l y
decreasing
itdunil~ as
n, n' ÷ ~.
It f o l l o w s
each parametric an L 2 - C a u c h y
disk
V
sequence,
Un*dUn
iIdun,ii~ ÷
that
and t h e r e f o r e 0
This m e a n s
iidun,- dUnll W ÷ 0.
the d e r i v a t i v e s
(resp.
~u /~x n
n, n' ÷ ~.
{~Un/~X}
~u /~x and ~u /$y are h a r m o n i c , we see that n n {~Un/~y} c o n v e r g e a l m o s t u n i f o r m l y on V. As V is
we c o n c l u d e
verges
almost
n, the
sequence
which Since
u
shows that
{Gn} , we can d e f i n e
CI(W).
du E F I determined
an o p e r a t o r
The l i n e a r o p e r a t o r
of b o u n d e d (BI)-(B4)
harmonic
CI(W)
CI(W)
by
f
d(Lf)
all h a r m o n i c
the
CI(W)
@ Fh0(CI(W)) , where
differentials
II~IiW < ~
The o p e r a t o r associated
~
such that
on
Modified 7A.
L
details
§§i and
consists
con-
for all
= f.
say
u,
A simple
du C F < ( C I ( W ) ) . of e x h a u s t i o n s
Lf = u.
space
E(~,W)
and s a t i s f i e s
the class
CI(W)
for any
is c a l l e d
w i t h the p a r t i t i o n
For f u r t h e r
7.
ula
and thus
by s e t t i n g
{du n }
la : f
n to a f u n c t i o n ,
with
into the
space
the c o n d i t i o n s
Let
we r e f e r
the P
Fh0(CI(W))
(harmonic
consists
of
up to the b o u n d a r y
dh C F I ( c I ( W ) ) e
W
III,
u
independently
maps
on
since
uniformly
on
L L
functions
of d i f f e r e n t i a l s
Moreover,
as w e l l as
(DI)
~) w i t h
on
{u } c o n v e r g e s a l m o s t n seen to be h a r m o n i c on
is u n i q u e l y
Theorem.
that the s e q u e n c e
uniformly
is e a s i l y
computation
÷ 0
Since
and
arbitrary,
form
i.e.
I I v { l ~ - ~ ( U n ' - U n ) I 2 + l~-~(un, - U n ) 1 2 d x d y as
that in
~u / ~ y ) n
a (second)
principal
and is d e n o t e d
the r e a d e r
to A h l f o r s
operator
sometimes and
Sario
by
on
W
( ~ ) L I.
[AS],
Ch.
~R'
in
2.
Green R'
Functions be a r e g i o n
of a f i n i t e
number
in
R
such that the b o u n d a r y
of n o n i n t e r s e e t i n g
closed
analytic
curves
R
103
and
CI(R')
the
is n o n e o m p a c t .
complement
of
monic
measure
monic
function
boundary
or,
Let
let
be the
Then,
G
for any
Proof. with
be any
on
constant
C
vanish
oriented
Lemma. U
negatively regular
for any
G' D R , Since
such
that
~,
u E U.
Let
h(z)
the
with the
*dh
> 0.
to
K
show
Choose
(i0)
be
positive
We n o w take vanishes
u > 0
harmonic any
on
and
(ii) on
(i0)
v
6'
and
since on
*du £ c. and
u(z)
there
Hence
u(a)
= 0
set
~'
c > 0
the
and
G DR,
and
*du £ i. a positive
G'
in
R
such
that
8' = B(G') D R ' . for the
and
to
i
along
on
~',
Then, such
We
region 8'
we h a v e
by use
of
that
v(z)
G DR' at
the
in
C' > 0
G' D R ' .
is n o t h i n g
Since
= h(z)
CI(G' D R ' ) .
on
~ G
[e,
region
problem
< cmin zES'
~'
C'
on
in
u = 0
u(a)h(z)
everywhere S~,
< v(a)
If
G DR'
a
har-
by
u E U.
increases
a constant
function
u E U.
identically
everywhere
v(z)
and
0
har-
bounded
exists
a constant
h
positive
DR'
and
there
regular
Dirichlet to
that
e'
<
if
R'.
every
DR')}
of
has
harmonic
on
a region
point
find
such
for
exists
equal
fixed
we can
to
functions,
for any
conjugate
any
R
£ C
of the
data
in
R'
We d e n o t e
respect
CI(G'
such
solution
c -Imax zES'
for any
u
G'
z E
of
hyperbolic
a nonconstant
G DCI(R,),
u(z)
that,
is c a l l e d
DR'
u = 0
of
~ G, t h e r e
harmonic
inequality
that
SUPzEK
the b o u n d a r y
local
Harnack's
region
such
subset
on
with
of p o s i t i v e
~ G' ~ CI(G')
by
carries
collection
compact
R'
boundary
R'
identically
max{u(z):
denote
ideal
CI(G D R , ) ,
It is e n o u g h DR'
in the
a region
equivalently,
which
DR'
continuous
DR'
Such
some
point
in
to prove.
second
half
G DR',
then
So we a s s u m e
of
(i0)
implies
< cu(z) on
e',
It f o l l o w s
that
~ c / ( S ~ , *dh).
we
see that
(ii)
0 ~ u(a)fe,
Next
we use
holds
*dh ~ c x
the
first
half
of
get
max
By the m a x i m u m by the c o n s t a n t
u(z)
~ c u(a)
principle
u(z)
c2/(~,.
*dh),
~ c2[i[
is m a j o r i z e d as was
*dhj~ -I
everywhere
to be proved.
[]
on
CI(G' D R')
104 7B.
We use
Lemma.
(a)
that
]a' (b)
monic (cf.
the n o t a t i o n s
There
*du
> 0.
If
R'
is a p o s i t i v e
v
and
and
then
on
function
there
CI(R')
exist
such
u
on
bounded
that
dv,
CI(R')
such
positive
har-
dv'
E Fh0(CI(R'))
and
S Proof.
v'
above.
harmonic
is h y p e r b o l i c ,
functions 6D)
given
Let
*dv
a T
GI ~ G 2 ~
and
> 0
.-.
S
*dv'
a T
be a r e g u l a r
< 0.
exhaustion
of
R
with
DR' $ G I
set
8' = B(G ) A R , for each n. Let v be the s o l u t i o n of the n n n p r o b l e m for R' N G w i t h the b o u n d a r y data equal to 0 on n a' and to i on 8'. Then v is h a r m o n i c on CI(R' N G ) and the n n n S e, *dv n , is p o s i t i v e . We set un = flux dn of vn over ~', i.e.
Dirichlet
v /d . T h e n n n is e q u a l to
u i.
n : i,
2,...}
By the
diagonal
convergent
fact
vanishes
the p r e c e d i n g
process
almost
When
v' ~ i
Thus
is u n i f o r m l y
the a s s e r t i o n
nonzero,
is p o s i t i v e ,
n
lemma
bounded
we can
uniformly
on
a'
and
shows
on any
that
compact
CI(R').
Its
flux
the
of
{Un(k):
limit
u
over
a'
sequence
subset
find a s u b s e q u e n c e
on
its
{Un:
CI(R').
k = i,
clearly
2,...}
satisfies
(a).
R'
is h y p e r b o l i c ,
~ i
and
and
]a'
Sa , *dv
*dv'
the
limit
> 0.
< 0.
The
v
of
Setting final
v'
{Vn:
n = i,
: i - v, we
assertion
follows
: lim n÷~
*dv
2,...}
see that now
from
is 0
the
that
[[dv[]°K~'
= lim n÷~
[
:
]]dv n[]~<2AG *dv
<
n
~.
~[ ] e,
n
[]
J~v 7C.
Returning
Theorem.
Let
partition
associated
The
G
negatively
given
any r e a l
there
exists
(12)
for e v e r y
to the n o t a t i o n s
be a r e g u l a r with
G, w h o s e
boundary
numbers
a., ]
I
j.
region
oriented
a nonnegative
Moreover,
in in
Rj
j = i,...,
Bj(P) the
*du
R
parts
of
harmonic
6A, we get and
functions
let
~, w i t h
(mod
u
u
following P = P(G)
are d e n o t e d is d e n o t e d
function
~ a.
the
by
be any
RI,... , R~.
by
B~(P). Then, J ~j~ a. ~ 0 (mod 2~), i ] on R such that
2~)
for all p o s s i b l e
choices
of
105
{a.} J every
can be found fixed
Proof.
a C R
If ~ > i.
tains
a hyperbolic
Lemma
7B t h e r e
that
f61(p)
fine uI
Since
Then,
uj•
the
is h y p e r b o l i c ,
{u(a)}
set of v a l u e s
For on
the c o n d i t i o n .
one
We a s s u m e
CI(R.) ~
of the RI
harmonic
each
to be
for
function
such
f Bj (p)
*ds~~ = 0, we can a p p l y
on
L
*du. ~
conBy
= i.
by
such
a positive We de-
setting with
6B to the
j = 2,
s.
=
i ~ i, j.
open
corresponding
p~,
suppose
CI(R I)
exists
CI(R.)
Theorem
s. and the o p e r a t o r J exist harmonic functions
on
there
~ = 2,..., : 0
function
So t h e r e
uI
~
that
So we
R.'s at least J such a part.
j = 2,..•,
s. on R\ G for each J : u• on CI(R.) and
fB(G)
the
R \ CI(G).
R
is a n o n n e g a t i v e
CI(RI) , since
that
satisfies
component•
function
R \ CI(G),
u ~ 0
*du I = -I.
a function on
a way
is b o u n d e d .
~ = i, t h e n
that
harmonic
in such
set
to
3,...,
W = ~, on
J
R
such
that pj - sj = L((pj - sj)l~G)
on
R \ G.
Since
L((p~J - sj)I~G)
and
(B2)
in
are
seen
to be b o u n d e d
6B and
if n e c e s s a r y , tion
on
s.
since
we m a y and
the
;
sj
are
below
assume
on that
property
*dPk
k : 2,..., Finally
(mod
2~),
clearly
and
they
(B4)
Then
there
tions:
in v i e w
the
on
R.
pj
a constant
Our a s s u m p -
the
following:
-i
if
j = i
i
if
j = k
0
if
j ~ i, k
=
(BI)
functions
by a d d i n g
positive
of
Bj(P)
(12).
Moreover,
0 < b-
=
for any
bkPk(a)
~ 2~ ~ k=2
k=2
Theorem.
there,
in 6B i m p l y
*dSk
R \ G
~.
u(a)
7D.
are
b• be r e a l n u m b e r s w i t h ] u set u : [k[2 bkPk" Then
and
on
therefore,
let
satisfies
as desired.
bounded
nonnegative R
: I
6j(P)
for
are
< 2~
and
b.
~ a.
R
and
is n o n n e g a t i v e
on
a E R
the b o u n d
we h a v e
Pk(a),
[]
Here
we w i l l
construct
Let
g(-,~)
be the
exists
a function
modified
Green
Green
function
g0(.,~)
functions.
for
satisfying
R the
with
pole
following
~ E R. condi-
106
(a)
g0(-,~) - g(.,~)
is a p o s i t i v e
d(g0(.,~) - g(.,~)) e Fh0(R) ; (b) f $ j ( p ) *dg0(.,6) E 0 is a given (e)
partition g0(z,~)
Let
G
P = P(G)
are h y p e r b o l i c
hyperbolic,
we have
tive h a r m o n i c i,...,
Z',
2,...,
6'.
such that
have only viously
~.
to set
while
and
~
such that
~
CI(Rj)_
*du I : -i
% @ G
contains
fBj(P)
*duj
= - I
holds:
(i)
a.
: g(-,6)
and the c o n d i t i o n s
sj,
j = 2,...,
and
: O
on
]
just
stated.
~', by s e t t i n g CI(R i)
~j(P)
with
]
s. : u. ] ] i ~ i, j.
on
j : i,
F h 0 ( R \ G).
Moreover,
for every
adding
us h a r m o n i c
up to the b o u n d a r y is b o u n d e d
each
j = 2,...,
3j
~',
a suitable
and
is b o u n d e d
constant
In v i e w of the p r o p e r t y
of and
*dpj
that
k = 1
.:{1 if k:j
Bk(P) 0
6D
belongs
dpj E Fh0(R).
*ds]
: I
on
dsj E Fh0(R k G).
and
if
pj
R \ G.
pj
otherwise.
We
are pos-
in 6B of the o p e r a t o r
,-i
Bk(P)
on
R \ G, T h e o r e m
if n e c e s s a r y , (B4)
functions
see that
(i4)
~' > i.
CI(R.), ]
d(L((pj - s j ) l ~ G ) )
is b o u n d e d
pj
are ob-
BI(P)
pj - sj = L((pj - sj)l~G)
~'
s. is h a r m o n i c ] L((pj - s j ) I S G )
R.
j =
Then
such that
itive on
for
(a)-(c)
j : 2,...,
may assume,
j =
for
So assume
R
Thus,
: i
> 0
6B gives
to
posi-
bounded
*dg(.,~)
Bj(P)
of T h e o r e m
that
is
and set
an a p p l i c a t i o n
shows
RI, R
duj e F h 0 ( C I ( R j ) ) ,
so that
each
a parti-
that
Since
?B we take
with and
Then the f o l l o w i n g
B(G)
for
in any c o m p a c t
suppose
are not.
By use of Lemma
in v i e w of the facts
CI(R I)
Since
with
~, where
lying
We may
R6,+I,... , R 6
on
fBl(p)
g0(-,~)
satisfied
on
R
j = ~' + i,..., ~; and (iii) a3. = 0 for i a.] = 27. for a moment, we p r o c e e d further. If ~' = !, then we
Then we define = uI
fixed
region
a. = a.(~) ] 3
..., ~',• (ii) A s s u m i n g these
z
j = i,...,
on
B(R);
= {RI,... , R6}.
uj
We take any
j = i,...,
boundary
for
6' ~ i.
functions
(13) for
for
function
z.
be any r e g u l a r
tion of the form ..., R6,
(mod 27)
ideal
is b o u n d e d
set not c o n t a i n i n g Proof.
of the
harmonic
L, we
107
For
j : Z' + I,...,
~
We now define
go
(15)
we set
pj ~ 0
on
R.
by the formula
g0(.,~)
=
[ aj(~)pj j=2
+ g(-,<).
The property (a) is then clear. The property (b) also holds, simple computation using (13) and (14) shows that -2~ IBk(p) When
~
lies in
fore, in view bounded on R Take a regular denote by C n
*dg0(''~)
G, the same
= { 0
pj,
if
k = i
if
k > i.
j = 2,...,
for a
~, can be used and there-
of the properties (i)-(iii) of aj, g0(-,<)- g(-,{) is by the same constant C not larger than 2~2 llpjtl . exhaustion G I ~ G 2 ~ .-. of R with CI(G) ~ G I and the constant C corresponding to G n. Then the property
(c) is satisfied
if
to have g0(-,~) Finally, we with i £ j ~ Z 6j(P). Then fj
- g(.,~) ~ C n. have to prove the properties (i)-(iii). Take any j and let f. be the restriction of g(',~) to the set J > 0 and, by Theorem 6A, Ch. I, g(-,%) : H[fj~Rj] on
CI(Rj).
g0(.,%)
is constructed
Take again a regular
exhaustion
for
< E G n \ Gn_ I
G I ~ G 2 C ...
of
R
so as
with
CI(G) =C GI, and define Gnj = GnAR.3 and Bj(Gn ) : 6(Gn) AR.,3 so that SGnj = 8j(G n) - 8j(P). Further, let gn (resp. $n ) be the solution of the Diriehlet problem for the open set Gnj with the boundary data equal to fj (resp. i) on Bj(P) and to 0 on Bj(Gn). Then gn and its derivatives converge almost uniformly on CI(R.) to g(-,{) and its corresponding
derivatives,
respectively.
Thus
I Bg(P) ~'~dgn: I Bj(P) Cn*dgn - I Bj(G n) Cn*dgn
ffG
ffG
n]
nj
IBj P)
gn*d@n - I
=f Bj(p ) fJ *d~n Letting
n ÷ ~, we see that
Bj(G n )
gn*d~n
108
(16)
I
*dg(.,~)
= I
Bj(P) : H[I;Rj].
where Bj(P). R. 3
Moreover,
f.*d~, ]
6j(P)
Since
0 ~ ~ ~ i, we see that
*d~ < 0
on some c o m p o n e n t
Since
f. > 0, it f o l l o w s ]
is h y p e r b o l i c .
I
of
*d~ ~ 0 8j(P)
from
along
if and o n l y
if
(16) that
< 0
*dg(.,{) Bj(P)
if and o n l y if follows
at once
in T h e o r e m
7E. Lemma.
R. is h y p e r b o l i c . This p r o v e s (i) and (ii). (iii) 3 f r o m the l o c a l e x p r e s s i o n of the G r e e n f u n c t i o n g i v e n
6A, Ch.
We n e e d Let
I.
some f u r t h e r
{V, z}
and its p a r a m e t r i c V
such t h a t
to
~0'
coordinate, I~I
of
{Izl
g.
disk,
< r I}.
in w h i c h we i n d e n t i f y
~0 , %0'
and let
< r I < r 2 < I.
the d i s k
with
property
be a p a r a m e t r i c
I~ol,
within
tersecting
[]
Let
Then
Proof.
*d(g(.,~)
- g ( . , % 0 )) =
differential
We use the n o t a t i o n
arg{(z-
joining ¥
in ~0
not in-
f ]
~ 2 ~
o(y), c
is a r e a l
single-valued
points
be an are
for any 1 - c y c l e
y
o(y)
be d i s t i n c t
c
c
I where
a point
branch
in Ch.
in
Fh0
I, 9.
of the f u n c t i o n
given
Let
in T h e o r e m
v(z)
9C, Ch.
(resp.
s(z))
~)}
(resp.
log{(z - %0)/(z-
I.
be a
~0)/(z- ~)}) in the a n n u l u s r I S Izl < i a n d let e(z) be 2 C - f u n c t i o n on R such that e ~ I on {Izl < r I} and
a real-valued 0
on
R \ {Izl
{Izl £ i}
and
< r2}.
k(z)
We also
= g(z,~)
of the G r e e n
Izl < i, w h e r e
is a h a r m o n i c
*dk = d { a r g ( z for
Izl < i, w h e r e We f i r s t
(17)
h2
function
= logl(z-
Then
~0 ) - a r g ( z -
is a h a r m o n i c
on
d{(l - e)k} • Fe0(R).
follows
function.
{0)/(z- ~)I
that
k = w+ h I
for
Thus, ~)}
+ dh 2
conjugate
of
hI
in
{Iz
< i}.
see that d ( k - ew)
: d{(l - e)k} + d { e ( k - w)} :
and so
w(z)
- g(z,~0).
F r o m the d e f i n i t i o n hI
set
* d ( k - ew) @ FeO ~{.
d{(l - e)k} + d ( e h I) E Feo(R) On the o t h e r hand,
dk + i * d k - d(ev)
E F e.
109
In fact,
on
V
we h a v e dk + i * d k -
which
is closed.
Next,
d(ev) on
: d{(l-
R \ {Izl
dk + i * d k which
is a n a l y t i c Let
a real
y
and
d(ev)
contained
differential
for any c l o s e d
S r 2}
we h a v e
= dk + i*dk,
so is closed.
be a 1 - c y c l e
harmonic
e)v] + d(h I + ih2) ,
in
o = o(y)
differential
~ E F
R \ {Izl E Fh0
< rl].
such
(Theorem
9B,
Then
that Ch.
there
is
fy ~ = (m,o*)
I).
Since
dk-
C
d(ev)
is exact
f
*dk
on
R \ {Iz[
= -i f
¥
< rl},
dk+ i*dk-
we have
d(ev)
= -i(dk+ = A,
Now,
from
(17)
follows d(k-
This
i*dk-
differential
say.
that ew) + i * d ( k -
is e q u a l
d k - d(ew) + i ( * d k -
ew) @ Fe0 + F e0 * "
to
e*dw-
w *de)
: d k - d(ew) + i ( * d k = dk + i * d k -
Since
Fho" ±
(Fe0 + Fe0*)
by
(4)
in Ch.
( d ( k - ew) + i * d ( k and
d(ev),o*)
y
I,
eds - w ' d e )
d(ev) + i(sde - w ' d e ) .
8E, we h a v e
ew),o*)
= 0
thus A : -i(i(w*de
- sde, o*)
: ( w ' d e - sde, o*)
rl< I z l< r 2 sded wde°*
d(ew)(]*
+ ffrl < zl
- ff
edw(~* rl< ]z
rl
rl<]Zl
110
:_f
w~o_ff I z I:r I
To c o m p u t e
edwo~-f I~ I
rl<
this,
we add p u r e l y
s~-ff
I z I: imaginary
rI
terms
rl<
eds~. I~ I
as follows:
_if z I=r I s~ iffrl< Iz I
is this:
-flzlvoo_ ff :r I
rl<
=
i
Ii z
:
i
Ii z
I z l
e~v~ + if
v ( a + ia*)
a
+ i IIrl
vda --r 1
f~;
da
z
= -2~r
~0
where
%0
f
z
(a+icr*),
e
is an a n a l y t i c
function
I
on
V
with
*dk = -2~ I y
7F.
Concerning
Theorem.
Under
fY where %0
and
Proof.
the f u n c t i o n
We set
pj
the f o r m u l a
(13).
Thus
with
[ j=2
we have
fc
k 0 = go (. , {0' ) - g 0 ( - , ~
are h a r m o n i c
Hence,
[]
as in Lemma
dependent
k0 = k + where
go
the same c o n d i t i o n
is a c o n s t a n t
o.
da = a + io*.
c
*d(g0(.,~)-g0(.,%0))=-2~
K. 3,Y {~.
rl< I z I < r 2 edv(a + ia ~':)
--r 1
I z l=r I
= -2~r
edvo
z I =r 1
of
7E, we have
{o(y) - j:2 [ K.],yO(Bj(P))}, j
0)"
and
y
Then by
but not of points
(15) we have
(aj(~') - aj(~0))Pj 0
dpj e Flhe(R)
by Lemma
the f o l l o w i n g
7E
and
a.(%)'s]
are g i v e n
by
111
aj(~6)-aj(~0 ) = - I
*dk : 2z I 8j(P)
It follows
that,
f
for any cycle
f
*dk 0 : y
y
*dk +
=-2~
in
[ j=2
y
R \ {Izl
< rl},
(aj(~6) - aj(~0))
{(~(y)c
8.
o(Bj(P)). e
~
(
f
*dpj y
*dpj)~(gj(P))}.
j=2
[]
y
Proof of Sufficiency 8A.
We are now in a position to prove the implication
in Theorem
2B.
We do this by contradiction.
is a hyperbol~e
Riemann
for some
Namely we suppose that
surface but not a PWS and therefore I~ B(~,a)d~
(and hence all)
(c) ~ (a) R
that
:
a E R.
We set m(~,a)
= sup{If(a)I:
for any line bundle
~ m(a)
In view of Theorem show that
m($,a)
over
R
llflll,a ~ i}
and then
= inf{m(~,a):
5A we have : 0
f e ~(R,~),
m(a)
~ e HI(R;~)}.
= exp(-f~ B(~,a)de)
for some line bundle
$.
: 0.
We should
For this end we still
have to prove two more facts. 8B. R£}
Let
GO
be a canonical
the set of all connected
j ~ £, the boundary respect to ~£-i
GO.
Let
CI(V) ~ G O ..., b N
V
in
R
of
R \ C I ( G 0 ) , and
contour of
basis
cycles
be any parametric
and all
Yn'S
N' I k=l
for
YI'''''
~i'''''
V.
Then,
~N'
~dg0(-,~ k) ~ b n Yn
CI(G 0)
{RI,..., ~j,
i
in
consists
of
~I'''''
~N"
disk included in
lie off
there exist points
(Ch. I, IC),
Rj, which is oriented positively with
Then a homology
and certain nondividing
Lemma.
region
components
GO
such that
for any real numbers V
such that
(mod 2~)
b I,
112
for
n = i,...,
Proof.
Let
N, a n d
Tj
R
N.
~0
number
be the
center
= o(6j(P)),
representing
write
The
Yn
of
V
a n = UndX + vndY
6j(P), and
~n IN Cn nU + ~j_£_2 c'u'3J : 0
~
e
on
V.
This
j = 2, . . . , £, are
+
u
~
n n
means
is
constant on
are
linearly
was
to
be
the
c:u'
V,
harmonic
] J
in
~0
n I
bn.
n = i, ... ,
V.
on
P = P(G0).
We
Then,
n =
Un,
independent
on
V.
In
then
c
3-{
numbers
differentials
where
:
j:2
of the
a n = a(Yn) ,
linearly
on
~0
n i
Z
eTj
a
+
n n
~
e."~
j:2
3 j
that
ca
tically
let
T3. = uj'dx + vj'dy
fact,
n:l
and
£, be
and
o :
independent
respectively,
i,... , N, if
is
j = 2,..., and
uj, '
N'
on
V
R.
Since
and
independent,
shown.
It
Tj
with
n = i,...,
we h a v e
follows
j=2
In N 1 e n a n + ~j_£ -2 c'T. J 3
therefore an,
+
n n
c
N
= c[ = 0 3
n
and
vanishes
iden-
j = 2,...,
for
all
n
V.
So we
and
£
j, as
that
#
~-
u n : u n - j[ K. u' :2 3 'Yn 3 for
n = i,...,
induction,
N
are
linearly
independent
%1' .... ' ~N' C V
points
such .
on
.
We
set
defined IXnl Since
the
eontains
for
n = i .....
Jacobian an
open
includes
an N - c u b e
have,
Theorem
by
of set
consider
~
0
N}
with
at
0
in
19N.
with
sides
the
al'''''
of
in
19N
mapping
k 1 ~
given
by
a
)
U = {(Xl,...,XN)"
r = min{l-]~'I: n = i , . . . , N}. n ¢(U) is e q u a l to A ( 6 { , . . ., ~N') ¢ 0,
For of
a large
length
7F,
), ....
k=l~y I
and
= (k:iJ~
in a n e i g h b o r h o o d
< r
0.
K. T. 3 'Yn 3
~(Xl'''''XN)
by
°
,...,~)--
a# an [ _£ n = - j-2
find,
.
•
A(~{
can
that
Nf
k i 7N
integer
27.
On the
M > 0, other
(2~M)~(U) hand,
we
113
M(
:
*dg0(-,~ ~) ..... k=l Y1
In view of the d e f i n i t i o n
of
with
sides
when
any
(bl,...,b N) E ]RN
of length
2~
M ~ k=l for
n = i,...,
there
If M
f • ~{~(R,~)
Then
in Ch.
Since
[F0(G0)] and
Hence,
for
such that
~n'
to
V
+x
n
'
n
i,...
=
and
~
e of
YI'''''
as in the p r e c e d i n g ,
there
over
II,
(mod 27) n
exists
GO
satisfying
e, of the f u n d a m e n t a l
"''' e~-i
there
2B, the bundle F0(G 0)
is i d e n t i c a l l y [0(G0), YN'
a constant exist
ILflL ~ I
group 0
and ~ to
elements
such
an e x t e n s i o n If(a)l
initial i
is d e t e r m i n e d
for these
m > 0
is given
with
equal
we have
~
to
~ m. by a character,
point
0, where
on the c o m m u t a t o r by its values
generate
at
~i'
the h o m o l o g y
HI(G0,%) = F 0 ( G 0 ) / [ F 0 ( [ 0 ) ] . Here, the paths from 0 by p e r f o r m i n g obvious d e f o r m a t i o n s .
exp(-2~iaj)
for
..., N, where the region there
a E GO.
for any line b u n d l e
subgroup
belongs
~k ) - b
same n o t a t i o n s
As n o t e d
an N-cube
U.
(mod 27)
are the points
'
the
t 0 = CI(G0).
group issue
*dg0(" Yn
8C.
Proof.
over
(Xl,...,x N) • U
- bn
~k ! s
[]
and an
say
~MN
then
N.
Suppose
a point
x k)
n = i,...,
Theorem. R
exists
side covers
ranges
r
I
that
(Xl,...,x N)
~i'''''
times,
k=l
Using
- 2~M%(Xl,...,XN).
M, the r i g h t - h a n d
*dg0(.,~+
MN
for
[ *dg0(-,~)) k:l YN
Yn
N.
N, each r e p e a t e d
Nf
j = i,...,
aj
and
bn
GO, we should
exists
~
and
0(yn)
are s u p p o s e d to We set 8(e.) = ] : e x p ( - 2 w i b n ) z for n = i,
are real numbers. have
[j=l a. - 0 ] harmonic function
a nonnegative I
*du ~
(mod
a.
Since (mod u
[j=l ~j
2w). on
bounds
By T h e o r e m
R
7C
such that
2~)
] for every
j, where
u(a)
aj.
Next we use Lemma
~MN
from a fixed
k=l
compact
Yn
~ C < ~,
C
8B to choose set
being
a finite
K
lying
*dg0(.,~ k)
~ bn -
in
f
Yn
a constant number G O \ {a}
*du
independent
of points
(mod
such that
27)
of
~i'''''
114
for
n = i,...,
where
~
N.
denotes
is h o l o m o r p h i c
We set
v = u+ [~i
the h a r m o n i c
on
R.
g0(''~k )
conjugate
of
and
v.
Since the d e f i n i t i o n
f = exp(-v-
We see first
of
go
(Theorem
i~),
that
f
7D) shows
that
I for any
*dg0(.,%)
and any
6 • GO
-
~ O
(mod 2~)
] j
= 1,...,
rI J
*dv
~,
~
we
see
that
(mod 2~).
-a.
]
We also h a v e MN -
*dv
:
-
*du
Yn Thus, ~
f
-
[
Yn
is a s e c t i o n
of
~
,~k )
-b n
-
Yn
of a line b u n d l e
is the r e s t r i c t i o n
If(a)l
*dg0(-
k=l
to
GO .
= exp(-v(a) -
~
over
R, so t h a t the b u n d l e
Moreover,
MN ~ g0(a,~k)) k=l
> m > 0,
where m : e x p ( - C - MN sup g 0 ( a , ~ ) ) %EK is i n d e p e n d e n t
8D.
of the c h o i c e
of
~.
[]
For each line b u n d l e
T
striction
of
GO .
Theorem.
Suppose
T
to the r e g i o n m(a)
= 0.
over
R
we d e n o t e
by
p0(~)
the re-
Then
Then,
for any line b u n d l e
T0
over
[0'
we h a v e inf{m(~,a): Proof.
Since
bundle
T'
the p r e c e d i n g a section where
m
m(a)
over
= 0, we see that
R
with
''-I)
is a c o n s t a n t
belongs
l(f0h)(a)l
m(T',a)
: T0}
for any
< ~.
to
~(R,T~
~ m(~',a)
such that
independent If
of
< E.
Since
e > 0
say
llf011~ ~ i ~.
h • ~(R,6)
''-I) : ~ / ( R , < ' )
= 0.
We set
t h e o r e m we f i n d an e x t e n s i o n ,
f0 e ~ ( R , ~
P0 (T) = P0 ( T )'P 0 (6'') = ~0" foh
p0(~)
and
Set with
there
exists
a line
T~ : P 0 ( T ' ) - I T 0 • T", of and
T~
to
R
By and
If0(a) I ~ m > 0,
~ = ~'T".
Then,
llhl11,a =< i, t h e n
llf0hlll,a =< I , so that
If0(a) I £ m, we have
lh(a)l ~ m-ls,
115
which means that sired result. 8E. that
~ m-it.
= 0
for some
s
is arbitrary,
open subset
V
(and hence all) of
We then choose a regular nonical regions
(Ch.
(resp.
Pjk
with
bundles
over
R
R
a @ R.
and a countable
2B, we suppose
We take a relatively
dense
subset
S
of
V.
exhaustion
j ~ k) the restriction Gk).
~n
over
We fix a line bundle
~j
mn = inf{mn(~n'b):
to
Gn
(resp.
Gj) of line
Finally we set
: sup{If(a)l:
for any line bundle
n ~ j
we get the de-
{G : n = i, 2,...} of R by can I, IC) such that CI(V) ~ G I. We denote by On
(resp.
mn(~n,a)
for
As
To finish the proof of (c) ~ (a) in Theorem
m(a)
compact
m(6,a)
[]
f • ~ ( G n , ~n ), llflll,a =< i]
Gn
and any
over
Gj
a • G n-
and take any
~n e HI(Gn;~),
b E Gj.
We set
Pjn(~n ) : ~j}
and = inf{m(~,b):
~ • HI(R;T),
pj(~)
= ~j}.
We claim (18)
lim m
n
: m.
This can be shown in the same way as in the proof of (8) (see 5A). fact,
if
belongs
~n+l E HI(Gn+I;T) to
HI(G
;~)
with
Pj,n+l(~n+l ) = ~j, then
In
Pn,n+l(~n+l )
and therefore
n
mn(Pn,n+l(~n+l)'b)
~ mn+l(~n+l'b)
~ mn+l"
Since every line bundle over see that
~ mn+ 1 ~ m
G. is the restriction ] and hence limn÷~ {n =
In order to show the reverse We take
~ E HI(R;T)
before that
<
in the form
({ ~ }
V' n G n
with
pj(~)
inequality, = 6j
and
we may assume that m(~,b)
is defined by means of a countable , {V~})
such that all
are simply connected.
that there exists an
V'
The definition
fn E ~ ( G n , P n ( ~ ) )
of one over
< ~.
R, we m < ~.
We assume as
open covering
{V~}
as well as all nonempty of
mn(Pn(~),b)
with the properties
shows llfnlIl,b
i f
and Ifn(b) I ~ m n ( P n ( ~ ) , b ) - i/n. Let {fn } be a representative of with respect to the covering {V' A G } of G and the representn a n~ n ative ({~eB}, {V~ n G n } ) of pn(~). Let {V } be a refinement of the covering
{V'}
such that
CI(V
)
is a compact
subset of
V'
for
116
every
~.
Since
IffnIll,b ~ I, t h e r e e x i s t s on
Gn
on the set
CI(V
n > i =
subsequence f o r m l y on formly
)
by a c o n s t a n t
are u n i f o r m l y {nk: V
on each
V .
{f }
Since
defines
Ill ~ h,
Finally,
~
C
independent
on
V
such that
{fnk
and such that
= lim f k÷~ nke a section
and
n. ~.
}k
{hnk} k
Thus,
f n~
So t h e r e
is a
is c o n v e r g e n t is c o n v e r g e n t
uni-
uni-
h : lim h k÷~ nk
of the b u n d l e
f • ~(R,~)
and
~, w h i c h we d e n o t e
llflil,b ~ h(b)
: k÷~lim Ifnk(b)l
by
= l i m k + ~ hnk(b)
f.
~ i.
=> limk÷~sup{mnk (pnk ~),a) - nk -I}
> lim sup m =
~
of
for each
we have
If(b)l
As
hn,
We set f
Then
bounded
k = i, 2,...}
for e a c h
function,
h n (b) =< i. Take any ~. If Gn i n e q u a l i t y shows that hn is b o u n d e d
on G n with Ifnl ~ hn includes CI(V ), then the H a r n a c k with
a harmonic
and
is a r b i t r a r y , By T h e o r e m
we have
8D we h a v e
k÷~
= lim m nk
n+~
. n
m > lim m and t h e r e f o r e (18) holds. = n+~ n b C m = 0 for any ~j e H I (Gj ;~) and any
Gj, and thus (19)
lim[inf{mn({n'b):
~n • H I ( G n ;T)'
P j n ( ~ n ) = ~}]j
= 0.
n+~
Let us take a s e q u e n c e appears
infinitely
n I < n 2 < • .. that
{bj:
often.
j = i, 2,...}
By use of
and line b u n d l e s
in w h i c h
each p o i n t
in
S
(19) we find a s e q u e n c e
over
{n.} 3 i = i, 2,...
for
Gn. l
with such
-i Pni'ni+l Then there
exists
(~ni+l)
a unique
= ~n. l
and
m
line b u n d l e
~
ni
(~n
l
,bi) < i
over
R
satisfying
pn (~) = i
~n.
for all
i, so t h a t we have
m(~,bi)
i
any
i
b E S.
T h e n our a s s u m p t i o n
for i n f i n i t e l y that e v e r y f ~ 0
~ mno(~n
on
many
i.
f E ~(R,~) R.
So
m(~,b)
vanishes
H e n c e we h a v e
on
{bj} = 0
e i -I.
Take
l
says t h a t we h a v e for all
at all p o i n t s
~I(R,~)
~bi)
b E S. in
S
b l.
= b
This m e a n s
and t h e r e f o r e
= {0}, as was to be proved•
[]
117
9.
A Few D i r e c t 9A.
Consequences
First
Theorem.
Let
we r e s t a t e R
be any
Theorem
PWS.
5A as
Then,
inf[sup{If(a)I:
follows:
for e v e r y
f e ~P(R,~),
S
= exp(-
B(~,a)d~)
p
with
IIfll p,a
= i}]
i ~ p ~ ~,
> 0,
0
where the
~
ranges
common
over
value
all
line
is e q u a l
The
last
statement
for any
Corollary. common
point
If
zeros
R
line
Theorem.
Let
(a)
For each
pair
with
(b)
For
a simple
zero
Proof.
comes
is a PWS,
9B.
f e H~(R)
{g(a,w):
f(a)
every at
from
Theorem
R
tion.
Take
because of
let
then
the
bundle
an
R
surface
R.
statement
h(z)exp[-g(a,z) H~(R).
Since
this
the in
theorem
is
following
~(R,~)
have
no
Then
points
the
following
a, b E R
hold:
there
exists
an
a E R
there
exists
an
f E H~(R)
which
has
bounded
be the
line
bundle
-I)
such
- i~(a,z)]
is e a s i l y
and
seen,
the p r o p e r t y :
over
R
extend
choose
by this
This
function,
and
f(b)
-I)
with
~ 0.
func-
is p o s s i b l e
a function
it a n a l y t i c a l l y
resulting = 0
determined
lh(b) l ~ 0.
We t h e n
the
f(a)
function
ig(a,z))
that
Corollary.
analytic
element
to the w h o l e say
f, b e l o n g s
This
proves
~ 0.
Then,
the
(a).
To p r o v e
in
then
~ f(b).
point
h E ~(R,~
As
and has
IC.
functions
be a PWS.
of d i s t i n c t
preceding
h(z)exp[-g(a,z)
H~(R)
is r e g u l a r ,
~ E HI(R;~).
the m u l t i p l i c a t i v e
~
of the
R
a.
Consider
and
If
in p a r t i c u l a r
z ~ exp[-g(a,z)on
R.
w e Z(a;R)}].
a ~ R, we h a v e
for any
over
to
exp[-[
valid
bundles
(b),
we
choose
- ig(a,z)]
Since
h(a)
h E ~(R,~
gives
~ 0,
f
rise has
h(a)
to a s i n g l e - v a l u e d a simple
zero
at the
function point
f a.
[]
118
NOTES For the fundamental brilliant
Parreau's
[70],
Most
two
in 1976, paper
although
Subsection
definitions
except
some
those
was
was
chapter
shown
out
coined
in S u b s e c t i o n s
from Hasumi
are
have
[18].
contains
taken
[52].
when
from
[18].
[18]
[19].
his
this
Essential
was
As a written.
to me the r e l e v a n c e
with my work
then
which
by H a s u m i
results
pointed
small m o d i f i c a t i o n s
3 are a d a p t e d
[70],
is in P a r r e a u
Parreau's
in c o n n e c t i o n type"
Widom
in this
definition
Z. K u r a m o e h i
[52]
results
follow
results
I did not k n o w
of P a r r e a u - W i d o m All
of PWS we
Parreau's
of t h e s e
of fact,
Afterwards,
faces
theorem.
paper.
equivalence matter
definition
The n a m e
of "sur-
by M. H a y a s h i . 3 and
6 are due
b e e n made.
to W i d o m
The r e s u l t s
in
CHAPTER
Every bounded almost means
harmonic
of the
Poisson
function
integral.
has a striking type.
discovered
Parreau
by M.
paper of Parreau time.
of Parreau the case
that
problem asking
of surfaces
positive
harmonic
issuing of Green
between
show that
harmo n i c
faces
i.
limits
V), results
Green
Green
in
sections
boundary. lines
on
are devoted
We show in 52 that
every
almost
line
every Green problem
data m e a s u r a b l e
on the
lines)
of functions
space
problem
and the fine
including
to
with re-
in §3 the B r e l o t - C h o q u e t
(along
for a class
objective type,
Definition Let
of Green R
g(a,z).
= r(a;z)
PROBLEM
and
8(z)
hyperbolic
is to i n v e s t i g a t e
3B, Ch.
limits
bounded
Green
assumption
Riemann
sur-
lines
on sur-
is e v i d e n t l y
V.
ON THE SPACE
OF GREEN
LINES
Lines
be a r e g u l a r Let
only r e g u l a r
this r e g u l a r i t y
in view of T h e o r e m
THE D I R I C H L E T
function
for any bounded We solve
for the
answer,
and the M a r t i n
and that the D i r i e h l e t
we c o n s i d e r
of P a r r e a u - W i d o m
IA.
r(z)
chapter
As our u l t i m a t e
legitimate
§i.
along
in that
appeared
functions.
In this faces.
same
type.
were
Brelot-Choquet
The other
has a limit
surfaces
direction
2B, Ch.
surfaces.
is r e s o l u t i v e
the radial
lines
by
as the Fatou
affirmative
to the
along
function
It is indeed type
is given about
of P a r r e a u - W i d o m
function
the
in this
(Theorem
type,
Green
known
discussion
spect to the Green measure.
are e s s e n t i a l l y
theorem
limits
limit
to all Riemann
in 1958.
of P a r r e a u - W i d o m
from any fixed point lines
result,
us to give a c o m p l e t e l y
Riemann
the case
famous
of P a r r e a u - W i d o m
with Widom's
relations
hyperbolic
from its radial
[52] already
In §i an i n t r o d u c t o r y general
in the unit disk has
generalization
surfaces
Combined
LINES
The first main results
then permit
of surfaces
This
direct
of P a r r e a u - W i d o m
and
GREEN
all radii and can be r e s t o r e d
theorem,
first
VI.
a E R
hyperbolic be held
= e(a;z)
Riemann
surface
fixed and define
by equations
with
Green
two functions
120
dr(z)/r(z) respectively. r(z) the
In the
= exp(-g(a,z)) point
which
a
large
the
following for the
~ 0
and
8(z)
set of G r e e n
~ > 0
conformally
the
de(z)
we d e n o t e
by
any m a x i m a l
issuing
region
with
the
: -*dg(a,z), r(z)
equation.
arc
a.
CI(R(a,a))
special
line
from
(= {(a),
for
from a
on
short)
For a s u f f i c i e n t l y
= {z e R: g(a,z)
unit
solution
issuing
issuing
$(R,a)
from
closed
the
A Green open
is c o n s t a n t .
lines
closed
isomorphic
and
first
is by d e f i n i t i o n
de(z)
denotes
= -dg(a,z)
disk
under
~ ~}
is
the m a p
z ÷ e~r(z)exp(i0(z)). Thus
each
= ~8 Using
Green
in such the
R
a way
that
and
the
set of G r e e n in
~
longs
to
Green lines
~0(a)
e
{(a)
in
So
on
only
called
regular
zero.
We d e n o t e
by
{(a).
Since
is r e g u l a r ,
R
infimum, L(R,a)
The u n i o n Green
$'(a)). the
The
region
function
E L(a)
lB.
by
point
a
~'(a)
the
S(f;~(a))
all a
set.
the
point
of be-
of the
A Green ~
unit
which
~ E {(a)
over
line
~
is e q u a l
We
s
(B2)
lim
set
is b o u n d e d
Green
the p o i n t
problem
real-valued
lines
in
is d e n o t e d
connected
as a g l o b a l
S(f;{(a)) pointwise
$(a)
is c a l l e d
z
on
~
on the
function
by
{'(R,a)
and
(resp.
in
on it.
For
for w h i c h
set f
~(a)
on the
functions
(or
and we can use every
g(a,z)
~ f(~)
let
for
Suppose G[f;{(a)]
supremum)
on
R
dma-a.e, that
both
(resp.
on
s
L(a), on
R
L(a).
[(f;{(a)) G[f~{(a)])
of f u n c t i o n s
in
=
of G r e e n set
below;
= -S(-f;~(a)).
are n o n v o i d infimum
to
lines
region
coordinate
set of s u p e r h a r m o n i c
inf ÷ 0 s ( z ( ~ ; ~ ) )
S(f;~(a))
is
Green
that (BI)
as
be the
CI(~)
set of r e g u l a r
and
is a s i m p l y
Dirichlet
the
= ~0(a)
a line
g(a,z)
the
with
= d8/2~,
closure
in a c r i t i c a l
2w)
= ~ N ~R(~,a).
{(a)
~0(R,a) the
see that
z, of
and at
denote
an e x t e n d e d
{z)
[0,
= L(a) UE0(a).
centered
z(~;~)
We d e f i n e Given
in
8 6
we h a v e
z ÷ r ( z ) e i0(z)
let
lines. denote
of the
star r e g i o n
to
= L(a)
with
identify
is a c o u n t a b l e
~(a)
the
that
if it ends
E0(a)
if the
Let
such
It is easy
2~)
with
d m a ( ~ 0) = dma(8)
{(a).
{(a)
set.
if and
g(a,z).
a measure
measure ~
is p a r a m e t r i z e d
8(z) ~ 8 (mod i0 ÷ £8' we can
introduce
is a c o m p a c t
function
in
correspondence
circumference is e a l l e d
line
and be the
S(f;@(a))
we such
121
(resp. and
S(f;{(a))).
s" E S ( f ; @ ( a ) ) , so that
lies,
G[f;@(a)] if
function
G[f;@(a)]
problem
G[f;@(a)]
5A,
Ch.
Dirichlet
f
on
R
are
nonvoid
An
only
is c a l l e d of G r e e n
with
the
following,
real-valued
which
if t h e r e
function
exist
s
on
function
a harmonic R
such
solution
lines.
and
common of the
It is c l e a r
that
is an a n a l o g u e
of T h e o r e m
for any
E > 0.
Proof.
The
If this
proof
sequence
{s~:
with
n : i,
function
u
to that
in
then
a*
superharmonic
super-
u : G[f;~(a)].
of T h e o r e m
5A,
~(f;{(a))
such
Ch. then
IIl.
In fact,
there
exists
a
that
< ~,
n
is any p r e s c r i b e d
is a p o s i t i v e
is r e s o l u t i v e
and a p o s i t i v e
u = G[f;@(a)],
(s'(a*)-u(a*))
n=l
L(a)
u - Es E S ( f ; @ ( a ) )
case,
solution
2,...}
on
and
is the
is s i m i l a r
is r e s o l u t i v e
f
that
u + ss e S ( f ; { ( a ) )
m > i
the
The
HP'(R).
extended
(i)
where
resolutive.
and
Problem
We b e g i n
harmonic
f
fami-
S(f;@(a))
is c a l l e d
{(a)
s' e S ( f ; { ( a ) ) are P e r r o n
are h a r m o n i c
and
and
space
for any g(f;~(a))
~[f;@(a)]
G[f;~(a)]
to
and
IIl.
Theorem.
if
by
s' ~ s"
S(f;{(a)) then
for the
belongs
2A.
if and
and If
= G[f;@(a)],
is d e n o t e d
Dirichlet
The
we h a v e ~(f;{(a))
~ G[f;~(a)].
G[f;{(a)]
2.
Since both
point
in
function
R. on
So the R.
Then
sum
s'
for any
= ~n=l (s~ - u) fixed
integer
we h a v e
=
u(z) + m - l s ' ( z )
~ u(z)+
m -I
(s n'- u)(z) n=l
=
for e v e r y ilarly, that
z @ R.
there
u - m - l s ''
superharmonic Suppose, positive
It f o l l o w s
exists
belongs
to
S(f;@(a))
that
function
s n'(z) that
u + m-ls ' E S(f;@(a)).
superharmonic
s = s' + s"
conversely,
superharmonic
-i ~ n=l
readily
a positive
function
m
for any satisfies
we h a v e s
function integer the
a harmonic
satisfying
s"
on
m $ I.
conditions function
(I).
Then
in u
SimR
such
So the (i). and
a
122
u : lim c÷O wherever
s
conclude
that
Using usual
(u + es) ~ [ [ f ; { ( a ) ]
is finite. f
Corollary.
s
is r e s o l u t i v e
this,
Dirichlet
Since
we can e a s i l y
~ G[f;{(a)]
~ lim s÷O
is i n f i n i t e
and
( u - ss) : u,
o n l y on a p o l a r
u = G[f;{(a)].
show the f o l l o w i n g
set, we
[]
as in the case of the
problem.
(a)
If
fl'
f2
are r e s o l u t i v e
functions
on
L(a)
and
el'
~2 are r e a l n u m b e r s , then ~ifl + a2f2, m a x { f l , f 2} and m i n { f l , f 2} are r e s o l u t i v e and s a t i s f y the f o l l o w i n g , in w h i c h we w r i t e G[.] in place
of
G[-;{(a)]: G [ ~ i f I + e2f2 ] : ~ i G [ f l ] + e 2 G [ f 2 ],
G[max{fl,f2}] (b)
Let
functions
= G[f I] V G [ f 2 ] ,
{fn:
on
with
Let
limit
sequence
G[f]
is the case,
2B.
n = i, 2,...]
~(a)
if a n d o n l y if the
G[min{fl,f2}]
= lim
f
{G[f
G[f
n÷~
n
n ].
= G[f I] A G[f2].
be a m o n o t o n e
sequence
of r e s o l u t i v e
= limn÷~
Then
is
fn"
]: n = I, 2,...}
f
: n = i, 2,...} be a s e q u e n c e of p o s i t i v e n u m b e r s n d e c r e a s i n g to zero, such that DR(en,a) N Z ( a ; R ) = ~. We set
strictly
n = I, 2, . . . .
Since the
surface
R
is r e g u l a r ,
family
{R : n = i, 2,...} forms a r e g u l a r e x h a u s t i o n n sense of Ch. I, IA. For e v e r y n the G r e e n f u n c t i o n
with pole
a
is e q u a l to
function
length measure R
n
on
DR
u(a)
=
g(a,z)which
n
and if
w i t h the b o u n d a r y
(2)
u
1 ; 2~ ~R
So if
is s u m m a b l e
is the
function
an.
solution
f
=
Lemma.
Let
s
the g r e a t e s t [(~
)(~) n
T h e n we h a v e
lr2
in the
gn(a,z)
is an e x t e n d e d
with respect
for
Rn
real-
to the a r c problem
for
1 I DR = -~-~
f(z) *dg(a,z) n
f(z(go;an))dO
be a s u p e r h a r m o n i c harmonic
R
the
f, t h e n
f(z) * d g n ( a , z )
-)--~-JO
of
of the D i r i c h l e t
n
u
If this
{a
R n = R(~n,a) ,
valued
resolutive
converges.
minorant
=
I ~(a)
function of
= lim inf s ( z ( £ ; ~ n ) ) , n÷~
s
on ~(Z)
f(z(g;an))dma(~)"
which R.
is b o u n d e d
b e l o w and
We set
= lim inf s ( z ( £ ; e ) ) . e÷O
123
u(a) => I]L(a) S(c~n )(£)dm a (£) => I]L(a) -s(£)dm a (£). Proof.
Let
un
be the greatest
u n = H[s;R n]. Then, of (2) we have
: lim Un(a) n÷~
u(a)
=>
2C.
harmonic
minorant
u n => Un+ I => --- => u
I]L( a )
on
of
Rn
s
and
on
Rn, i.e.
Un ÷ u.
By use
: lim IL s(z(£;~n))dma(~) n+ ~ (a)
S(en)(Z)dm
We apply the preceding
a
(£) => I]L( a )
result
s(£)dma(Z). --
to the Dirichlet
~
problem
defined
in IB. Theorem. that
Let
f(~)
~(f;{(a))
G[f;{(a)](a) ~
and
Proof.
If
I
f(£)dma(~)
s
f(~)dm
L(a)
such
(£) > G[f;~(a)](a), a
the lower and the upper
and if
2B implies
=
--
integrals
with respect
> I]L( a )
u
is the greatest
harmonic
minorant
that
s(Z)dm a --
(£) > T]L ( a )
f(£)dm
a
(£).
is arbitrary, G[f;¢(a)](a)
The remaining tegral
~ r
on
dma, respectively.
s 6 ~(f;{(a))
u(a)
function
Then we have
//u(a)
denote
s, then Lemma
Since
real-valued
are nonvoid.
JL(a)
to the Green measure
of
S(f;{(a))
> r =
where
be an extended
and
inequality
is always
inequalities.
7
> | f(~)dm (£). = JL (a) a
can be obtained
similarly.
larger than the lower integral,
As the upper in-
we @et the desired
[]
Corollary.
If an extended
resolutive,
then
f
real-valued
function
f(~)
is dm a -sunlmable and G[f;{(a)](a)
: [
~m (a)
f(Z)dm
a
(~).
on
]L(a)
is
124
§2.
THE S P A C E OF G R E E N
In w h a t Riemann
3.
follows
surface
The G r e e n 3A.
gion
ON A S U R F A C E
OF P A R R E A U - W I D O M
in this c h a p t e r we a s s u m e
of P a r r e a u - W i d o m
that
R
TYPE
is a r e g u l a r
type.
Star R e g i o n s
We c h o o s e
notations
LINES
given
a point
in IA.
D = D(a)
a • R, w h i c h
We map the G r e e n
in the open unit d i s k
is h e l d fixed, star r e g i o n
~
and use the
¢'(a)
onto a re-
in the c o m p l e x w - p l a n e
con-
W
formally
and u n i v a l e n t l y
by m e a n s w : ~(z)
where
r(z)
= r(a;z)
9 • [0, 27) ~(a) UE0(a
with )
and
e(z)
of the g l o b a l
= Q(a;z). Since
Se,
8 E ~0' d e n o t e s
the end p o i n t
the
slit
of the G r e e n
e @ ~0'
s h o u l d be a c r i t i c a l
Theorem
iC , Ch.
V, shows,
In v i e w of the fact of the slits
theorem
there
exists
in the c o m p l e x
be the set of all we h a v e
¢(a)
~ r ~ i},
z(e)
:
point
of
[{g(a,zj):
he
g(a,z),
e • ~0'
onto
$8,
D
~D
this
is finite. ~
of
D
Each
z(e),
z(e) E Z(a;R). < =
As
and therefore
< ~. that the t o t a l
By the R i e m a n n m a p p i n g the o p e n u n i t d i s k
and u n i v a l e n t l y .
is the u n i o n
The a b o v e
a.
implies
which maps
conformally
0 • ~0"
than
i.e.
zj • Z ( a ; R ) }
Se,
a function
r(z(8))
other
z]. E Z(a;R)}
= exp(-g(a,z)),
boundary
slits
e E ~0 },
r(z)
E-plane
the t o p o l o g i c a l and all the
~0
is r e g u l a r ,
{reie:
line
I{1 - e x p ( - g ( a , z j ) ) :
length
Let
R
and so D = D w \ U{S8:
where
function
= r ( z ) e i0(z)
%~ ~ E 0 ( a ) .
(3)
being
coordinate
of the c i r c l e
observation
~
Clearly, ~D
shows that
w ~D
is r e c t i f i a b l e .
3B0 ~.
We are g o i n g
First we prove
Theorem. ci(D
~
to m e n t i o n
some u s e f u l p r o p e r t i e s
of the f u n c t i o n
the f o l l o w i n g
can be e x t e n d e d
continuously
to the c l o s e d u n i t d i s k
).
Proof.
$
set of
e E [-7,
By T h e o r e m
is a b o u n d e d 7)
2A, Ch.
hoiomorphic
function
such that the r a d i a l IV, the set
~
on
limit
~%.
Let
~
l i m r ÷ I $(re i0)
has a n e g l i g i b l e
complement
be the exists. in the
125
interval in
I-z,
D~
and
a point orem,
in
~).
by ~D
let
c
C0 : i
for the
in
to
in
~D.
sequences • -. ÷ 0
curve
sake
in
r ÷ i.
be the
{@"(n)}
> 8"(2)
>
in
~
G n : {z @ ]D :
@'(n)
G'
: ~(G
converges
In o r d e r
to p r o v e
to a point
on the
in
contrary
in
such
that
We take < arg
~D.
n
~. ZD.
Set
that
c'
points
We then
@'(i)
any
take
< @'(2)
and
to
the the-
S0 E
to a p o i n t
set of a c c u m u l a t i o n
included
.-- ÷ 0.
0 £ r < i}
c$
converges Suppose
E $ ~D
{rei@:
~, then
converging
= ~(e)
is a c o n t i n u u m and
8"(i)
the r a d i u s under
as
~
e'
let
E
{@'(n)}
c@ c@
of s i m p l i c i t y .
and
Then
by
of
@ 6 9
show t h a t
D
and
image
every
be any
only
c'
the
for
We h a v e
oscillates
If we d e n o t e
c~
of two
<
set
z < @"(n)}
and
n
Then and
G'n the
@'(n)
is a r e g i o n
part
of the
bounded
boundary
< @ < @"(n)}
on
Gn,
the
the r e g i o n
G~,
so that
Let
u(w)
E
be the values
Diriehlet that
v
[-~,
or
u(w)
tends
tends
to
to
Hence,
3C. same
We d e n o t e
letter
we h a v e Theorem.
the
~.
should
the
So
~I~
problem
in
is a r e g u l a r
u > 0 on
w
the
to
as
maps
on
We @
point
e@'
to the
boundary
n + ~.
This
to a p o i n t
extension ~
of
with
tends
e@.
the Since
v = u O ~,
so
to e i t h e r
to
~D \ ~G'n
along
with
that the
~D, as d e s i r e d .
T
to
continuously
CI(D~) onto
~D.
and So
' c@.
It f o l l o w s
contradicts in
G'.n
for the
belongs
curve
along
D
in
of
w E ~ D \ E.
set
in
is c o n t a i n e d
for
if
D. If
~
converge
continuous
= 0
~.
goes
goes ÷ 0
e'
comes
on the b o u n d a r y
and
E
{el@:
eventually
image
lies
Dirichlet
then
as
~
E
c
c@,,(n ) '
fact []
by the Then
following
The
its r a d i a l
fined
c'
~),
zero as
of the
e@.(n),'
to the arc
curve
w E E
and h a r m o n i c
< (@"(n) - @ ' ( n ) ) / 2 ~
u > 0.
of the
and t h e r e f o r e
zero
the
part
if
curves
corresponding
continuum
point
(@"(n),
thus
v(0)
= i
every
problem
v(~)
and
solution
is b o u n d e d
@'(n))
the
).
convergent
Since
oscillating
f(w)
is a c o n t i n u u m ,
~D
~C.
the r e g i o n
boundary
by two
n
derivative limit
~'(6)
is a l m o s t
belongs everywhere
to the H a r d y equal
to
class
~T/~,
HI(~) which
by 8~. i@ ) : lim ~-~<e t÷0
(~(e l(@+t) ) - ~ ( e i @ ) ) / ( e i(8+t) _ ei@).
is de-
126
is of bounded Proof. Since ~D is rectifiable,, the function. ~I~I3% variation. We set d~(e it) = (ielt)-id~(e~t) on ~I3 . Then I and for
eitd~(eit)
= i-lf
d~(eit)
= 0
n : 2, 3,... I
enitdB(eit ) = i-i I ~D{
e(n-l)itdY(e it) 3D%
(n-i)[
~(eit)e(n-l)itdt
= 0,
J because ~({) is holomorphic in I]~ and continuous up to the boundary. By the F. and M. Riesz theorem (see Appendix A.3.2 and A.3.3) dz is absolutely continuous with respect to the arc-length measure and u(rei8 ) = i
0
P(r,O - t)d~(e it)
belongs to the Hardy class HI(ID ). Setting have by the Fatou theorem (Appendix A.I.2) f(e it )
= ~~(
eit
)
d~(e it) = f(eit)dt, we
a.e.
So the radial limit of u(~) is equal to ~ I ~ a.e. on ~]D . On the other hand, since du is orthogonal to e nit , n = i, 2,..., we have I~D
e -it + ~ e-l~_~d~(eit)
= f~]D~
d~(e it)
and therefore
u(~)
=
i I i [e it + ~ e -it + ~] ~ [e-~-- + d~(e it) ~ ~9~ ~ e_mt_ ~j
= 4~ = ~i =
f
•
[elt+ ~ ~D [e±t_ ~
+I
i d~(e it) = 2~
f
~]D
it
e__
el~_
I ~13 -e ~ I - % d~(eit) = 2-~ i ; ~I] (e~(eit) it- ~)2 d(eit )
~'(~),
which implies the desired result. [] Combined with the Fatou theorem, the preceding theorem shows:
127
Corollary.
If
~Y/Z%
verges to the value
exists at a point (~Y/~6)(~0)
any fixed Stolz region 3D.
in
~{
as
with vertex
in Appexdix A.I.2.
For
the connected
S(~0;~,p) {z ~ ~:
to which the point
~0 ~ ~ '
S(~O;~,O)
through
~0
of Stolz regions
0 < ~ < ~/2 component
is adherent.
con-
Y'({)
tends to
~0"
and
given
0 < 0 < i
we de-
of the set
-~ ~ a r g ( l - Z~o) ~ ~, 0 ~ ~0
then
%
We now have to modify the definition
note by
region
%0 ~ ~ '
uniformly
Izl < I},
In order to make the new Stolz
simply connected,
we always assume that
P ~ sin ~. Theorem.
(a)
every angle (b)
(~/~6)(~0)
exists and is different
80 E [0, 2~) \ ~0' where
Let
w 0 : exp(i80)
80 E [0, 2~) \ ~0 = ~(%0 ).
Then
satisfy the condition
SD
have the same tangent at the point
with
0 < ~ < ~/2
the region
Stolz region with vertex
p
depends
S(w0;a,p) ~0
{0
~0' lies in
~%
We showed
Poisson
integral of
Theorem
in Theorem
function 2A, Ch. IV.
point in
the
in
~
3C that
Stolz region
(< ~) in the disk sides which, at
%0
and ~0 ei(~+~),
Since
~-i
Stolz region
~/~ ~'(~)
Hence the statement
~6
any
except the vertex to the two adjacent
respectively.
exists a.e. and is not identically
can vanish only on a set of measure
c
which,
(a) holds
~'
is the
zero, its zero by
for almost every
~0"
~
satisfies
the condition
except the initial point
and has a tangent at
tial to the circumference tinct from
2~
80 E [0, 2~) \ ~0
Draw a smooth curve ~
Under the map
~.
Suppose that disk
Z~/$~. ~T/~
D) and
2e.
and such that the tangents ~0 ei(~-e)
of
for any
a Stolz region of the form ~.
is sent to a curvilinear
triangle with smooth
Proof.
Consequently,
(b) above we mean by a curvilinear
sides have directions
boundary
and
and angular measure
closed eurvilinear
w 0.
contains w0
and angular measure
In the statement with vertex
D on
in (a) and set
(see (3) for the definition
~w
S(w0;~,0) , where
from zero at almost
%0 = ~-l(exp(i80))"
t 0. .
Let
We suppose that ~i' ~2
We have
~(~i ) - ~(~2 ) =
T'(~)d~,
in (a).
~0' lies in the c
is not tangen-
be two points on
c
dis-
128
where
the r i g h t - h a n d
and let
%2
side is the i n t e g r a l
tend to the p o i n t
~0
along
along
c.
the c u r v e Then
c.
Fix
tl
~(~2 ) ÷ ~(%0 ), so
that
I
~(t I) - ~(t 0) = Since
~'(t)
tends
to
(3~/3~)(~0)
shown that the d e r i v a t i v e
of
is e q u a l to
(~/~t)({0).
arg{~(%0)}
u n d e r the map
angle
between
with respect boundary tangent Hence
~D to
two c u r v e s
to the c i r c u m f e r e n c e
~.
at
cI
{0
between
~D
and
at
~
÷ ~0
~(e).
~(~0)
to
tends
As
~D
Since
~(t ~ )
to
~0' we h a v e
the c u r v e e
issuing
under a rotation the c i r c l e
and
along
at
c
{0 ~0
(3~/~)(~0)
~ 0, the
is o b t a i n e d
e and
e 3~ w .
f r o m the
arg{~(t0)}.
= w 0 6 3~ w
{~n*: n = i, 2,...}
the
nontangentially
by the a n g l e
( = w n, say)
by
preserves
and the curve
~(~0)
e x i s t s and
is r o t a t e d
~(t)
from
w 0 = ~(~0 ), w h i c h
we can find a s e q u e n c e
~ ~0'
t E c
%@
and t h e r e f o r e
e2
~Dt
as
~ + ~(~) and
the a n g l e
tifiable,
at
~'(t)dt.
So the t a n g e n t
has a t a n g e n t
that b e t w e e n
~
{l
is e q u a l to SD
~C ~
is r e c -
such that
Then,
wn ÷ w 0
and
~ ( t ~ ) - ~(t O) w - wO % ~ - ~0 = lim n n÷~ ~tO
= lim n÷~
We thus h a v e a r g t0~r[3~~ " )} = a r g w 0 - arg ~0 This
shows
w 0.
The first h a l f of
in p a r t i c u l a r
c'
~D
and
a Stolz-region
be any one of its sides
issuing
arg(1-w~ for
w E c'
D t.
Set
We s h o u l d
with
w i t h the c o m m o n
for
~i 6 ci,
above,
c!l
equations c'
c
arg(l-
initial
i : i, 2.
converge
to
~ 0 ) = e.
a r g ( l - w i w 0) = ~l.
point
~0
c
from
for i n s t a n c e
to
t0
for
w0:
c
in
at
D
is a s m o o t h
and
cI
arg(l-
and
determined
lies in a Stolz r e g i o n w i t h v e r t e x
in
As s h o w n
w0, w h i c h
w.l ~ c!l' r e s p e c t i v e l y . w0
~I' c2
t i ~ 0) = ~i
c i' = ~(c.). ± at
in
at
we take any
segments
such that we set
curve
and has a t a n g e n t
To see this,
and have t a n g e n t s
lies in a Stolz r e g i o n w i t h v e r t e x
and c o n s e q u e n t l y
included
and d r a w two
And f u r t h e r w0
S(w0;a,p)
so t h a t
converges
0 < ~i < e < e2 < 7/2
~t
h a v e the same t a n g e n t
w
0) =
c = ~-l(c' \ {w0}),
show that
t0 , for w h i c h we h a v e ~2
$~
(b) is n o w clear.
Let us now c o n s i d e r let
that
(mod 2n)
satisfy
the
So the c u r v e c I'
by ~0
and
c~,
determined
129
by
cI
to
e, we h a v e
and
satisfying of the
c 2.
the
Since
shown
equation
statement
4.
Limit
X.
For a g i v e n
Let
can be t a k e n to
~0
~ 0 ) = ~.
arbitrarily
and has
This
proves
close
a tangent the
at
latter
~0
half
Lines
be a f u n c t i o n Green
u~(~)
e2
converges
[]
Green u
and c
arg(l-
(b).
along
4A.
el
that
line :
on
R
with
~ ~ ~(a)
n
we
Cl[u({z(~;B):
values
in a c o m p a c t
space
set o
~ < ~})].
<
~>o If
u~(~)
dial
consists
limit
Theorem.
of Let
Green
star
~(~)
exists
on
(i)
~ in
~
u
that,
Since
to
E
this
property.
~-io
¢
Hence
Then
(ii) {'(a)
Let
u
is s i m p l y
uniquely
under
the
in any So on
zero.
is a b o u n d e d
holomorphie every
function
~0
function
through
under
with
vertex
in
for a l m o s t
every
so that
its r a d i a l
limit
harmonic
the h a r m o n i c ~(a)
= 0.
: exp(-u(z)
function ~ E L(a).
on
for a l m o s t function
conjugate Sinc~
u
say)
the map in
E.
~ e L(a). vanishes
every
on ~
{0
possess
~80
exists
~ 0
~%
80
Stolz
we see
(= {0'
Let
~, ~0
fixed
zero,
~-l(exp(ie0))
line
on
of such
of m e a s u r e
n0).
and
point
any
totality
region
~(~)
limit
~'(a)
every
Stolz
,
on the
the
on
~(~) •
condition
function
of
Green
~(~).
dma-measure.
sets
2~) \ n0,
of the
u
be the
definition
the ra-
is dm a - m e a s u r a b l e vanishes identically
holomorphic
to
E
by
~ E L(a)
for a l m o s t
preserves
be any p o s i t i v e
the
for a l m o s t
tends
Hence
connected,
tends
Let
[0,
image
h(z)
exists
%
t 0.
80 E
v ~ 0
of m e a s u r e
as
÷ ~D
exists.
u ~ 0, t h e n
is a b o u n d e d
3A for the
is c o n t a i n e d
on a set
~
every
(see
~(Ze0 )
limit
harmonic
then
holomorphie
v(~)
vertex
~:
for a l m o s t
v
is c a l l e d
is d e n o t e d
~ ÷ ~(~)
holomorphic,
theorem
point
every
function
on a set of p o s i t i v e
Then
with
and
for a l m o s t
be a b o u n d e d
Fatou
~
the
be a p o s i t i v e
The
is b o u n d e d
then
line
u
Then
vanishes
~%
.
belongs
If
u
to a f i n i t e
region
let
{'(a).
point,
Green
is finite.
Let
by the
one
the
and
v = u o ~ - i o ~.
so that
in
and
~(Z)
Proof.
in
a E R
If
whenever
along
region
L(a).
set
u
of o n l y
{'(a). of
only
~ ~ L(a).
u
Since
exists
is p o s i t i v e ,
- i[(z))
~'(a) Since
and t h e r e f o r e ho ~-io ~
does
by
(i)
not
h(~)
vanish,
130
its r a d i a l
limit
that
h(~)
~ 0
~(Z)
= -log
4B. fact,
lh(Z) I
In the
Let
case
f(~)
on a set of m e a s u r e
and
~ E ~(a).
is f i n i t e
of a PWS,
Theorem
and
Consider
•
be a b o u n d e d the r a d i a l
for a l m o s t
Rn
with
every
in 2B.
limit
{R
is d e f i n e d
the o r d i n a r y
Then
fn
a.e.
We
Dirichlet
bounded.
It is e a s y
bounded
equioontinuous
subsequence monic
data
set
clear
see
In
that going
S~
to
S~:
+ S 0) if
solve
w
rectifiable
boundary
let can
slit
the
and
of
with
of the
can be v i e w e d
Then is equal
Rn
Dirichlet
=
problem
conformal
limit
So,
forms
of
a uniformly passing
converges
to a
to a h a r -
map
}
of the
we d e f i n e d
in
to b e l o n g w' E D
D.
For
of its
to
two
Se
satisfying
common
point
exp(-g(a,z(0))
sense
3A.
Pn = It is
as the u n i o n
only
i.e.
Green
z E R'n, w h e r e
for the r e g i o n
of
The
in an o b v i o u s
~R n,
is u n i f o r m l y
D n = (pn D) D D w .
e E ~0'
> 0).
2,...}
which
for
is d e f i n e d
as the
on
solution
R.
problems
$0,
is the
{u n}
on
D : D(a),
slit
R
the
Consequently,
= pn ¢(z)
w E $8
I m ( w ' w -I)
of
Se
+ i0).
as a J o r d a n
region
Then with
L, w h e r e
L = U{S +e U S~:
v
n Un+2,...}
).
uniformly
Dirichlet
is r e g a r d e d
D
exists
function
: n = I,
n a s s u m e that
Cn(Z)
each
.. }
measurable
{u
CI(R
the r e g i o n
a point
the r e g i o n
Now
on
we can
and
I m ( w ' w -I) < 0 (resp. + and S 8 is the v e r t e x
L(a).
= f(~)
{Un+l,
we c o n s i d e r
we r e g a r d
and
on
where
Then
that
almost
onto
.
u n = H[fn;Rn] , which
family
hand,
2,
we c o n s i d e r
be the image of Cn' i.e. D I =D D 2 ~ .. • =D D n =D . . . D D .=
Dn
purpose,
(resp.
to
u,
~'(a)
Let
We are
n ary
lh(z)1,
strengthened.
function
i,
=
n
fn'
problem.
R'n = {'(a) D R n
exp ~n"
edges
say
other
star r e g i o n
this
It f o l l o w s
= -log
[]
2C is m u c h
is a b o u n d e d set
if n e c e s s a r y ,
function, On the
then
zero.
u(z)
G[f;{(a)](~)
: n
n
For e a c h
the b o u n d a r y
~ E L(a).
which
We
a.e.
measurable
fn(Z(~;en)) for
As
~ E L(a).
an e x h a u s t i o n
R(~n,a) , as g i v e n for
only every
exists
f(~)
f is r e s o l u t i v e
Proof
vanish
we have:
Theorem.
to
can
for a l m o s t
0 E ~0}
U {e ie : 8 E
[0,
2w) \ ~0 }.
v be the r e s t r i c t i o n of u o ¢-i to the r e g i o n D. Then n n n c l e a r l y be e x t e n d e d c o n t i n u o u s l y to the b o u n d a r y L, the b o u n d -
values
being
denoted
by
f~.
If
Z = ~e E ~ ( a ) ,
then
we h a v e
131
+
f~(e 18)
point
= f(£).
If
Zn(W) 6 R
sequence
{zj:
~n(Zj) ÷ w tinuity.
D.
W E S;
(or
converges
w
of
f~(w)
C R'
=
f*(W)n
the
is
sequence
£ = £8 E l ( a ) ,
of
z 6 S + US;. e D supported
see that of
L.
d~ w
exists
there
3
÷ zO(w).
+ U(Zo(W)).
function
f*,
is
z. ÷ z (w)
a
a
and
n
determined
by c o n -
(w): n = I, 2,...} n to a p o i n t z0(w) 6 R.
: Un(Zn(W))
Thus,
Namely,
stays In
if {f~}
i.e.
: f(£)
and
f*(w) if
properties
uniquely
~-l(pnlw')
to a w e l l - d e f i n e d
there
and (ii)
{z
converges
f*(e ie) if
S8) , then
= Un(Zn(W))
with
w' ÷ w, t h e n
then
pointwise
and
(or
Zn(W)
n
the
R
and
S:),
(i)
2,...}
such
subset
w' E D
w e S;
Such a p o i n t
For e a c h
if
and
such that
j : i,
in
in a c o m p a c t
fact,
8 e ~0
: u(z0(w))
For any
given
w E D
on
Since
L
L.
is a b s o l u t e l y
let
d~
w is r e c t i f i a b l e ,
continuous
be the h a r m o n i c it is not
with
respect
: S
f~d~w'
hard
measure to
to the a r c - l e n g t h
As we have
(U n o }nl)(w)
: Vn(W)
L so we d e d u c e , vergence
by l e t t i n g
n ÷ =
and
using
the
f
(u o ¢-l)(w)
= I
f* dm
JL Namely, D
u o ¢-i
is e x a c t l y
corresponding As we h a v e
i}
with
theorem
dominated
con-
8 6 shows
to the seen
[0,
the
solution
function
in T h e o r e m
2w) \ ~0
of
r ÷ i
of the
problem
3D, ~w
almost
every
is o r t h o g o n a l
radius
for a l m o s t
every
8 E
every
£ E ~(a),
Every
we can
[0,
as was
to
~D.
So the
= f(£8 )
2z) \ ~0"
This
means
that
= f(£)
to be
shown.
[]
show:
dm a - s u m m a b l e
for
{re ie : 0 ~ r <
that
As a c o n s e q u e n c e Corollary.
Dirichlet
f*.
lim u ( z ( £ ; ~ ) ) for a l m o s t
• w
( u o # - l ) ( r e i 8 ) + f*(e i8) as
Lebesgue
theorem:
function
on
L(a)
is r e s o l u t i v e .
Fatou
132
§3.
5.
THE
GREEN
LINES
Convergence 5A.
bolic
the
function kb(0)
For
of G r e e n
surface
with
the M a r t i n
R
at
for a n y
III.
£ E
pole
Let
L(a)
and
The
and of
A.
sists and
CI(£)
means
Z U {a} We
say that
of a s i n g l e
to the
a detailed tive
5B.
We a s s u m e
for
z E R, w h e r e
poles
shall
and
IC,
Ch.
~g(a,z)
V,
set
then
the H a r n a c k
We d e f i n e
covering
s(z)
function {V
}
of
R. R
R*,
Martin
so that
have
lines
been
given
Z E L(a).
i.e.
Since ez
R*
is c o m p a c t
is a n o n v o i d
is c o n v e r g e n t
standing Green
that
that
problem
line
if
subset
e~
due
con-
to B r e l o t
in
L(a)
(with
See
Brelot
[5]
the p r o b l e m
has
for
an a f f i r m a -
R
is a r e g u l a r
PWS.
We t a k e
: 6g(a',z)/6g(a,z)
function
on
R.
Since e ~.
: ~{g(z,zj): shows
R
If
It is easy
to
a ~ a',
then
is a PWS, So,
if we
we h a v e
see that it has by T h e o r e m
set
zj E Z(a~R)},
that
is a p o s i t i v e
s(a)(z)
< ~
for
superharmonie
z ~ Z(a;R)
function.
Set
and = g(a)(z)exp(-g(a',z)).
= s(a)(z) + g ( a ' , z ) ,
on
R*.
= 2(Zg(a,z)/~z)dz.
u(a,a';z)
harmonic
kb
R,
of PWS's.
follows
inequality
and t h e r e f o r e that s (a) (a) g (z) = e x p ( - s ( a ) ( z ) ) (5)
show
zj e Z ( a ; R ) }
s(a)(z)
in
every
case
Z(a;R) U {a'}.
~{g(a,zj):
in
of
set
is a m e r o m o r p h i c
in the
of
see that
is a long
P(a,a';z)
P(a,a';z)
origin
Green
Z
boundary
b 6 A, be the
dm a ) is c o n v e r g e n t .
in the
in w h a t
a' E R
of
~ E L(a)
almost
We
at least
point
line
measure
£
R, we
Here
whether
Green
the
consider
end
of
in
a Green
exposition.
solution
another
closure
point.
asking
kb,
properties
and
the
0
of a h y p e r -
A I) be the M a r t i n
Let
by
R*
: CI(~) \ ( ~ U {a]),
is n o n - c o m p a c t
Choquet
respect
the
(resp. A).
basic
denote e~
where
A of
be f i x e d
e£
compactification
We d e n o t e
b E A. a E R
let
points
b.
let
BOUNDARY
Lines
set of m i n i m a l
= I
in Ch.
THE M A R T I N
Let us c o n s i d e r
Riemann
(resp.
AND
In fact,
consisting
which
is a l s o
it is a p o t e n t i a l . of s i m p l y
connected
a positive We t a k e open
sets
super-
an open V
133
such that,
whenever
V
disk which contains associate notes
a function
a harmonic
A V B ~ ~,
of the f o r m
conjugate
t a i n s no s i n g u l a r i t i e s
of
is a u s u a l h a r m o n i c critical
point,
say
UV B
is i n c l u d e d
of
s(z) + i~
siV a .
s, t h e n
conjugate
z E V , where
u
of
in a p a r a m e t r i c
s(z).
(z),
W i t h each
z E V , where
To be m o r e p r e c i s e ,
s(z) of
is h a r m o n i c
s
on
zj, of m u l t i p l i c i t y s(z)
for
V
at m o s t one s i n g u l a r i t y
V .
mj,
If
V
we
~
de-
if
V
con-
on
V
and so
V
contains
a
then
= -mj log Iz - zj I + u(z)
is h a r m o n i c ,
and so
$ (z) = -mj arg ( z - zj) + ~(z), where
~
is a h a r m o n i c
conjugate
of
u
on
V s.
Then we set
f (z) = e x p ( - ( s ( z ) + i~ (z))) for
z E V , which
that,
a constant union ({V
~B
defines
with
any n o n z e r o
a line b u n d l e ,
2B, Ch.
element,
V s.
associated
w i t h the c o v e r i n g ({V
section,
say
belongs
f to
function
on
Since
of
Let us
with norm
of this e l e m e n t
}, {he}).
a nontrivial
R, w h i c h we d e n o t e by
By the
~ {0}.
~(R,~a,a,)
({V
If I
~(R,{a,a,).
~(R,~a,a})
h (a'a'),
defines
So the p a i r
< a , a , , ( ao,vae,r ) R, for w h i c h
{V }, i.e.
}, {f h })
A V B ; for the
V
set.
T h e n one can find a r e p r e s e n t a t i v e
that the p a i r
It is easy to see -i is e q u a l to
f (z)f6(z)
connected
V) we k n o w
say
i.
F
on
~ ~,
say
f(a,a')
less t h a n
morphic
NV~
one on the i n t e r s e c t i o n
forms a h o l o m o r p h i c
(Theorem
function
V
in a s i m p l y
~, we see that
Widom t h e o r e m choose
~
is i n c l u d e d
}, { ~ B } ) for each
e,
of m o d u l u s
UV B
V
({V }, {f }) i
is a h o l o m o r p h i c
for each p a i r
It is i m m e d i a t e
single-valued
F(a,a';z).
holo-
The p r o p e r t y
of
that we n e e d is this:
(6)
IF(a,a';z)l Let
{an: n = i, 2,...}
decreasing
We m a y
Green f u n c t i o n
for
exists
for
R
n a constant
~gn(a',z)/~g(a,z) -(2~i)-16g(a,z)) the p o i n t
be a s e q u e n c e
to zero w i t h the p r o p e r t y
Rn = R(en,a). function
~ u(a,a';z)
a'
R
suppose here with pole
n w i t h pole c < o
along (resp.
on SR n a).
~Rn,
that a'.
o n l y on for
of p o s i t i v e
a' E R I. Since
Let
ga- ~
n inequality
a, a'
and
the h a r m o n i c
u(a,a';z)
~ i
on
numbers : ~
and
strictly set
gn(a',z)
be the
is the G r e e n shows that t h e r e
R, such that
-(2~i)-l~gn(a',z)
represents Since
R.
~R(~n,a ) AZ(a;R)
a, the H a r n a c k
depending
on
0 <
(resp.
measure
of
R, we h a v e
Rn
at
134
(7)
0 S u(a,a';z)(6gn(a',z)/Gg(a,z))
on
DR
. Since n the m e r o m o r p h i c
and
since
u(a,a';z), function
(6) holds,
defined
by
(5),
vanishes
~gn(a'~z)/6g(a,z)
the
S c
with
at e v e r y
the
same
pole
of
multiplicity
function
F(a,z';z)(6gn(a',z)/6g(a,z)) is a h o l o m o r p h i c It f o l l o w s
function
from
on
R
and
n
is c o n t i n u o u s
CI(Rn).
on
R, we h a v e
Since
6gn(a',z)
converge
to
R.
Since
both
F(a,a';z)
holomorphic
on
are
harmonic
bounded
and
R, the real
line
limit
~(a,a';~)
z(~;~)
in
0.
in
A.
We d e n o t e
parametrization Theorem. forms
The
Take
function almost dial nate
Along
set
A(a)
has
~ E L(a).
z = x + iy
Z
a' E R
P(a,a';~)
we t h e n
radial
thus
A
lines
of
for
exists.
in such
b~
set
when
every
radial
Green
that
dx = d g ( a , z )
and
each
dy
if topology
of c o n v e r g e n t denote
~ = ~e
lines
the
Green
limit
of
according
radial
z E ~
to the
= dx
from
a
one. above,
the
P(a,a';~)
for w h i c h
we take
= *dg(a,z).
have
seen
limit
~ E L(a)
= (~xg(a,z))dx
issuing
dm a - m e a s u r e
As we h a v e
finite at any
At
Martin
in IA.
~ a.
a way
6g(a,z)
F(a,a'~z)
almost
finite
to the
b~
of G r e e n
a'
look
the let
defined
a nonzero We
along
and
functions
to be c o n v e r g e n t
respect
= A(a)
L(a)
with
limits
bounded
4A both
a nonzero
is said with
~ E A(a) be
has
are
of t h e s e
~ E L(a).
L(a)
in
parts
So by T h e o r e m
of c o n v e r g e n t
subset
P(a,a';z)
every
limit
any
R.
every
A(R;a)
write
of G r e e n
a measurable
Proof.
by
For e v e r y
sometimes
on
uniformly
I ~ c
imaginary
nonzero
~ E
to a p o i n t
L(a). We
line
almost
F(a,a';z)P(a,a';z)
the
P(a,a';z)
for a l m o s t
Green
converge
a ÷
lines
have
~ E L(a).
A regular
as
functions
F(a,a';z)P(a,a';z)
Green
and
and
I ~ c
6g(a',z)
IF(a,a';z)P(a,a';z) on
boundary.
(7) that IF(a,a';z)(6gn(a',z)/~g(a,z))
on
up to the
a local
the
for ra-
coordi-
135
and
6g(a',z) where
g(a',z)
uniquely g(a,z)
~(a,a';£)
tends as
to
shows
(9)
we (i) and
Then
the
both
left-hand
g(a,x+
g(a',z),
We m a y
assume
Then
side
iy 0)
we h a v e
of
and
of the
of
(9)
{g(a',x+
exists such
to
determined that
(8) has
g(a',x+ surface
a limit
iy 0) R,
a'
run
there
for e v e r y
a' E A.
on
density
R, the
portional.
As
eL
consists
6.
Green 6A.
exists
iY0)/g(a,x+
a sequence that
tend
x
to
zero
a measurable
and
on
b
eL
in
£
subset
A
We
Theorem. (a) f E LI(dx )
Since of
shown
So the
of
A
in
of
L(a)
R.
such
A
and
shall and
Let
the
in
R
establish
a C R z:
eL,
b. Then that
exists
that
this
each
with
b E A
kb
and
means
that
£ 6 A.
[]
is c o n t i n u o u s k b'
are
b = b'.
pro-
Namely,
Boundary
further
connection
between
the
space
of
boundary.
~ ÷ b£
function
2B,
for
be fixed.
= G[f o z;~(a)].
kb
implies
III,
the M a r t i n
the M a r t i n
The map
function
point
final in
= kb,(a')/kb,(a)
the
in Ch.
with
is a r b i t r a r y
as a f u n c t i o n
dense
subset
zn
z n ÷ b.
Since
a countable
iY0)/dx}
iY0)).
of p o i n t s
xn ÷ 0
is c o n s t a n t
through
of a s i n g l e
Lines
lines
H[f]
as
l'Hospital's
m a (A) = i; (ii) for each a' e A and ~ e A, P(a,a';~) is finite. So, if b, b' E e£ with £ E A, t h e n
Green
x =
on
+ iY0)/dx).
iYo)/dx)/(dg(a,x +
kb(a')/kb(a).
kb(a')/kb(a)
let
see that
= lim x+0 there
is e q u a l
quotient
{dg(a',x +
kb(a')/kb(a)
and
£.
= lim x÷0
" 0 x n + ly
coordinates
Now
factor.
along
of
that
b E e£.
member
conjugate
of the r e g u l a r i t y
Re(P(a,a';£))
Let
+ i~xg(a',z))dx,
: (dg(a',x + iY0)/dx)/(dg(a,x
Since
in v i e w
constant
= constant
exists,
zero.
x ÷ 0
rule
the
Y = Y0
Re(P(a,a';z))
Since
the h a r m o n i c
up to an a d d i t i v e and
(8)
the
denotes
= (~xg(a',z)
of
Then
we h a v e
A(a)
f o ~, d e f i n e d In p a r t i c u l a r ,
into
the A
dm a -a.e. f o ~
following: is m e a s u r a b l e . on
A(a),
For any
is r e s o l u t i v e
is d m a - s u m m a b l e
and
136
I
f(b)kb(a)dx(b)
= I
A (b) ~(~)
If
u
is a p o s i t i v e
for a l m o s t
function
u
(c)
every
function
exists
a.e.
A(a)
on
R, then
u(b~)
=
The same is true of e v e r y m e r o m o r p h i c
characteristic,
P(0,a;b) The set
harmonic
~ E A(a).
of b o u n d e d
P(0,a;b)
(d)
f(b~)dma(~)" L(a)
on
i.e.
AI
= kb(a)
log lul E SP'(R).
and a.e.
can be c h o s e n
on
A I.
in such a w a y that the m a p
in (a) is i n j e c t i v e . (e)
The map
(A(a),
dm a)
Proof.
(a)
in 5B.
Then
n
~
and
is an i s o m o r p h i s m
(A, dXa)
dXa(b)
We take a s e q u e n c e ~
is the
goes to i n f i n i t y ,
any d x - s u m m a b l e finitions
with
We also have
4.
Put
problems
~ S(g;~(a))
H[f] ~ G [ g ; { ( a ) ] .
it is r e s o l u t i v e
by C o r o l l a r y
J that
G[f;~(a)]
(b) t i o n on
R, i.e.
have
G(b)
dial
limit
is d e f i n e d Suppose
the s t a t e m e n t Suppose
: 0
for e v e r y
R.
on
set
on
~ E B. so that,
to be d x - s u m m a b l e , = H[f]
By C o r o l l a r y
at once. Then,
positive
by T h e o r e m
by T h e o r e m
~(~)
= 0
4B,
~ e L(a),
a contradiction,
cB
function
we h a v e u
on
u(z)
L(a).
~ > 0
such t h a t cB
is r e s o l u t i v e
for
4A, the ra-
function which
number
dma-measure
func-
III, we
dm a -a.e.
exist a p o s i t i v e
of p o s i t i v e
harmonic
5E, Ch.
dm a - m e a s u r a b l e
We c l a i m that
by C o r o l l a r y
2C we h a v e
(~).
is a s i n g u l a r
that t h e r e
for any
and
a
T h e n the c h a r a c t e r i s t i c
is c l e a r l y
H[f]
On the o t h e r hand,
B ~ L(a)
in IB and Ch. III,
H[f] ~ G [ g ; ~ ( a ) ] .
i.e.
g(~)dm
as a n o n n e g a t i v e
L(a).
~(~) ~ ~CB(~) This
4 I.
exists
on the c o n t r a r y
dma-summable Since
a.e.
a.e.
u
the de-
is a s s u m e d
= H[f].
: [ J L(a)
(a) f o l l o w s that
as be
f(b)kb(a)dx(b).
u E HP(R) A I(R).
~(~)
a measurable
on
first
f
41
= ~[g;{(a)]
G[g;{(a)](a) From these
f III,
let
By c o m p a r i n g
given respectively
Since
given
~ ÷ z(~;~ n)
Secondly,
g : f o 7.
3D, Ch.
spaces
the p r o p e r t i e s
functions
and t h e r e f o r e
H[f](a) = [ It f o l l o w s
satisfying
it is m e a s u r a b l e .
on
of the D i r i c h l e t S(f)
{a n]
the m e a s u r e
= kb(a)dx(b).
limit of c o n t i n u o u s
so that
function
3A, we see that
between
of on
and
~(~) B
is
~(a).
~ G[BCB;~(a)](z)
is s i n g u l a r
while
the
137
function erty
G[~cB;~(a)]
(a) i m p l i e s
-I(A)
is q u a s i b o u n d e d
in p a r t i c u l a r
is dm a - n e g l i g i b l e .
for a l m o s t
every
Suppose
f(b)
f(b)
Then
= 0.
E A(a).
By
G[g;~(a)].
u
= G(b) f
for
(a) a b o v e
on
and T h e o r e m
As an a n a l o g u e
s
for any
e > 0.
on
R
for any
~ ~ A(a).
a.e.
L(a).
For any
on
A(a).
u - Es E S(f)
every
characteristic,
~ E A(a).
bounded holomorphic
result
Re(~(0,a;~)) ~ E A(a).
bounded holomorphic
Since
from (12)
every
~ E A(a).
has a d x - n e g l i g i b l e
(i0) and
and
= prob-
superu - ss E S(f)
so that
u(£)
u(~)
exists
exists,
dm a-
we have
~ f(b~). a.e.;
inequality
so we h a v e
is o b t a i n e d
~(~) f r o m the
: ~(b~) if
u
is a m e r o m o r p h i c
it can be e x p r e s s e d
follows
theorem
f r o m the a b o v e
P(0,a;z)
of
(Theorem
2B,
consideration.
: k(b~,a)
is e x p r e s s e d
the p r o p e r t y
as a q u o t i e n t
(b) i m p l i e s
of
that
: P(0,a;b~)
The p r o p e r t y complement
(a) i m p l i e s
in the space
in p a r t i c u l a r A.
(ii) that Re(P(0,a;b))
function
as a q u o t i e n t
5B we s h o w e d that
: k(b~,a)/k(b~,0)
P(0,a~)
~(A(a))
for e v e r y
u = H[f]
= f(b~)
in v i e w of W i d o m ' s
functions,
(ii) for a l m o s t
otherwise,
= f(b~)
a positive
limit
is f i n i t e
Finally then
In the p r o o f of T h e o r e m
for e v e r y
function.
exists;
~ S(g;~(a)),
~ g(~)
s(z(Z;e))
: f(b~)
functions,
so the d e s i r e d
(i0)
= 0
and h e n c e
for a l m o s t
(c)
~(f)
The r e v e r s e
of b o u n d e d V);
= ~(b~)
for the D i r i c h l e t
exists
for w h i c h
lim inf ÷ 0 s ( z ( ~ ; ~ ) )
g(~)
III, we have
4A the r a d i a l
~ e A(a)
~(~)
Ch.
The p r o p -
harmonic
u + Es E ~(f)
(u + e s ) ( z ( ~ ; ~ ) )
By T h e o r e m
~(b)
2A is t r u e there
k n o w that
~(~) + c l i m i n f ~÷0
fact
~(£)
positive
Set
5E, Ch.
satisfying
We a l r e a d y lim inf
2B,
positive.
is d x - n e g l i g i b l e ,
shown that
A.
of T h e o r e m
function
dma-a.e,
A
b E AI, w h e n e v e r
is d x - s u m m a b l e
harmonic
f(b~)
~
is a q u a s i b o u n d e d
compactification,
By Lemma
A
H e n c e we h a v e
lem for the M a r t i n
on
and s t r i c t l y
if
~ E A(a).
next that
We d e f i n e
that,
= k(b,a)
a.e.
on
A7 .
that
So it f o l l o w s
138
Changing
the role
(13)
0
and
Re(i/P(0,a;b))
It is easy b E 41 on
of
to
= Re(P(a,0;b))
see that
satisfies
both
a, we get
P(0,a;b) (12)
: i/k(b,a)
is r e a l
and
(13).
and
Hence
a.e.
on
A I.
is e q u a l
to
P(0,a;b)
= k(b,a)
k(b,a),
when
a.e.
41 . (d)
Let
f
is r e s o l u t i v e
be a b o u n d e d
by T h e o r e m
measurable
(14)
G[f;~(a)](Z)
for a l m o s t
every
E A(a).
~ E L(a).
In v i e w
of
(c),
to the
we look
parametrization
Of c o u r s e we h a v e
at the
gible on
the
This
A(a)
and
the
Let
u
5D).
every
if
~ = he
according
we h a v e
= 8
the
Let set
Theorem
eonsequenee
A'(a) A'(a)
of
z:
(a) and
6A to m u l t i p l i c a t i v e
be an l.m.m,
Then
the
of b o u n d e d
following
be the
set of
has
a dm a - n e g l i Z ÷ b£ is o n e - t o -
(d).
analytic
[]
functions,
we
~(b)
exists
a.e.
on
A I.
exists
a.e.
on
A(a).
(c)
~(b~)
: ~(~)
We
set as and
by C o r o l l a r y now
a.e.
in Ch. UQ 4B, that
IV,
for
~ @ A(a).
4B
v = log u,
= exp(Vq). Ch.
on
R says
on
R
(see
Then
Ul
v i = Pri( v), = i
and
and
v
Vq
u = UQ
: prQ(v) , a.e.
on
IV.
v > 0.
So
=
ing t h e o r e m
characteristic
hold:
~(~)
Suppose
(16)
for a l m o s t ~ ~ A(a)
: 8
correspondence
(a)
harmonic
every
Then
£ = £8" Then
is an i m m e d i a t e
Applying
u I = e x p ( v i) &l
with
holds.
is true
f0(~)
in IA.
(b)
Proof.
it
following
Theorem. II,
(15)
in
Then
A'(a).
6B.
Ch.
Z E A(a)
complement
(e)
get
every
for w h i c h
~(a).
: f(~).
G[f0;~(a)](bz)
E A(a)
one
(14)
for a l m o s t
function
mentioned
(15) for a l m o s t
on
= f(£)
G[f;{(a)](b~) In p a r t i c u l a r ,
function
4B and we h a v e
by T h e o r e m
v. i
5B,
Ch.
II,
> 0 =
the
that ~q(~)
> 0. q
: Oq(b~)
Since
=
statement
v
is q
(b) of the
preced-
139
for almost every
£ E A(a).
On the other hand, we set
# £) = lira sup v i (z(~;a)) vi(b for
£ e A(a).
Since
v. > 0, we have
v'#(b£ ) l
> 0 = 0i(b ~)
last equality sign being true by T h e o r e m 4B, Ch. IV. bounded l.a.m, fined by
h
h = exp(-vi . - v q ) and denote by q the line bundle deThen we take any nonzero l.a.m, k < i,
(Ch. II, 2C).
whose line bundle is
q-i
(Theorem 2B, Ch. V).
We set
0
and
Vq'
This is possible in view of Widom's theorem - l o g k = v i' + v'q
~q(£)
for almost every Since
with
v'i : P r i ( - l o g k) =>
pr Q (-log k) => 0, and see as above that
=
(17)
h
and
7(£) = f(b£)
almost every
: Q'(b~)q
Z 6 A(a). k
c o r r e s p o n d to m u t u a l l y inverse line bundles,
there exists a nonzero have
a.e., the
We look at the
f 6 H=(R)
such that
for almost every
hk : IfI
£ E A(a).
on
R.
We thus
This means that for
£ 6 A(a) lim h ( z ( ~ ; ~ ) ) k ( z ( ~ ; e ) )
exists and is equal to
(18)
If(m)l
: If(bm)l =
exp(-Qq(b~))exp(-~'(b~))q
by means of Corollary 4B, Ch. IV. almost every
: ~(bm)~(bm)
From (16) and (17) follows that,
for
£ E A(a), lim e x p [ - V q ( Z ( ~ ; ~ ) ) - v'(z(~;~))] ~+0 q
exists and is equal to
exp[-vq(b£) - 0~(b£)]
~ 0.
Therefore
lim exp[-v.(z(~;e)) - v!(z(£;e))] ~+0 1 1 exists
and
E A(a). value
is
equal
On t h e
to other
If(b~)[expEOq(b~) hand,
since
+ O~(b~)]~
v.
1
and
v!
1
for are
almost
(18) is m a j o r i z e d by lim inf e x p [ - v i ( z ( ~ ; ~ ) ) ] ~+0
Combined with
every
nonnegative,
: exp[-v~(b£)] $ i.
(18), this gives
i ~ If(b~)lexp[0q(b£) + 0~(b£)] ~ exp[-v~(b~)] ~ i.
the
140
Hence, to
v~(b~)
0
: 0
for a l m o s t
a.e., every
which means ~ E A(a).
that
on
A(a).
This e s t a b l i s h e s
The g e n e r a l to the p o s i t i v e
7.
Boundary 7A.
R
Behavior
Let
R
be a r e g u l a r
with vertices
in the M a r t i n
We d e n o t e
by
our a s s e r t i o n s
parts
of A n a l y t i c
~(a,a')
and is e q u a l
= 0
case can be s h o w n by a p p l y i n g and the n e g a t i v e
exists
Thus
~'(£)z = Oi(b~) a.e.
~i(~)
of
when
log u $ 0.
the a b o v e
log u.
consideration
[]
Maps
PWS.
We first d e f i n e
boundary
the set of
41 .
e E [0,
Let
2~)
Stolz r e g i o n s
a, a' E R
satisfying
in
be fixed.
the f o l l o w i n g
conditions: (i) (ii)
~8 E A(a); (~I~¢)(~)
exists
and
is d i f f e r e n t
from
0
for
6 =
~-l(exp(ie)); (iii)
both
P ( a , a ' ; Z 8)
and
P ( a , a ' ; b 0)
exist,
are f i n i t e
and
satisfy P(a,a';~8) (iv)
both
l i m i t s at
e ie
respectively, Moreover,
: P(a,a';be)
F0 o ~-i
where
(F 0 o ¢ - l ) ( e i e )
F0(z)
and
and
have nonvanishing
(F 0 o % - i ) ( e i 8 )
= F(a,a';z)
F 0 o ~-l(w)
~
A(a)
and
and
and
Fl(Z)
with
~
were
were g i v e n
and
finite radial
(F I o % - I ) ( e i 8 )
= F(a,a';z)P(a,a';z).
F I o %-l(w)
respectively,
S(eie;~,p)
statements,
F(a,a';z)
by
(F I o ~ - l ) ( e i S ) ,
through any Stolz region
z),
FI o ¢-i
w h i c h we d e n o t e
the f u n c t i o n s
In t h e s e
and
: k(be,a')/k(bs,a) ;
tend uniformly
as
w
tends
to
to e ie
0 < ~ < 7/2. defined
in 5B.
in 3A, w h i l e
Our p r e v i o u s
P(a,a';
observations
s h o w the f o l l o w i n g Lemma.
The
7B. included
set
Let
set
D(a)
This m a y be c a l l e d be .
We c o n s i d e r (Theorem
complement
in
[0, 27).
any Stolz r e g i o n
3D), w h e r e
0 < ~ < 7/2
S(eiQ;e,p) and
0 <
set S(bs;~,Pia)
point
has n e g l i g i b l e
e E ~(a,a').
in the
p < i, and
~(a,a')
: S(be;~,p)
a Stolz r e g i o n
To see this,
we d e n o t e
in by
= %-l(s(eie;~,p)). R
if it c l u s t e r s e(be,e)
the
o n l y at the
set of c l u s t e r
141
points
in
A
of the
is i n d e p e n d e n t in the
proof
Lemma.
set
of the
of T h e o r e m
For any
S(be;e,p).
choice
We take
a fixed
Then
Lemma
negligible
7A shows
we have
that
the
equation
with
distinct
= b 8.
any
in
A1
of
A1
(19)
Namely,
a • R
with
number
one
8 • ~l(a)
(20)
r(a~z) a unique
e(be,~) to t h a t
solution
z
(Ch.
consists
set
subset
of
[0,
27)
For any p o i n t is d e n s e
in
Martin
used
III,
2B),
of a s i n g l e We thus
we
Al(a)
be the
Al(a)
is a m e a s u r a b l e
0 < p < 1 and
such
e(a;z)
~'(R,a)
that E d
mod
for any
b8
have for
b8
subset
For any
exists
the
see
set of p o i n t s
following: there
should
point
set
the
R, we
have:
let
0 < ~ < 7/2
b' E
functions
the
satisfies
in
and
and
any
: c
R
Since
0 < ~ < 7/2.
and
of
A
with
and
with
Since a' • R.
proportional
Then
A
8 • ~l(a).
a' • A.
be f i x e d
p = p(b@,~)
similar
a' • A}.
e(be,e) ~
8 • Ql(a).
of d x - m e a s u r e
Al(a)
has
set
any
let
for all
never
subset
is a m e a s u r a b l e
Now
holds
are
the
and
Let with
~l(a)
for any
(19)
poles
e • ~l(a)
Theorem.
that
dense
: n{Q(a,a'):
complement.
e(bs,~)
see that
= k(bg,a')/k(be,a).
countable
~l(a)
with
to
By an a r g u m e n t
we h a v e
k(b',a')/k(b',a)
7C.
It is easy
p.
5B we h a v e
b' • e(bs,e)
(19)
b'
of
b8 •
a positive
system 2~
pair
of n u m b e r s
(C, d)
satisfying (21)
p £ c < i
where (20)
r(a;z) and
and has
cluster
We call
the
set
in
R
region
lows.
a). Let
there
S(ei8
point
Then,
a positive
;~l,~2,p)
set of
i(d-8)
in
(or, be this
= {z • ~:
z
for the
we d e f i n e d
system in 7B,
A. more
exactly,
and angular definition
for any number
£ ~,
solutions
S(be;~,p) , which
be
vertex
generalize
8 E ~l(a). exists
set
S(bs{~,p) with
We can
The
to the
one
Stolz
-~ £ a r g ( l - c e
: exp(-g(a,z)). is e q u a l
only
origin
7/2,
(21)
and
~i' p,
~2
measure
of S t o l z with
0 < p < i,
~I £ a r g ( l -
S(be;~,pla))
ze
2~
-i8
(with
regions
-~/2 such
a
as fol-
< ~i < ~2 < that
) £ ~2 }
the
set
142
is i n c l u d e d
in the r e g i o n
S(be;~l,~2,pia) Then,
S(bs;~l,~2,p)
D(a).
We set
: S(bs;~l,~2,p)
has a u n i q u e
cluster
v i e w e d as a k i n d of S t o l z r e g i o n s . choices
of
7D.
a
We can e x t e n d
describe
some r e s u l t s
in C h a p t e r
space
X.
Let
Let
~i' ~2
-~/2 < ~i < ~2 < 7/2,
p
the
with
intersection 0 < p < i.
Theorem.
surface
subset ~ A',
7E. points
Theorem. plane
of
R'*. A
If
A
Let
fV(b)
R, t h e n
side is t a k e n
f
f
fV(b)
for a l m o s t analytic
the
every
m a p of
for all p o s s i b l e
b E Al(a). R
of
set of
fv, we d e f i n e
such that
e ie
Then one.
exists
into a R i e m a n n R'
A'
and
b E Al(a)
A2(a)
a
for w h i c h
m a p of
is a m e r o m o r p h i c = {f(b)}
for i n s t a n c e
R
such that
according b
in
function
for a l m o s t
the
into the e x t e n d e d
w0 E [
every
to be the is t h i n at
set of b0
is seen to be a s u b s e t
is r e p e a t e d
for a l m o s t
A2(a)
R \ ¢'(R;a)
We t h e n h a v e
a point
summation
= {~(b)} If
for any
b E Al(a).
compactifieation
be an a n a l y t i c
If t h e r e the
into a
< '~i < ~2 < ~/2},
every
denotes
e E ~l(a)
of d x - m e a s u r e
¢.
We w i l l
is d x - n e g l i g i b l e .
is thin at
Corollary. on
is n o n e m p t y
a metrizable
then
w 0} < ~, w h e r e then
for a l m o s t
be a n o n c o n s t a n t
with
Al(a)
set,
-~/2 < ~i < ~2 < ~/2}.
R'*
R
put
In o r d e r to speak of be
D w \ D(a) set
on the r i g h t - h a n d
f~(b)
[CC].
S(b;el,e2,p)
and
: U{f(b;~l,~2):
R',
f~(b)
so that
b C Al(a)
fV(b)
f
of a n a l y t i c
m a p of
-~/2
(a)
polar
behavior
= N{f(b;~l,~2):
Let
(b)
distinct
= n Cl(f(S(b;~l,e2,p))) ,
We f u r t h e r
~ f~(b)
and m a y be
Stolz r e g i o n s .
fA(b)
f^(b)
Corollary.
A
and C o r n e a
be fixed,
Take any
f(b;~l,e2)
in
be a c o n t i n u o u s
a C R
S(b;~l,e2,pia).
where
on b o u n d a r y
f
always means with
be
equivalent
19 of C o n s t a n t i n e s c u
a few of t h e m here.
compact metric
point
It is not h a r d to see that
give r i s e to e s s e n t i a l l y
maps a p p e a r i n g
= ¢-l(s(eie;~l,~2,p)).
and
of the
following complex
[{g(a,z):
f(z)
to m u l t i p l i c i t y ,
~(f) n A 2 ( a ) . of b o u n d e d
every point
characteristic
b C A2(a).
=
143
NOTES The general d i s c u s s i o n in §i on Green lines and the c o r r e s p o n d i n g Dirichlet p r o b l e m is adapted from Brelot and Choquet Sario and Nakai
[6].
See also
[62; pp. 199-209].
The results
in §2 are due to Parreau
were r e d i s c o v e r e d by Hasumi
[52], a l t h o u g h some of them
[17, 18].
The B r e l o t - C h o q u e t p r o b l e m - - t h e main topic of §3--can be found in Brelot
[5;
§14].
The result in this section were obtained by Hasumi
[17, 18], except T h e o r e m 6A, due to Hayashi in Subsection
[27].
(c).
The latter is an important c o m p l e m e n t
Stolz regions on PWS's and related things sketehed
7 are d i s c u s s e d at length in Hasumi
contains a cluster value theorem on PWS's.
[19].
Niimura
[48]
CHAPTER
The this
Cauehy
chapter.
ity w o u l d them
be a m a t t e r
in a f o r m m o r e
far f r o m verse
being
Cauchy
teristic direct
of
surfaces
Cauehy
theorem--is In direct
Among
other
weak-star
closed
Unless
(= PWS),
§i.
THE
Statement IA.
a E R of
INVERSE
be
Let
the
utmost
and
prove
shall
of
of the
We
algebra
IX.
§2 the
which
are
the
integral
in Ch. in
of
charac-
hand,
state
variation,
the
surfaces
Cauchy
again
is
in-
is true
given
H~(dx )
in
for
§3.
is a m a x i m a l
L~(dx ).
stated,
R
is r e g u l a r
CAUCHY
that
The
is i n d e e d
On the o t h e r
A few a p p l i c a t i o n s
show
for any
this
theorem.
its w e a k e r
surface.
we
IX,
of
problem
analysis.
form holds
be d i s c u s s e d
Cauchy
So the
detailed
generalization
and w i l l
inverse
denotes
in the
a surface
sense
of P a r r e a u - W i d o m
of p o t e n t i a l
theory.
THEOREM
R
be a r e g u l a r and
let
{Zl,
the
critical
to m u l t i p l i c i t y .
We use
PWS w i t h z2,...}
points the
of
j:l
(a)( z)
: exp
S (a)
Green
function
be a f i x e d
g(a,-),
following
s(a)(z) : [ g(z,zj) g
situation.
rather
valid-
of R e s u l t s
fixed
Z(a;R),
thinking
type.
subalgebra
which
we are
of P a r r e a u - W i d o m
otherwise
type
in fact,
in Ch.
valid
in
their
see
shall
be d i s c u s s e d
sense,
But,
deserves
will
classical
general
Riemann
things,
inverse
in its m o s t
theorem
any h y p e r b o l i c
its
in the
As we
theorem--an
§i we p r o v e
and
taken
THEOREMS
to o u r p r e s e n t
and
not a l w a y s
Cauchy
theorem were
fitted
type.
CAUCHY
of t r i v i a l i t y .
evident
theorem
Parreau-Widom
i.
integral If t h e s e
VII.
which
(- s(a) (z)),
= exp(-s(a)(z)
we r e p e a t
notations:
s(a)(z) : '
g(a,z).
enumeration
n
[
g(z,zj),
j:n+l gn(a)( z)
= exp ( - s(a) (z))
- i[(a)(z))
Let
of m e m b e r s
according
145
and s(a)(z) n where
~
denotes
tion
[(a)
= 0.
lytic
function
which
S (a)
IB.
: exp(_s(a)(z) _ i[(a)(z)), n n
the h a r m o n i c S (a)
on
S (a))
S (a)) d e f i n e s n
Our o b j e c t i v e
in this
of
u
normalized
{ (a) over
section
_(a)) %n
(resp.
is to p r o v e
and w i l l be p r o v e d
Theorem.
be fixed.
u E LI(dx)
S
If
line b u n d l e
the f o l l o w i n g ,
Cauehy theorem
a E R
the
ana-
R.
is c a l l e d the i n v e r s e Let
by the c o n d i -
is a b o u n d e d m u l t i p l i e a t i v e
We d e n o t e n by
R.
(resp.
conjugate
(resp.
h(b)u(b)k(b,a)dx(b)
which
in 2D below.
satisfies
0
AI for any and on
h, m e r o m o r p h i c
h(a)
R, such that exists
an
lhig (a)
f E HI(R)
is b o u n d e d
such that
on
R
f = u
a.e.
AI . IC.
theorem
By the way we w i s h to state w i t h o u t for an a r b i t r a r y
Theorem. Rt
on
= 0, t h e n t h e r e
Let
R
be a (not n e c e s s a r i l y
the r e g u l a r i z a t i o n
gt(a,z)
be the G r e e n
ical p o i n t s according
in
Rt
of
R
function
for
morphic
on
then t h e r e
If
R, such that
This f o l l o w s
an
regular) and
PWS w i t h o r i g i n
Z ( 0 ; R t)
z ÷ gt(0,z),
{gt(z,w):
satisfies
h(0)
f E HI(R)
easily
Cauchy
3B, Ch.
V.
0
the set of c r i t -
w h i c h we r e p e a t
= 0
w e Z(0;Rt)})
fA I hud X = 0
and
Ihlg t(0)
such that
from Theorem
u = f
3B, Ch.
for a n y
is b o u n d e d a.e.
on
h, m e r o on
R,
A I.
V and the p r e c e d i n g
the-
orem.
2.
P r o o f of T h e o r e m 2A.
To p r o v e
w h i c h we state
IB
Theorem
in t h r e e
and
Let
Set
u C LI(dx )
exists
Rt
of the f u n c t i o n
to m u l t i p l i c i t y .
z E R.
the i n v e r s e
in the s e n s e of T h e o r e m
g t(O)( z) : e x p ( - [ for
proof
PWS.
IB we n e e d
lemmas.
some p r e l i m i n a r y
The f i r s t
observation,
is the f o l l o w i n g
146
Lemma.
^(a)( g b)
Proof.
Since
= 1 s(z)
R,
F. R i e s z ' s
u
is a n o n n e g a t i v e
orem Ch.
5A,
Ch.
III,
is a p o s i t i v e
(Theorem
harmonic
III,
s
A1
and
by
fA I s ( b ) d b d X ( b ) .
from
s
part
n : I,
s - s n.
Since 2, . . . .
finite
except
at
zj,
u = 0
on
and
consequently
R
2B.
Next
we
u = his]
in Ch.
Lemma.
Let
V = {I~I
fixed.
Then
there
VI,
< i}
exists
on
we
~',
Proof.
We c o n s i d e r
in Ch. {an:
VI,
~'
= ~.
and
~", h
on
a constant
on
R
a.e.
on
A I.
C
disk
such
h(% , ) - h(~")
/el < 1/4}
is g i v e n and
his]
S'n :
= h[Sn ]
Since
except
on
at
for
s(z)
is
z]..
Hence
[]
further
gn(~",z)
in
{Rn:
any
let
a
be
z • R \ CI(V).
n = i,
tending
to
0
that
CI(V)
~ R I.
Green
functions
for any r e a l
2,...),
decreasing
be the Then,
and
< CI~' - ~"I
for a s t r i c t l y
numbers
R
that
and
exhaustion
of p o s i t i v e
Rn,
so
2, . . . .
zero
be a p a r a m e t r i c
respectively.
h[s]
a.e.
function
Rn = R(en,a)
and
exists
5B.
a regular
We a s s u m e
s
5B,
real-valued
Sn : s(a)n and
By The-
by T h e o r e m
function
set
on
= ~g(a',z)/~g(a,z),
= {~ • V:
i.e.
2,...)
gn(~',z)
function
(1)
5B,
n = i,
Z(a;R) let
~" e V'
and
that
= 0
IP(a,~'; z) - P ( a , ~ " ; z ) I g (a)(z) for a n y
R
n = i,
to
function
s = u + U, w h e r e
as an e x t e n d e d
III,
hisS]
£ Sn,
the
that
is a p o t e n t i a l .
harmonic
s = 0
investigate
already
U
Ch.
2,. ..
converge
P(a,a';z) appearing
5D,
is a p o t e n t i a l ,
sn
and
function
of the
n = i,
Thus,
superharmonic
I) shows
is c o n t i n u o u s
Theorem
For
Ch.
function
Since
quasibounded
s n'
6F,
is a W i e n e r
= u.
it f o l l o w s
the
A I.
= s(a)(z)
theorem
h[s]
function,
a e. on
with
Let
~, for
as d e f i n e d sequence 3R(~n,a ) N
~" E V' Rn
quasibounded
with
and poles
harmonic
we have
i ~a - -~-~-~ 1
h(z)[
i~gn(~' ,z) ~gn(~",z)] ~g(a,z) ~g(a,z) ] 6 g ( a , z ) .
n
Put
h+ = h v 0
quasibounded
and
h-
harmonic
= (-h) v 0.
functions
on
Then, R
n
.
h+
and
By the H a r n a c k
have c(r)-i
h-
~ h + ( ~ ' ) / h + ( ~ '') S c(r),
are
positive
inequality,
we
147
where
the
r =
I%' - ~"I
function
h
.
and
Ih(¢')-h(¢")l
(2)
c(r)
= (3 + 4r)/(3 - 4r).
The
same
is true
of
So
~ Ih+(C ' ) - h + ( ¢ ' ' ) ]
+ Ib-(C')-h-(C")I
< 8 r ( h + ( % '') + h - ( ~ " ) ) ~gn({",z) )h(z) I ~ - ~ [ ] ~
: 8r(- 1----) I ~R 2~i
6g(a,z)
n
8rl(
-i---) 2~i S~R
Ib(z)i~g(a,z), n
where
is
1
Combining
a constant
(i) and
(2),
depending
~gn(~',z) ~g(a,z)
~R
n
.
We
v(z) v < i.
It f o l l o w s
(a)
~R
.
and
R, and
not
on
n.
function
on
R
~gn(~",z) I 6g(a,z) ~ 81r
(z)exp(-g(6',z)-
Since
the
g(~",z)).
of a m u l t i p l i c a t i v e
analytic
that
6gn(~',z) 6g(a,z)
(3)
on
= g
is the m o d u l u s
Then,
V
a,
set v(z)
with
on
we h a v e
] on
only
-
left-hand
6gn(~",z) 6g(a,z) member
.v(z)
of
(3)
)
so that
~ 81r
is the m o d u l u s
of a m u l t i -
n
plieative
analytic
function
remains
to be v a l i d
when
on z
CI(R
ranges
n over
R n.
IP(a,{';z) - P ( a , ~ " ; z ) I v ( z ) on
R.
Since
CI(V')
is a c o m p a c t
the
subset
inequality
Letting
sign
n ÷ ~, we h a v e
~ 81r
of
V, the
set of f u n c t i o n s
exp(g(~' ,z) + g(6 " ,z)) with
~',
~" E V'
R \ CI(V).
Hence,
2C.
Lemma.
R \ Z(a;R) I~)
< 1/4},
and
forms there
Let J
where
any
a uniformly exists
V
a desired
be a p a r a m e t r i c
closed
a e R
bounded
rectifiable
is fixed.
Pj(z)
constant
on the C.
disk whose curve
Set
= I P(a,~;z)d~ J
family
region
[]
closure
contained
in
lies
in
{6 E V:
148
for
z E R \ (Z(a;R) U CI(V)). (a)
Pj
a n a l y t i c a l l y to (b)
Pj(a)
(c)
Pj
R \ (Z(a;R) U C I ( V ) )
and can be extended
R \ Z(a;R). = 0.
is m e r o m o r p h i c with poles in
ity such that (d)
Then we have the following:
is h o l o m o r p h i c on
IPjig (a)
Pj(b)
Pj(b)
counting multiplic-
is bounded.
exists a.e. on
(4)
Z(a;R)
= I
A1
and
(kb(~)/kb(a))d%
a.e. on
A I.
J Proof.
Since the poles of
Z(a;R),
the function
1/4}).
if
Pj
P(a,{;z)
~ ~ ~', where
in
~'
h(~,~')
~c,h(~,~')
with
is symmetric
in
singularity at
~
and
~', is h a r m o n i c
~' = ~.
So we have
= -(~ - ~')-id~' + 5~,h(~,~'),
is an analytic d i f f e r e n t i a l
in
~' E V.
For
V.
can be c o n t i n u e d a n a l y t i c a l l y to the whole
regarded a n a l y t i c on Since
5g(a,z)
are c o n t a i n e d in
R \ Z(a;R).
the function
V, so that it can be
This proves the statement
has a pole at
Z(a;R)
Hence,
a,
Pj(a)
= 0.
counting multiplicity.
(a).
The poles of Since
J
pending only on
a,
J
and
(S) R.
In fact,
let
a
R, where
c(a,~)
is fixed and
the fact that say, when
~
~
~ E J. (a)
depends only on
a
I~I < i/4},
range over
J
5B,
~ c(a,~)e g(~'z) and
~
and is b o u n d e d when
ranges over any compact set, e.g.
z
de-
~ e
Then, as we saw in Ch. VI,
(z)IP(a,~;z)I
J ~ {~ E V: and
c
with
IPj(z)Ig(a)(z)
g on
R
Pj
is compact,
the d i s c u s s i o n in Ch. VI, 5B shows that there exists a constant
on
~' E V
1/4 < I~'I < i, we have
the r i g h t - h a n d m e m b e r being analytic t h r o u g h o u t Pj
{~} U
I~I
: - l o g I~- ~'I + h(~,~')
and has a r e m o v a b l e 6~,g(c,~')
where
R \ (Z(a;R) U {~ E V:
~, ~' @ v, then g(~,~')
for
are c o n t a i n e d in the union
is analytic on
and
g(~,z)
J.
In view of
is bounded above, by
R \ {z' e V:
Iz'l < 1/2},
c'
149
respectively.
Therefore
g(a)(z)IPj(z) I ~ {max~ej where
z
ranges
o v e r the o u t s i d e
c(a,~)}{length(J)}.e
of
{z' • V:
Iz'I
o~
,
< 1/2}.
On the
o t h e r hand, Pj is a n a l y t i c on CI(V) and so is b o u n d e d there. (a) g IPjI is b o u n d e d e v e r y w h e r e on R, w h i c h shows the i n e q u a l i t y Hence
(5).
(c) is proved. The i n e q u a l i t y
of b o u n d e d a.e.
Thus
on
(S) also
characteristic,
A1 .
such
Pj
logiPjI
is a m e r o m o r p h i c
• SP'(R),
In o r d e r to show the e q u a t i o n
a fixed parametrization continuous
shows that
i.e.
on
J
of the c u r v e
for any f i x e d
J.
(4),
Since
and thus
let
y:
function Pj
exists
[0, I) ÷ J
a' ÷ P ( a , a ' ; z )
z • R \ (Z(a;R) U C I ( V ) ) ,
be
is
we h a v e
for
z,
Pj(z) where
n = lim ~ P ( a , ~ n , j ; z ) ( ~ n , j - ~ n , j _ l ), n -~ j=l
~n,J~ = y(j/n),
be a m e a s u r a b l e
subset
b • 4', we h a v e every
n
and
and Lemma
j = 0, i,...,
n-l,
of
X(A I \ A')
-g(a)(b) j.
41
with
= i
and
S u c h a set
and
~n,n = ~n,0"
P(a,~n,j;b)
&'
exists
= 0
Let
such that,
A'
for each
= kb(~n,~)/kb(a)j
in v i e w of T h e o r e m
for
6A, Ch. VI,
2A.
Take any exists
an o p e n
eluded
in
b • &' set
R \ CI(V)
D
Then,
for any
• G(b)
0 < c < i
(see Ch.
n and
III,
4A)
and any
n, t h e r e
such that
D
is in-
n
Ig (a) ( z ) P ( a , ~ n , j ; z ) - k b ( ~ n , j ) / k b ( a ) I < for any
z • Dn
and any
j = i,...,
n.
Thus,
n Ij=l ~ g(a)(z)P(a'~n' j
;z)(~ n
'J - ~n'j-l)
for
z • Dn,
n kb( ~ ~n,~ ) j=l kb(a) (~n,j - ~n,j-l)I
e length(J). We take an i n t e g e r
nO > 0
in such a w a y t h a t
contained
in a disk of d i a m e t e r
Put
Jn,j
= y([(j-1)/n,
no.
Then,
of L e m m a f I
since
j/n]),
I~ - ~n,jI
for e a c h
j = i,..., for each
n.
y([(j-l)/n, n ~ nO Let
~ • Jn,j'
and
j/n])
-
z • Dn
with
we have,
n [ g(a)(z)P(a'~n,j;z)(~n,j j:l
is
j = i,..., n =>
in v i e w
2B,
g(a)(z)P(a'{;z)d% J
< g
g
- 6n j-i )I '
n.
150
n If
{g
_-< ~
j=l
(a)
(z)P(a,%;z) - g ( a ) ( z ) P ( a , 6 n , j ; z ) } d ~
I
Jn,j
Cs.length(J). Since for
a' + kb(a')
is c o n t i n u o u s
on
R, there
exists
an
n kb(~n, j ) l kb(~) I ~ kb(a ) ( ~ n , j - ~n,j_l ) - j k b ~ d ~ I j=l J Hence,
for
n => max{no, - f
Ig(a)(z)Pj(z)
n I}
a.e. ^(a) g
and is equal
AI
= i
a.e.
on
2D.
Proof
such that,
AI,
z E R.
f
be any p a r a m e t r i c
their
coordinate
fiable
curve
and Lemma
e-length(J) + Ca-length(J)
to
IB).
To prove
f = I J
disk
Theorem
contained
in
+ e.
g(a)pj
By Lemma
exists
2A we have
equation
(4).
[]
R.
Let
IB, we set
u(h)k(b,z)dx(b) AI
included are
for
the d e s i r e d
is a q u a s i b o u n d e d
variables
function
fj ( k b ( ~ ) / k b ( a ) ) d ~ .
so that we obtain
(Theorem
Then,
<
< E.
z E Dn, we have
the fine b o u n d a r y
f(z) for
for
kb(~ )
shown that
on
and
j kb--~7 d~I
Thus we have
V
nI
n > nl,
in
harmonic
R \ Z(a;R),
identified.
{z E V:
Let
IzI < 1/4}.
function
on
in w h i c h
points
J
be any c l o s e d
Then the Fubini
and recti-
theorem
2C show that
SJ f z dz fA I ifJ k--~--~ dz ]u ( b ) k ( b , a ) d x ( b ) = S
Pj(b)u(b)k(b,a)dx(b)
= 0.
AI By the M o r e r a tinuous hence monic f = U
on f
theorem
R, every
f point
is e v e r y w h e r e
majorant, a.e.
on
so that At.
is a n a l y t i c
[]
in
on
Z(a;R)
holomorphic f E HI(R).
R \ Z(a;R).
is a r e m o v a b l e
on
R.
Since
f
is con-
singularity
Clearly,
In view of T h e o r e m
Ifl 5E,
and
has a harCh.
III,
151
§2.
THE D I R E C T
3.
CAUCHY THEOREM
Formulation 3A.
of the C o n d i t i o n
First we e x p l a i n w h a t we m e a n
To do this,
we b e g i n w i t h two
Lemma.
Let
istic.
Then
f
Proof.
We m a y
be a m e r o m o r p h i c f
is a q u o t i e n t suppose
by d e f i n i t i o n , positive
simple
that
f u n c t i o n on
of b o u n d e d
f
uI
and
R
u2
SP'(R)
character-
functions
identically.
As we saw in Ch.
in
C a u c h y theorem.
of b o u n d e d
holomorphic
does not v a n i s h
log IfI E SP'(R).
elements
by the d i r e c t
lemmas.
II,
such that
on
R.
We have,
5A, t h e r e
exist
log If[ : u 2 - u I.
Thus we h a v e f : c . e x p ( - u I - i ~ l ) / e x p ( - u 2 - i~2) , where
c
is a c o n s t a n t
of m o d u l u s
functions
exp(-uj - i~j),
j = i,
say.
h
element
Let
of W i d o m ' s and
be a n o n z e r o
theorem
(Theorem
f2 = h ' e x p ( - u 2 3B.
Lemma.
Ifig (a)
i~2)'
If
f
has a h a r m o n i c
belongs
to
Proof.
The h y p o t h e s i s
by L e m m a fl/f2
with
fj
Since
~(a)
is a h a r m o n i c 5E, Ch.
3C.
(DCT a)
If
V).
on
f
is s i n g l e - v a l u e d ,
the
same line b u n d l e ,
A~(R,~01),
which
Setting
is a m e r o m o r p h i e
shows t h a t
exists
function f
[0
i~l)
f = fl/f2.
on
R
exists
the
because
fl : e h ' e x p ( - u l -
expression
R, t h e n
values
= i
a.e.
majorant III,
so is
f
is of b o u n d e d
of b o u n d e d
By T h e o r e m
analytic
5E,
Ch.
a.e.
on
AI
on
AI
by L e m m a
of
[]
such that a.e.
on
AI
and
characteristic.
functions,
III,
both
and t h e r e f o r e
Iflg (a)
f
2A, we h a v e
Since
u
e.g.
fl
and
exists
So, f = f2
a.e.
on
IfI ~ u, w h e r e
is s u m m a b l e
a g a i n by
i, as was to be proved.
We m e a n by the d i r e c t
a harmonic
in
Ch.
majorant
bounded.
A I.
following
2, g e n e r a t e
we get a d e s i r e d
3A, it is a q u o t i e n t
fine b o u n d a r y
Theorem
Since
LI(dx).
have
u
2B,
one.
Cauchy
theorem
for a point
a E R
such that
Iflg (a)
the
statement: f
is a m e r o m o r p h i c
majorant
on
function
on
R
R, t h e n
f(a)
: I
f(b)kb(a)dx(b)"
has
152
As
indicated
theorem that,
for a PWS,
a n d so w e m a y ious
4.
The
Cauehy
Although
statement
(DCT)
the remaining
part which
a E R {an:
n : i,
function
n = i,
2, . . . .
Un: I R n = R. Lemma. u
does
Let
on
R
g(a,.). Rn
We a l s o
set
hold
in Ch.
n
}
a shown
for a l l
a E R
a.
Var-
X.
for P W S ' s ,
we d e n o t e sense
by
tending
do n o t
there
Riemann R
theory.
decreasing
to
zero
contain
is a
surface.
In
any hyperbolic
of p o t e n t i a l
a strictly
numbers
Rie-
Let
sequence
such
that
any critical
the
points
set
R : R(~ ,a) : {z E R: g ( a , z ) > ~ }, n n n are Jordan regions, C I ( R n) ~ Rn+ I and 6g(a,z)
be a c o n t i n u o u s some
be g i v e n
always
choose
= e
We
or false
be
Type
in the
and
it w i l l
to a n y p a r t i c u l a r
for a n y h y p e r b o l i c
section,
g(a,z)
Then,
F
for
not
of p o s i t i v e
{z E R:
of the
of W e a k
is r e g u l a r
2,...}
curves
will
(DCT a ) is n o t
chapter
true
referring
(DCT)
is v a l i d
be f i x e d a r b i t r a r i l y
level
statement
simultaneously
to
of this
the
In the n e x t
without
Theorem
which
mann
surface,
(DCT)
equivalent
Direct
4A.
introduction, on PWS's.
(DCT a) a r e
write
conditions
weaker
in t h e
but a c o n d i t i o n
= 2(~g(a,z)/~z)dz.
Wiener
quasibounded
function
harmonic
on
R
function
such that
u
on
R.
IFI
T h e n we
have
(6)
- lim ~ n+°°
Proof.
We m a y
4B in Ch. have be
if
F(z)6g(a,z)
suppose
llI,
F
F
that
exists
In o r d e r is b o u n d e d . by T h e o r e m
5D,
Ch.
h[F]
is n o n n e g a t i v e . AI
a.e.
convergence is b o u n d e d
III,
and
By L e m m a
5C a n d
is m e a s u r a b l e . on
£i"
Since
Since
~
Theorem we
is s e e n
to
summable.
to s h o w t h e Then
F
a.e..on 0 ~ F ~ G
is a l s o
F(b)kb(a)dx(b).
&i
O ~ F ~ u, we h a v e
sununable,
f
=
~ Rn
of
(6), w e f i r s t
and afortiori
assume
that
F
is q u a s i b o u n d e d .
So
we h a v e
h[F]
= I
F(b)kbdX(b)" A1
By T h e o r e m for any
5A,
Ch.
III,
(7)
h[F]
outside the
there
exists
a potential
U
on
R
such
that,
~ > 0,
a compact
proof
subset
of T h e o r e m
5D,
- eU < F < h [ F ]
K
of
Ch.
Ill,
R.
+ sU
Since
shows
that
F
is f i n i t e
we m a y
assume
everywhere, U(a)
< ~.
153
Given
any
~ > 0, we take
inequality
n
(7) w i t h r e s p e c t
differential
so large to
-(2~i)-16g(a,z)
hEnCa) : I
d~n, to
Ks =C R n
that
which
SR . n
and i n t e g r a t e
is the r e s t r i c t i o n
the
of the
Since we have
hEFl
ZR n
AI
and
U(z)d~n(Z)
~ U(a),
I~R n
we c o n c l u d e
that
~Rn Since ting
U(a)
Al
is a s s u m e d
Next we c o n s i d e r F m = min{F, h[F] A m have
to be finite,
m]
the g e n e r a l
is a W i e n e r
and t h e r e f o r e
shown above,
a positive
integer
exists,
Fm(Z)d~n(Z)-
for
n ~ nO.
s > 0, a n u m b e r
Sinee
9
m ~ m 0. < u- u
F(b)kb(a)dx(b)
=
m
5B-(b),
m = i, 2,... a.e.
on
A I.
R, w h e r e
0 < I
llI,
h[F m] =
By the fact we
m = I, 2,...
and any
¢ > 0,
such that
f
Fm(b)kb(a)dx(b)l
< s
and
Fm + 9
a.e.,
there
exists,
for
such that
< I
Fm(b)kb(a)dx(b)
I
u
m
we have
= min{u,
0 ~ F ~ u
m}.
F(z)d~n(Z) - I DR
+ ~ and t h e r e f o r e that
n U m ( Z ) d Z n (z)
r
DR
It follows
Fm(Z)d~n(Z) ~R
n
u(z)dDn(Z) -]DR n
n
< u(a) - (u A m)(a). If we take
Ch.
with
AI
On the other hand, on
m}
is s u m m a b l e m 0 = m0(s)
AI
m
(6) by let-
A1
any
for
the i d e n t i t y
By T h e o r e m
for
for any
n o = n0(m,¢)
~R n
I
case.
function
Fm = min{F,
there
f
F
we have
s ÷ 0.
m ~ m0(s)
and
n ~ n0(m,s) , then we o b t a i n
F-
154
II
F(b)kb(a)dx(b) - I AI
Since
u
implies
F ( z ) d ~ n ( Z ) [ < 2e + u(a) - ( u A m ) ( a ) . ~R n
is q u a s i b o u n d e d , the d e s i r e d
4B.
we h a v e
result.
By the d i r e c t
(u A m)(a)
+ u(a)
as
m ÷ ~, w h i c h
[]
Cauchy
theorem
of w e a k type we m e a n
the f o l l o w -
ing result: Theorem.
Let
..., z I
R
be a r e g u l a r
be any f i n i t e
subset
g0(z) If
f
is a m e r o m o r p h i c
majorant
on
R, t h e n
= exp(on
R
a.e.
on
= I
surface
and let
Zl,
We set
I ~ g(zj,z)). j=l
exists
f(a)
Riemann
Z(a;R).
function
f
(8)
hyperbolic of
s u c h that AI,
has a h a r m o n i c
Iflg o
is s u m m a b l e
and
f(b)kb(a)dx(b)" A1
Proof.
Since
Theorem
4A, Ch.
surface
R
compact
set
z~
and
that
c
R \ K.
IV,
is an l.a.m, shows that
being regular, K
in
go ~ e -i
harmonic bounded
]flg 0
u
R
on
R\ K
on
Re(f)
We then m o d i f y
functions
of T h e o r e m on
R.
(resp.
fl
on
R
Since
with
III,
-
by
X(A I \ N ( f j / u ) )
f2/u = 0
j = i,
the p r e c e d i n g
if
lemma
(fl + i f 2 ) ( z ) 4 g ( a ' z ) 8R n
Im(f))
for
and
is
it is q u a s i function K
on
so as to
By a p p l y i n g
A I \ ~(Re(f)) and
set
We see
f2 ) on the s u r f a c e
n
lim ~ n+~
(resp.
and a
Zl,... ,
R \ K.
c-lu,
on the
f(z)6g(a,z) 8R
on
Re(f)
If21 S c-lu).
fl/u
R, Our
c > 0
is thus a W i e n e r
Im(f))
on
the p o i n t s
]fl ~ c - l u
(resp.
fj = (fj/u)u,
Ifjl S e-lu,
-lim ~ n÷~
that
number
contains
Im(f))
(resp.
function
It f o l l o w s
5D, Ch.
a positive
Since
majorant
is q u a s i b o u n d e d .
in m o d u l u s
G = R \ K, we see that
are n e g l i g i b l e . uous
R \ K.
(resp.
Ifll S c-lu
III, w i t h
on
Re(f)
a harmonic
Int(K)
and is m a j o r i z e d
R \ K.
the p r o p e r t y
exists
So we have
is q u a s i b o u n d e d
on
have a real c o n t i n u o u s
Ch.
there
such that R \ K.
having
u = L H M ( I f l g 0)
R
Lemma
with 5C,
A I \ N(Im(f))
are b o u n d e d j = i,
2, are W i e n e r shows that
2.
continIn v i e w
functions
155
= I
(31+ if2)(b)kb(a)dx(b)
= S
AI
f(b)kb(a)dx(b)' AI
where
{R : n = i, 2,...} is an e x h a u s t i o n of R m e n t i o n e d in 4A. If n n is so l a r g e that R includes K, t h e n f(z)6g(a,z) is a m e r o m o r n phic d i f f e r e n t i a l in z on the c l o s e d r e g i o n C I ( R ) w i t h o n l y one n p o l e at the p o i n t a, w h o s e r e s i d u e is equal to -2~if(a). H e n c e , we get the f o r m u l a
§3.
5.
(8).
[]
APPLICATIONS
Weak-star 5A.
which
(see H e l s o n Theorem.
that
extends
[33],
p.
H~(dx ) Let
algebra
of
s* = 0.
L~(dx )
that
bounded
among weak*
generated
S (a)
is b o u n d e d
on
there
and analytic
closed
and let
by
C
H=(dx ) to
we p r o v e the
on
R.
on
R.
a
function
Since
C
closed f*.
Suppose
is any f i x e d p o i n t
in
B E H~(R)
B
is c l o s e d
in
H ~ ( d x ), we h a v e
I
B(b)u(b)(f*(b))ns*(b)dx(b)
under
such R. such
is o b t a i n e d
~(R,(~(a))-l).
sub-
to s h o w that R
function
u
L~(dx).
on
Such a function in
of
be the w e a k l y *
It is s u f f i c i e n t
a nonzero
element
subalgebras
and the f u n c t i o n
C.
R, w h e r e
exists
and a n o n z e r o
t i o n by f u n c t i o n s
theorem,
in the ease of the unit d i s k
we take any m e r o m o r p h i c
IB(z) I ~ g(a)(z)
tiplying
a fact w e l l - k n o w n
is o r t h o g o n a l
is a PWS,
Cauchy
27).
To see this,
R
of the i n v e r s e
f* ~ L=(dx ) \ H~(dx)
Iulg (a)
Since
H~
is m a x i m a l
s* E LI(dx)
that
of
As an a p p l i c a t i o n
following,
Proof.
Maximality
by m u l -
Thus
Bu
is
the m u l t i p l i c a -
: 0
AI for
n = 0, i, . . . .
each
n = 0, i,...,
hn : B s * ( f * ) n m a p of
R
by T h e o r e m
with
a.e.
By the i n v e r s e a function on
Al"
%R(0)
= a.
7B, Ch.
h
Let Then
n
Cauchy
~R:
D
on
~D. of
there
exists,
for
such that
÷ R
h (a) = 0 and n be a u n i v e r s a l c o v e r i n g
h n o %R E H I ( D ) ,
h n o %R ( O) : 0
and,
III,
(h n o ~R )^ = ( ( B s * ) o S R ) ( f * o
C'
theorem
E HI(R)
Thus
(Bs*) o SR
L~(do)
generated
is o r t h o g o n a l by
H~(do)
and
SR )n
a.e
to the w e a k l y * f* o SR"
closed
Since
subalgebra
f* ~ H ~ ( d x ),
156
it is e a s y to see, H (do)
C' = L=(do) 0.
that
B ~ 0
Ill,
closed
Common
(Bs*) o SR = 0 a.e.,
Lemma.
a.e.
we c o n c l u d e
~ H~(do).
Since
L (do), we see that This
shows that
Bs* =
s* = 0, as was to be
We b e g i n w i t h the f o l l o w i n g Let
~
Proof.
Let
~C
be a line b u n d l e
common
no n o n c o n s t a n t
inner
common
Q0
over
factors
inner
factor,
common
--~{-(R,~-I~ I)
i n n e r f a c t o r of a n y e l e m e n t ~(R,~
0)
of i n d u c t i o n
2, . . . .
T h i s means,
k : i, 2 . . . . .
constant
function,
6B.
has
Q0"
Then
of
and
~ ( R , q -I) -i ) :
~{~(R,~
common
inner
0)
should
be d i v i d e d
by
Q0"
and t h e r e f o r e ~ ( R , n 0) = QoH~(R). k = Q0 H (R) for each k = i,
that
a point
)
~ ( R , ~ k) 9A,
Ch. V, that
IQ0(a) I = i
as was to be shown.
Let us c h o o s e
has no
~ (R,~
has no n o n c o n s t a n t
in v i e w of T h e o r e m
It f o l l o w s
Then
inner factor to
~(R,~
Q0
we see that
~{~(R,~)
5D).
-i) =c S{=(R,q -I),
in
contains
By m e a n s
such t h a t II,
too.
associated
~(R,n0)~(R,n-ln0
Obviously,
R
(see Ch.
be the g r e a t e s t
be the line b u n d l e
Since Q0 ~ (R,n -i ~i)f a c t o r s and since
for
f* O S R of
Inner Factors
nonconstant
the
7D, that
subalgebra
[]
6A.
let
weakly*
and t h e r e f o r e
As we k n o w
proved.
6.
in v i e w of Ch.
is a m a x i m a l
and so
Q0
is a
[]
a E R, w h i c h
is h e l d
fixed,
and set
Jn (a) = Jn = s ( a ) ~ ( R ' ( n ~n(a))-l)' S
n
= S
(a) n
and
~n = ~n~(a) for
n = i, 2, .
. (see . . IA)
T h e n we h a v e
oo
Lemma.
Un=l Jn
Proof.
First we look at e a c h
common
has no n o n c o n s t a n t
i n n e r f a c t o r of
c o m m o n i n n e r factors.
~=(R,~n) ,
~{~(R,~n) , then
were nonconstant,
t h e n it s h o u l d
n.
w o u l d have a c o m m o n
So
~(R,~
)
n = i, 2, . . . .
Q
should divide
v a n i s h at some zero,
If S n.
Q
is a If
Q
z. E Z(a;R) with j > ] c o n t r a d i c t i n g to C o r o l l a r y
157
9A, Ch. V.
This means that
~(R,~
)
has no nonconstant
common
inner
-n
factors.
By the preceding
lemma
inner factors.
Thus the function
factor of
Since the eommon
Jn"
n = i, 2,...}
are only constant
~ ( R , [ [ I)
has no noneonstant
S (a) ~is the greatest n
common inner ~(a)
inner factors of the sequence functions,
we are done.
common i~ n
:
[]
oo
7.
The Orthocomplement 7A.
space
of
H (dX)
We want to determine
Ll(dXa ).
the orthocomplement
For this purpose we fix a point
following notations
besides
those given in IA.
S n'(z) = s(a)(z)s(a)(z)-lexp(-g(a'Z)n for
n : I, 2,...
of
H~(dXa )
a E R
in the
and use the
We set - ig(a,z))
and
S'(z) whose line bundles
: S (a)(z)-lexp(-g(a~z)
are denoted by
~n
and
- i~(a,z)), ~', respectively.
We also
set
for
Let in
n : i, 2,...
Jn Jn
(resp. (resp.
III (resp. in
n
K'(a)
= K' = S'~I(R,~'-I).
and
Kn )
Lemma
lowing result
= Kn
be the set of fine boundary
functions
for elements
Kn) , whose existence has been shown in Theorem
the weak* closure Un=l = Kn
Kn(a)
3B). of
Ll(dXa)),
We further denote by U n=l ~ Jn where
concerning
in
L~(dXa )
J(a)
dXa = kb(a)dx(b).
orthocomplements,
= J
(resp.
5E, Ch.
(resp.
K(a)
the closure
= K)
of
Then we have the fol-
which will be used later and
has its own interest. Theorem.
For any PWS
R
(a)
K : H~(dXa )-L,
(b)
~ : (~')±,
we have the following:
where the o r t h o c o m p l e m e n t a t i o n (Ll(dXa), L~(dXa)). Proof.
is taken with respect to the dual pair
(a) If f E Kn, then f is meromorphie on n If(z)iexp(- [ j=l g(zj,z)) has a harmonic majorant.
R,
f(a)
= 0
By Theorem
and
4B we
158
have
I
f(b)h(b)dXa(b)
: f(a)h(a)
: 0
A1
for any
h E H~(R) •
So ,
Kn C = H ~ ( d X a )±
(9)
for e v e r y
and t h e r e f o r e
n
K ~ H~(dXa)1. N e x t we take any
i, 2~...,
f~ E K±
= L ~ ( d X a )) . (C
K'Jn C = Kn
Since
for
n =
we have
f
^^
f~hk dXa
: 0
AI for any
h E K'
theorem
(Theorem
f~k.
The
bounded u/k
and
IB) t h e r e
function
and thus
a.e.
analytic
k 6 Jn"
f*k
u 6 H~(R).
If
on
u E HI(R)
k ~ 0, t h e n
k ~ 0
f*
can be v i e w e d
as the b o u n d a r y
f, of b o u n d e d
characteristic.
R
7B, Ch.
on the disk,
are c o m p l e t e l y
is d e t e r m i n e d
f2 E H~(R)
determined
uniquely
by use of L e m m a
III, w i t h analytic
3A.
by
R' = •
f*.
a n d so
function
f* =
for an
As seen for in-
of b o u n d e d
boundary
We w r i t e
So we h a v e
u =
is also
and p r o p e r t i e s
functions
by t h e i r
u
a.e.
say
Cauchy
such that
AI, we see that
Namely,
functions
f
a function
By the i n v e r s e
function,
istic on that
exists
f*k ± K'.
being bounded
stance by u s i n g T h e o r e m analytic
Thus,
functions,
f = fl/f2
seen that
of
character-
with
so fl'
k f l / f 2 E H~(R)
~ ~ J n has, by L e m m a 6B, no n o n c o n s t a n t for any k C U n=l Jn . Since Un=l c o m m o n i n n e r f a c t o r s , the i n n e r f a c t o r of f2 m u s t be an i n n e r f a c t o r
of
fl"
It f o l l o w s
belongs closed
to
H~(dXa )
in the
space
that
f = fl/f2
belongs
and c o n s e q u e n t l y
to
H~(R).
K± ~ H ~ ( d X a ).
L l ( d X a ), we c o n c l u d e
Hence,
Since
K
f* = is
that
: ~±± ~ H~(dXa )Combining (b) and
this w i t h
(9), we get the d e s i r e d
T a k e any
f E K',
Iflg (a)
meromorphic a harmonic
has a h a r m o n i c on
R,
majorant.
(fu)(a)
so that majorant = 0
By T h e o r e m
f
and
f on
R.
If
on
u E Jn'
l(fu)(z)lexp(-[j~l
R,
f(a)
then
fu
g(zj,z))
= 0 is has
4B we h a v e
^^ AI fu dXa = (fu)(a)
So
identity•
is m e r o m o r p h i e
= 0.
f 6 J± and as n is a r b i t r a r y f 6 ~ Thus n ' ' " N e x t we take any f~ e 9 ± (~ Ll(dXa)). Since
~v C J
n
J±.
is an ideal of
159
H~(R),
h E Jn
and
u E H=(R)
imply
I
hu E Jn
and so
^ ^
A1 f*hu dXa = 0.
f*h E H ~ ( d X a )± = K
Namely,
n : I, 2 .... So there
and since
exists
the a r g u m e n t belongs
is closed
a function
used
(a) .
in view of
K'
in
u E ~/(R,~ '-I)
in (a), we deduce
such that
from this
7B.
Theorem.
Let
R
be a PWS
for every
to
K _C K,.
f*h : S'u.
observation
to ~ ( R , ~ '-I) and thus f* b e l o n g s ^± ^ ± J = K' or, e q u i v a l e n t l y , J : K'
Hence,
K n =C K'
Since
Ll(dXa ), we have
that
By
u/h
K'; namely,
5± C K,.
[]
for w h i c h
( D C T )a
holds.
Then
~'(a) : ~(a) : H~(d×a )±. Proof.
We have
is i n c l u d e d any
in
h E H~(R)
which
is equal
shown
in the p r o o f
K'(a).
and thus, to
K.
of the p r e c e d i n g
Now we take any by
(DCTa) ,
Hence,
f E K'
theorem
Then,
f£1 fh ^^ dXa
: 0"
K' ~ K, as desired.
that
K(a)
fh E K' So
for
f E H ~ ( d X a )_L '
[]
NOTES The c l a s s i c a l IV of Heins Neville tion.
[31].
theorem Cauchy
inverse
[47] has a v e r s i o n It is p o s s i b l e
pactification, false
as was
of this
to f o r m u l a t e indicated
in its full g e n e r a l i t y .
strong
restriction.
The w e a k - s t a r lished
[27].
Cauchy-Read The
note
[20].
A weaker maximality The r e s u l t s
is d i s c u s s e d theorem
depending
in [18].
version
in
in C h a p t e r
in H a s u m i
6 and
com-
theorem
[17] under
4B) is in H a s u m i L~(dx)
[18].
compactificaof W i e n e r
Cauchy
in H a s u m i
(Theorem
H~(dx)
in terms
The direct
in S u b s e c t i o n s
in detail
shown
on a n o t h e r
our r e s u l t s
It was p r o v e d of
was
is
a
[17].
is in an unpub7 are due to H a y a s h i
CHAPTER
The themes
ence of A.
theory
Beurling's
began
the
such modules and simply is strong simply
role.
tion that
every
plicative)
As a m a t t e r
function.
covering
as a preliminary. doubly
Cauchy
theorem,
Beurling a E R
subspaces
chapter,
will
and their
is not
all
simply
be given
(multi-
in Ch.
here
in §2.
the direct
subspaces
that the statements
X.
to the
is r e c a l l e d
Assuming
invariant
plays
to the condi-
over a PWS are d i s c u s s e d
show that
so
to sur-
(DCT)
by some
liftings disk
theorem
As for
extends
is equivalent
of the unit
subspaees
Cauchy
theorem
is g e n e r a t e d
on the
As usual,
subspaees.
theorem
are determined.
it is proved
invariant
the p r o b l e m
subspaces
in Ch.
PRELIMINARY
let
measure III.
sense of p o t e n t i a l
i.
Invariant
Finally,
the h a r m o n i c
as defined
51.
The case
type.
inverse
Cauchy
discussion
subspaces
surface.
we next
interesting.
are of
(DCT a ) with
are all equivalent. In this
dX
(DCT)
H~(R)
Further
invariant
invariant
type.
of
sur-
defined
invariant hand,
Gamelin Riemann
LP(dx)
doubly
the direct
of fact,
ideal
over
influ-
it very
out that the
on the other
Here
of Helson,
of P a r r e a u - W i d o m
all doubly
type.
6-closed
inner
First,
It turns
of
to see when and how Beurling's
In §i we define universal
R
the decisive
subspaces
found
into two classes:
ones.
of P a r r e a u - W i d o m
a crucial
in books
already
surface
subspaces,
We have
under
H~(dx)-modules
to d e t e r m i n e
invariant
simple. faces
are divided
enough
we have
closed
of a given
invariant
[2], as seen
SUBSPACES
has been one of the central
classes
study of invariant
only recently,
boundary
subspaces
of Hardy
paper
Although
Our aim is to c l a s s i f y Martin
SHIFT-INVARIANT
study of s h i f t - i n v a r i a n t
in the m o d e r n
and others. faces
VIII.
R on
denote AI
a hyperbolic
for the point
We assume
as before
Riemann
0--the
that
R
surface
origin
of
is r e g u l a r
and R--
in the
theory.
OBSERVATIONS
Generalities IA.
By T h e o r e m
We are going 3A, Ch.
to c o n s i d e r
IV, the map
LP-spaces
f ÷ f
gives
LP(dx)
in what
an isometric
follows.
linear
injec-
161
tion of space
HP(R) HP(R)
into
LP(dx)
for every
p
is equipped with the norm
with
((LHM(IflP))(0)) I/p ]IflIp : {sup{if(z)l: The space
HP(R)
is denoted by
A subspace is closed
M
Moreover, we set
of
if
for
LP(dx)
(weakly* closed,
invariant subspace variant)
z • R}
if
0 < p <
if
p = ~.
if
is thus identified with a subspace of
HP(dx).
H~(d X) = {f: f • H~(R)}
and
0 < p ~ ~, where the
(the quasinorm,
M
H~(dx).M
H~(R)
0 < p < i)
LP(dx), which
: {f • HP(R):
f(0) = O}
0 < p ~ =.
is called an invariant subspace if it
if
p = ~) and if
H ~ ( d x ) - M ~ M.
Such an
is said to be doubly invariant
(resp.
is dense
M.
(resp. not dense)
in
simply in-
When
p = ~,
the density should also be taken in the sense of the weak* topology w(L=(dx),LI(dx )) Let
f
of
L~(dx ) .
be any m e a s u r a b l e function on
able subset
E
of
AI
supports
there exists a m e a s u r a b l e supports
f.
the support of
M
f.
smallest measure such that
IB.
Let
% = %R
T : TR
in
in
A I.
AI
LP(da).
L~(dx)
or in M
EM
[.]
up to equivalence
set
functions,
EM ~ AI
f • M.
of the
The set
EM
is
up to equivalence.
a(~-l(A)) [-]p
be a subspace of
D
÷ R
with for
= x(A)
~(0) ~.
T
for any m e a s u r a b l e
LP(da)
M
LP(dx).
Let
{M}
M o $.
Then
with set
A LP(dx)
LP(da) T
is the set of T - i n v a r i a n t
P {M]p
is the closure
of the linear envelope of
in
M o $ : {f* o ~: f* • M}
be the invariant subspace of
H~(dx ) o $
LP(da)
(weak* closure,
if
H ~ ( d a ) ( M o $).
is equal to the set
H~(da)T
H~(da).
be a doubly invariant subspace of
is a doubly invariant subspace of
LP(da).
LP(dx); then
=
By
denotes the closure o p e r a t i o n in
LP(da)T, where
LP(da).
of T - i n v a r i a n t elements Let
f
of m e a s u r a b l e
is a m e a s u r a b l e map defined a.e. on
We note in passing that
Lemma.
Then
denotes the o p e r a t i o n of taking weak* closure in
which is generated by p = ~) in
M
supports every M
A I \ E.
L~(da).
is a subspace of elements of
$
0 < p < ~,
or in
For a set
be a universal covering map:
such that
For
Let
a.e. on
be the group of cover t r a n s f o r m a t i o n s
Theorem 7B, Ch. III, values
f = 0
Ef, of the smallest measure that
is defined to be a m e a s u r a b l e
again d e t e r m i n e d u n i q u e l y by
and let
if
say
We say that a measur-
Such a set is d e t e r m i n e d u n i q u e l y by
and is called the support of
0
f
subset,
£I"
{M}p
162
Proof.
Since the map
LP(da)
and since the linear
linear Mo $
envelope
of
f* ÷ f* o $
H0(da)T(MO
~)
is dense
dense
in
M.
[M] 2
p = =, so that
The linear
with respect
note that
H~(dx).M
envelope
in
in
L2(dx),
M ~ [H~(dx)-M]2w Since the operations L2(dX)
[lin(H~(dx).M)] 2. Theorem
[']2
(Dunford
and
Passing
of
it thus
H0(dx).M
To see this, in
M.
If
that
the lemma
is w(L~(dx),LI(dx))
topology.
-
is dense we first
[']2w
de-
then
~ [lin(H~(dx).M)]2w. coincide
for any convex
[8], p. 422), we infer that
to the universal
7B, Ch. III, we see that
M, the
implies
is invariant,
H0(dx).M
[']2w
and Schwartz
into in
This
This proves
IIn(Ho(dX).M)
to the L2-norm
LP(dx) is dense
M o $.
is w(L2(dX),L2(dx))-dense
notes the weak closure
of
H0(dx).M
in ei@{M} • Since ei@{M} P i8 P and therefore e {M} P = {M} P .
Next we suppose
of
of
is included
includes {M}p for p < ~.
in
is an isometry
envelope
covering
surface
Mo $ ~ [lin(H~(da)T.(Mo
subset M
and using
$))]2
and a
fortiori M o $ E [lin(HV(d@).(M o $))]2" Clearly,
the right-hand
side is an invariant
subspace
of
L2(d~).
So
we have
{M} This shows that
~ {M} 2 ~ [ l i n ( H ~ ( d a ) . { M } 2 ) ] 2 = ei@{M}2 . {M} 2
to the L2-elosure implies
then that
invariant. IC.
of
is doubly {M}
{M}
Here
= {M}2 nL~(da).
M
is another
Let
(resp.
S) be the support CE
invariant
and also that
In view of Lemma
2B below,
Hence,
{M}
{M} 2
is equal
the latter
fact
must be doubly
[]
Lemma. where
.
simple
fact:
be any set of measurable
(resp.
of
C S) denotes
M
(resp.
functions M o 2).
the characteristic
on
Then
AI
and let
CS = C[O $
function
of
E
E a.e., (resp.
S).
2.
Shift-lnvariant
Subspaces
on the Unit Disk
2A. A subspace M of LP(da) is invariant if and only if it is closed (weakly* closed, if p = ~) and ei@M ~ M.
163
Lemma.
If
Proof.
Let
f E M
and
quence
{hn:
n = i,
2, ... }
tend
to
M ~ LP(do)
h
2, . . . .
a.e.
If
on
is i n v a r i a n t , h E H~(do).
T.
for
By A p p e n d i x
P(T) M
hM ~ M
such
for any A.I.4
h E H=(da).
there
is a se-
IIhnII~ =< IIhlI~
that
is i n v a r i a n t ,
h f E M n
and
for
hn
n = i,
0 < p < ~, t h e n
n : i,
belongs
in
Since
l h f - hnfiP. =
vergence
then
2,...
theorem to
=< 2PIIhII~IflP E Ll(dg)
lh- hn[Plf[P
and we h a v e
h f - h f + 0 a.e. By L e b e s g u e ' s n ~ I h f - h n f i P d o ÷ 0. Since M
M, as desired.
If
p = ~,
then,
for any
dominated
con-
is closed,
hf
k E Ll(do),
l ( h f - h n f ) k [ ~ 211hll IIfll Ik I e Ll(da) for as
n : i, n ÷ ~.
Hence
2,... This
hf E M.
2B.
and
(a)
0 < p < ~, then,
for
of
M
(b) then,
and If
M
for any
Proof.
(a)
Lq(d~).
p'
sure.
of
we
show
and to
M
M
n = I, $ n},
set
{IfI
topology
÷ 0
of
L (do).
that
The a b o v e
latter let
half
we h a v e
M
the we
in
with
subspace
with
0 < p ~ ~,
Lq(do)
M ALq(d~)
is w e a k l y *
is an in-
LP-closure see that
of the
u n = max{log+Ill
always
(a),
- logn,
£ p-l]flP/nP.
0 £ u n =< p - I i f i P / n P
on
the
In e i t h e r
take 0}.
T
that clo-
Suppose
to the
contains
Since
When
LP-norm
f E M.
belongs
is w e a k l y *
statement
shows
to its
that
f
f E M.
M AL~(do)
any net
w(LP(d~),LP'(do))
spaces
we c o n c l u d e
take
in the
f ~ L~(d~).
is e q u a l
that
q < ~, t h e n
closed,
to an
of B a n a c h
shows
If
is c l o s e d
topology
LP(d~)
LP(do),
thus
LP(do)
LP(do).
is closed.
that
theory
in
0 ~ u n = log(Ifl/n) < n},
LP(do)
of
convergent
argument
is L P - c l o s e d ,
in
of
in the w e a k
in
of
is an i n v a r i a n t
M NLq(d~)
f
Since
and
N
MNL~(do)
to
subspace
M = NNLP(do).
is w e a k l y *
is c l o s e d
2,...,
subspace
and
MNL~(da)
M A L~(do)
see the
{[fl
f (hf- hnf)kdo
MNLq(do)
closure
The d u a l i t y
of
of
IlfIiq i m p l i e s
MAL~(do).
belongs
each
Lq(do)
converges
p ~ i.
closure
To
of
= p/(p - i).
Since
closure
invariant
which
closure
now t h a t
So
M NLq(do)
closure
To see that
C MNL~(do)
the w e a k
a.e.
in the w e a k *
is an i n v a r i a n t
p < q ~ ~,
IIfI!ip ~
p > i, the net with
M
is the
First
inequality
{fl}
If
is an
subspaee
space
÷ 0
h f + hf n
0 < q < p, the
variant
the
that
D
Lemma.
Lq(do)
(hf- hnf)k
means
L 2-
L 2-
case,
f
closed. any
f E M.
Then,
on the
un = 0 and
thus
For set
on the
184 I u do < p-ln-Pi[fl[P ÷ 0 T n = p as
n ÷ ~.
Let
~n
T h e n by A p p e n d i x
be the h a r m o n i c
A.2.2
in
belongs
conjugate to
of
LS(d~),
un
with
~n(0)
= 0.
0 < s < i, and
iJ[nlls ~ CsllUnill,
(i) where
c s = 2 ( s + l ) / S ( c o s ~s/2) -I/s.
Fixing
an
s
with
0 < s < i, we
see that
ill II ÷ 0 as n ÷ ~. This m e a n s that u + i[ ÷ 0 in m e a ns n n So, t h e r e e x i s t s a s u b s e q u e n e e {Un(j) + i~n(j): j = i, 2,...}
sure.
converging
a.e.
to
llhjii
and
hj ÷ i
~ i
since
h .] f E M
0.
We set a.e.
by L e m m a
2A
'
hj
= e x p ( - U n ( j ) - i[n(j)).
Since
ihjfl
Then we h a v e
= Iflexp(-Un(j))
hjf E M A L ~ ( d o )
C MALq(do).
~ n(j)
and
Moreover
=
,
if - hjfl p = i ( l - hj)fl p £ 2Plf] p e Ll(do) for e v e r y vergenee
j
f - h . f ÷ 0 a.e. 3 f I f - h j f I P d o + 0 as
theorem,
the c l o s u r e (b)
and a l s o
of
M N Lq(do)
Clearly,
l a t t e r half,
N
fn ÷ f and
in
we m a y a s s u m e , a.e.
min{Ifi,n} + I
tfl < i
for
or
n : i, 2,...
Then
I I ~ [Ifn - fiiq We n o w c o n s i d e r
for
M
con-
is equal
LP(do).
to
To see the
exists
Since
a sequence
fn ÷ f
in m e a -
if n e c e s s a r y ,
- log ]fl , 0}
Ifl > n.
Then,
if
that
i =< Ifl =< n
[fnleXp(-Un)
and
I undo =< I [l°g+Ifni - l ° g + i f I l d °
= I I + I2,
of
to a s u b s e q u e n c e
Un = m a x { l ° g + I f n l
if
Hence
so that t h e r e
iif- fnliq ÷ 0.
with
by p a s s i n g
We set
= log+Ifn I
subspaee
f E N A LP(do), M
j ÷ ~.
dominated
LP(do).
is an i n v a r i a n t
we take any
{fn : n : i, 2,...} sure,
in
By L e b e s g u e ' s
+ I
ifi>n
l°g+ifld°
say. q ~ i
the case
and
~ q-lilf n - fit2 ~
p < ~.
for
0 < q < i.
T h e n we see that
JflPdo. Ifl>n Thus,
I I + 12 + 0
be the h a r m o n i c
as
n + ~
conjugate
of
and c o n s e q u e n t l y u
for
{Un( j) + i [ n ( j ) } , w h i c h
0 < s < i. converges
T h e n by
Let
with
~ (0) = 0.
As in
(a), we f i n d a s u b s e q u e n c e
n
llUn~is ~ Cs]lUnllI
f U n d o ÷ 0.
(i) we h a v e
n
to
0
a.e.
on
~.
We set
~n
h 3• :
exp(-Un(j) - i~n(j)) a.e. and
and see that
hjfn(j)
[hjfn(j) - fl p ~ 21fl p + i e Ll(da).
c o n v e r g e n c e theorem, LP(da), we have
hjfn(j) + f
f E M
in
and t h e r e f o r e
We finally suppose enough, then
12 = 0
p = ~.
So
and thus
we see that
w(L~(da),Ll(da)).
f E M
and so
NNL~(da)
and we are done.
2C.
is bounded.
f Unda + 0
M
C M.
as
If
n + ~.
= M,
n
M.
is large
P r o c e e d i n g as
hjfn(j) + f
~ f
in
L~(da)
a.e. and
in the weak* topol-
is weakly* closed in
L~(da), we have
The converse inclusion is true as before
[]
As is easily seen, an invariant
doubly invariant
is closed in
A g a i n by the d o m i n a t e d c o n v e r g e n c e
hjfn(j)
Since
M
is included in
we have got the desired result.
hjfn(j) e M A L ~ ( d a )
theorem, we conclude that ogy
Since
N N LP(da)
f
[hjfn(j) - fl £ 21fl + i ~ 211fll + i.
hjfn(j ) ÷ f
By Lebesgue's d o m i n a t e d
LP(da).
The converse inclusion being trivial,
above,
e M AL~(da),
(resp.
simply invariant)
subspace if
M
of
ei0M : M
LP(da)
(resp.
is
eiSM
M).
Theorem. LP(da),
Let
M
be a closed
(weakly* closed,
(a)
M
S
of
T
such that
a c t e r i s t i c function of
S.
(b)
M
q E L~(da)
M = CsLP(da),
The set
up to a set of Lebesgue m e a s u r e
S
where
CS
is the char-
is d e t e r m i n e d u n i q u e l y by
with
(i)
subspace of
zero.
lql = 1
a.e.
such that
M : qHP(da).
We begin with the case L2(da).
p = 2.
Suppose first that
The function
factor of modulus one. Let
M
be an invariant
ei0M = M.
Then let
orthogonal p r o j e c t i o n of the constant function i E L2(da) in0 space M. So i- q w e q for all integers n, i.e. I T for all integers Hilbert space
n.
Since
L2(da),
(i
I
P(T) + P(~). hq E M we have
e-i0M = M Since
for any
M
{e ine}
be the
forms an o r t h o n o r m a l basis of the a.e.,
subset,
is closed in
q
to the sub-
0
say
so that S, of
and therefore that
h ~ L~(da)
qL2(da) ~ M.
q)qeineda
( I - q)q = 0
istic function of a m e a s u r a b l e implies that
M
is simply invariant if and only if there exists a function
is d e t e r m i n e d u n i q u e l y up to a constant
Proof.
p = ~) subspaee of
is doubly invariant if and only if there exists a measur-
able subset
q
if
0 < p ~ ~.
q T.
hq E M
is the c h a r a c t e r Our a s s u m p t i o n for any
L2(da), A p p e n d i x A.I.4
and c o n s e q u e n t l y
for any
To see the reverse inclusion,
h
in
shows that
h ~ L2(da). take any
f E M
So
166
which
is o r t h o g o n a l
to
qL2(da).
i- q ± ein0f
for all i n t e g e r s
Hence
a.e.,
f = 0
a null
set,
M, there
ei@M ~ M.
a function
Then
q ± qe in@
is equal to a c o n s t a n t Jql = i
a.e.
qH2(da) space for n
Since
~ M.
Then
a.e.
that
qlq2
to a c o n s t a n t Finally,
fq
a.e.
qlq2
a doubly
L2(da).
This p r o v e s
the case
Suppose
tersection of
CsL2(da) suppose (i),
N = CsL2(do) It f o l l o w s
Finally doubly (resp.
for
It f o l l o w s
that q ± fe in0
w i t h all f = 0
integral
a.e.
= [q2J
that
to the
and also
JqlJ
Hence
= i
of
a.e.
qlq2
is equal
(resp.
qH2(do)
invariant
subspace
By
(i)
subspace
or to
by L e m m a
and
M
with of
qH2(da)
2B that
of
in the s e n s e d e s c r i b e d qHP(da)
of
M.
: qH2(da)
M : N nLP(da)
CsLP(da)
subspace
or
to
lqJ : i
= qHP(da).
be the L 2 - c l o s u r e S ~ T
either
with or
subspace
2B, the in-
is the c l o s u r e
is e q u a l
M : CsLP(da) N
As for
be an i n v a r i a n t Then,
MnL2(da)
S ~ T
invariant
M
0 < p < 2.
and let
CsLP(da).
2B and the case
Jql 2
p = 2.
p ~ 2, and let
from Lemma
q) is u n i q u e
is o b v i o u s
simply)
with a measurable
simply)
that
then implies
and h e n c e
CsL2(da)
(resp.
we h a v e to show that
(resp.
with
of
as desired.
we find that
2 < p S ~
subspace
To see the u n i q u e n e s s
H2(da)
is an i n v a r i a n t
LP(da).
LP-closure,
that
i a.e. qHP(da).
Lemma
in
with a measurable
By t a k i n g
to
one,
first that
M nL2(da)
MNL2(da)
a.e.
S, up to
is o r t h o g o n a l
a.e.,
M = qH2(da). = q2H2(da)
gives
LP(da).
lql : i
belong
a.e.)
of
~ M.
which
for
Since
of m o d u l u s
0 < p S ~,
qP(~)
f E M
it is easy to see that
Let
we have
is o r t h o g o n a l
This m e a n s
lJqil2 = i
n : 0, i,... in0 is o r t h o g o n a l to e
Jq] : i
(ii)
n = i, 2, . . . .
take any
qlH2(da)
and
of
is a c l o s e d
JfqJJ2 = i, w h i c h
Our a s s u m p t i o n
and c o n s e q u e n t l y
q, we s u p p o s e Then b o t h
for
f ± qe in0 So
vanishes
M ~ qH2(da)
ei@M
Since
eieM ~ M, we have
n = i, 2, . . . . and h e n c e
Moreover, (i - q)f = 0
The u n i q u e n e s s
q @ M, w i t h
a.e.
Conversely,
qH2(da).
a.e.
obvious.
next that
exists
ei@M.
to
fq = 0
and c o n s e q u e n t l y
w h i c h we had to show.
is a l m o s t
Suppose
Then n
with
(resp.
qHP(da))
LP(da)
and a l s o that
the r e s u l t
p = 2, w h i c h has a l r e a d y
Next
Then,
= CsLP(da )
in the t h e o r e m .
a.e. by
JqJ = or
:
is a CS
The r e s u l t
follows
from
been established.
[]
167
§2.
3.
INVARIANT
Doubly 3A.
SUBSPACES
Invariant
We now c o n s i d e r
tions m e n t i o n e d Theorem.
Let
in IA. E
variant
subspace
Proof.
Suppose
H~(dx).M
the case of R i e m a n n
function
of
of
LP(dx )
that
subset
Z.
for
of
Then
AI
0 < p < ~.
Since
then
its b o u n d a r y
on a n e g l i g i b l e
subset
£ I.
So t h e r e
h(b) -I
if
b e E
for any g i v e n
such that
with
f • M
f
n
fn • H ~ ( d a ) . M .
I f - fnl ~
and
If[
t h e o r e m we h a v e M.
The case
3B.
Here
Theorem.
that
i ~ p ~ ~;
(b)
0 < p < i
Since
L e m m a IC.
3C.
let
X(Z)
M ~ CzLP(dx )
S
is r e g a r d e d
Suppose
B • S(0)~(R,(~(0))
IB
which
on
=
A I.
And
is b o u n d e d ,
n
un
implies
dominated H0(dx).M
that convergence
is d e n s e
is omitted.
in
[]
section.
Let
M
be a d o u b l y
support
of
the p r o b l e m
is also d o u b l y
M.
invar-
Then
M =
is to p r o v e invariant
for some m e a s u r a b l e
as the s u p p o r t
f i r s t that -I)
true,
{M]p
is n o w d i v i d e d
be any e l e m e n t
with
Un(b)
< i.
{M}p : C s L P ( d a )
The p r o o f
of
in this PWS.
M. only
= M
Hence
be the
in
holds:
is a l w a y s
By L e m m a
2C-(a),
Z
E ~ AI Set
and the p r o o f
is a r e g u l a r and
and
inclusion.
by T h e o r e m
p / ( p - i)
R
LP(dx)
u
By L e b e s g u e ' s n ÷ ~.
similar
if one of the f o l l o w i n g
Since
T.
of
(a)
reverse
a.e. as
is a l m o s t
in-
is c l o s e d
vanishes
otherwise
Since
~ CELP(do)
is our first m a i n r e s u l t
Suppose
iant s u b s p a c e cELP(dx )
f - fn ÷ 0
E.
: 0
The d e f i n i t i o n
llf- fnlIp ÷ 0
p = =
and
h
a set
on
M
is d e n s e
function
exists
: hu f. n
Unf • UnCELP(do) and t h e r e f o r e
denote
is a d o u b l y
H0(dx)'M
0 < lh[ < ~
[h(b) I ~ i/n
we set
CE
it is c l e a r that
h • H~(R); of
and let
M = c z L P ( d X)
~ M, we h a v e only to show that
complement
and use the n o t a -
0 < p ~ ~.
Take a n o n z e r o
negligible
surfaces
First we show the f o l l o w i n g
be a m e a s u r a b l e
the c h a r a c t e r i s t i c
and
Subspaces
of
M ° $,
i ~ p ~ ~.
Let
is o r t h o g o n a l
in the n o t a t i o n
subset
CE o $ = CS
into two cases
(a) and
described
M.
S
of
a.e.
with
p'
Take any n o n z e r o
in Ch.
by
(b).
s* E LP'(d×) to
the
and so,
VII,
IA.
If
=
168
u
is any m e r o m o r p h i c
then
Bu E H~(R)
function
and so
on
R
Buf* @ M
(2)
[ i
such that for any
lulg (0)
f* E M.
is b o u n d e d ,
Thus we h a v e
B u f * s * d X = 0. A1
By the i n v e r s e tion
Cauchy
k E HI(R)
theorem
such that
(Theorem
IB,
k = Bf*s*
a.e.
Ch.
VII)
on
A I.
there
exists
Setting
a func-
u = 1
in
(2), we h a v e
(3)
t : ~ J
k(0
On the o t h e r hand,
the f o r m u l a
~ d X : 0. AI
(12)
in Ch.
III shows that
H [ ( B f * s * ) o $] = H [ ~ f * s * ] o ~ = H[~] o ~ = k O % 6 H I ( ~ ) . For any
v E H~(D)
we thus have,
by
(3) and T h e o r e m
I~ v ( e i S ) ( ( B f * s * ) o $ ) ( e i S ) d o ( 8 )
:
By t a k i n g
LP-limits
in
I
for any B
is n o n z e r o ,
Hence
s* = 0
have
S
{M}p = C s L P ( d g ) , we c o n c l u d e
on
Z.
Lemma.
This
implies
ment Proof.
f* 6 LP(dx ),
~ e H~(dx) (Lemma)
0 < p < ~.
such that Let
a.e.
~f*
that
that on
(~s ~) o
E.
zero
s* I C z L P ( d x ) .
Since in
A I.
We thus
(a) is v e r i f i e d .
In o r d e r to deal w i t h the case Let
Bs* = 0
o n l y on a set of x - m e a s u r e
C E L P ( d X) ~ M, so that the case 3D.
0.
:
and c o n s e q u e n t l y
can v a n i s h
a.e.
~)(o)
= v(0)(kO
v - ( f * o $), we see
Since
on B
III,
((as*) o ~ ) ( e i S ) f l ( e i S ) d g ( @ ) = 0
fl E {M}p.
m u s t v a n i s h a.e.
v(0)k(0)
7B, Ch.
(b), we p r o v e
Then there
exists
a nonzero
ele-
is b o u n d e d .
u* : l o g + I f * [ .
Then
u*
is p o s i t i v e
and
summable,
for
0 ~ u~ : log If~l : p-flog If~l p ~ p-ilf~IP on the
set
R
u*
of
{If*I
> i}.
and let
v
Let
u : H[u*]
be the h a r m o n i c
be the h a r m o n i c conjugate
of
u.
extension Then
u
to is a
169
positive m. on
harmonic
R.
If
function
6
denotes
on the
R
and t h e r e f o r e
line b u n d l e
e -u
is a b o u n d e d
associated
to
l.a.
e -u, t h e n t h e r e
exists
an e l e m e n t h I ~ ~ (R,6 ) with llhl~l~ = i, for R is a PWS. -u-iv Then h l e d e t e r m i n e s a s i n g l e - v a l u e d f u n c t i o n , say h, b e l o n g i n g
to
H (R)
and we h a v e
Let whose
M
be a d o u b l y
support
an i n v a r i a n t vanishes and
N
E
subspaee
of
2C, that
The a r g u m e n t
{N} 2
zero,
namely
S
given
Since
o(S)
m u s t be d o u b l y
in 3C t h e n
shows t h a t
Since
LP(dx)
3E. LP(dx)
= [L2(dX)]p,
(b) is proved. Problem. with
Can one show that
4.
Simply 4A.
point
In w h a t
consider lowing
then
element
lemma
= X(Z)
is H~(dX)
implies
that
M
N ~ C z L 2 ( d x ).
in 3B is the s u p p o r t < I, we see,
invariant.
N
of
Hence
of
{N}2,
so
in v i e w of T h e {N} 2 = C s L 2 ( d ~ ) .
and t h e r e f o r e
) ~ M ~ czLP(dx). result
M = CzLP(dx).
So
that
M
is a d o u b l y
and that the s u p p o r t
invariant
of
M
subspace
coincides
of
with
A I.
?
Subspaces
is h e l d
R, c o n s i s t i n g a function
0 < p < i,
So we h a v e
f o l l o w s we w o r k on a r e g u l a r
a @ R, w h i c h
group of
the a b o v e Z.
we get the d e s i r e d
M = LP(dx)
Invariant
LP(dx),
[]
Suppose
0 < p < i
of
[]
N = MNL2(dx);
N = CEL2(dx)
C E L 2 ( d X) : M n L 2 ( d x
the case
Set
S i n c e any n o n z e r o
o n l y on a set of m e a s u r e
the set
~ i, as desired.
subspace
< i.
L2(dx).
have the same support,
{N} 2 ~ C s L 2 ( d o ) .
orem
invariant
has x - m e a s u r e
On the o t h e r hand, that
lhf* I ~ e-U*If*l
Q
fixed.
of c l o s e d
We d e n o t e curves
on the p r o d u c t
PWS by
Let us c h o o s e a
Fa(R)
issuing
space
R.
the f u n d a m e n t a l
f r o m the p o i n t
A I × Fa(R)
with
a, and
the fol-
properties:
(AI)
for each
(A2)
there
y E Fa(R) ,
exists
b ÷ Q(b;y)
a line b u n d l e
~
is m e a s u r a b l e
over
Q(.;yl ) = ~(yl)~(y2)-iQ(.;y2 ) for any
YI' Y2 ~ Fa(R)"
corresponding
character
Such a f u n c t i o n tive")
on
A I x Fa(R)
scribe
the b o u n d a r y
Q
Here at the
~
is c a l l e d
of c h a r a c t e r values
say that two m - f u n c t i o n s
represents
same time
(Ch.
~
and
Q2
on
AI
a line b u n d l e II,
AI~
such that
a.e.
an m - f u n c t i o n
and the
2B). (m for
and w i l l be u s e d
of a m u l t i p l i c a t i v e QI
R
on
analytic
are e q u i v a l e n t
"multiplicain o r d e r
to de-
function.
We
if t h e y h a v e the
170 same bundle
(or character),
say
~, and there exists a
Y0 E Fa(R)
such that Ql(-;y) for every
y E Fa(R).
= $(y0)Q2(-;y)
We write
a.e. on
QI e Q2
if
QI
AI and
Q2
are equiva-
lent. To each as follows: $'(a)
f e ~P(R,~)
we associate
take a branch,
= {'(R,a)
say
and denote
it by
Fa (R).
For each
tity of the group
f0(z;y) for
z E $'(a).
Then,
most every Green line
for
b = b£,
determined
£ E A(a),
a.e.
on
AI
A I.
tions
fl(z;y)
f0
and
fl
function
where
y E F a (R)
on
A I × Fa(R)
l
denotes
the iden-
we set
= $(¥)f0(z;l) 4A, Ch. VI,
% E A(a).
We set
if the right-hand
f0(%;y)
exists
side exists.
So
for al-
f0(b;y)
is
and
: ~(y)fo(b;1)
fl(b;y)
say
as above,
= ~(y0)fl(z;y)
are equivalent.
for
4B.
and
f0(z;y)
f
on the Green star region
f0(z;l),
If we choose another branch,
such that
f
by Theorem
fo(b~y) on
an m-function
f0' of
and
fl' of
f
and define
then there exists f0(b;y)
a
Y0 E Fa(R)
= ~(yO)fl(b;y);
We call any one of
~
func-
namely,
the boundary m-
f.
In the following we consider
shall see, results
are independent
the case
a = 0.
of the choice of
In fact,
a.
as we
We first show
the following Theorem.
Let
IQ(.;y)I
= i
for some Proof.
R
with
uj(z;y)
procedure
be an m-function for each
is a PWS, there exist
and
~j(b;y),
and
~2(b;y)Q(b;y)
are independent
functions
and
in
Then
of character
~
M = {f* e LP(dx):
uI E ~(R,~)
lu2(0) I ~ 0
a = 0. of
Then
7 e F0(R)
and
(Corollary
j = i, 2, be constructed
in 4A with v~
A I × F0(R)
with f*/Q
I ~ p ~ ~, is simply invariant.
lUl(0) I ~ 0
described v~
on
y e F0(R).
h E ~P(R,~-I)},
Since
~ ( R , ~ -I) Let
Q a.e.
u2 E 9A, Ch. V).
from
Ul(b;y)/Q(b;y) and define
L~(dx ), respectively.
uj
by the and
single-valued
Ul(Z;Y)U2(z;y)
is
171
also independent
of
y
and defines
We now take any If
h(b;y)
denotes
the boundary
f~(b)/Q(b;y)
and if
corresponding
to
and defines HI(R)
h(z;y)
h(b;y),
an analytic
say
u3, in
f*/Q
~ h
for an
m-function
for
h
Ul(Z;y)h(z;y)
function,
say
hl,
H~(R).
h • ~P(R,[-I).
satisfying
is the multiplicative
then
analytic
h(b;y)
is independent
in
HP(R).
:
function of
For any
y k •
we have k(b)f*(b)v~(b)
= ~(b)(f*(b)/Q(b;y))Q(b;y)v~(b)
~(b)~(b;Y)~l(b;~) = ~(b)fil(b)
:
a.e.
a function,
f* • M, so that
on
AI
(cf. Theorem
6A, Ch. VI) and therefore
;
~(b)f*(b)v~(b)dx(b)
= I
41
k(b)hl(b)dx(b)
: k(O)hl(O)
: 0-
41
Namely,
v[ ± Ho(dx).M.
I
But, on the other hand,
v~(b)v~(b)dx(b)
= I
hl
we have
v~ E M
and
u2(b;y)Ul(b;y)dx(b) AI
= I
u3(b)d×(b)
= u3(0)
~ 0,
AI for
]u3(0) I : lUl(0)llu2(0) I f 0.
M, as was to be proved. 4C. (DCT a)
In order to proceed
(Ch. VII,
Theorem.
Suppose
space of
LP(dx),
4 l x F0(R )
Thus
H~(d X).M
cannot
be dense
in
[] further,
we need the direct
Cauchy theorem
3C), which we use here as a hypothesis. that
(DCT 0) holds.
If
M
I ~ p £ ~, then there
of some character
~
with
is a simply
exists
invariant
an m-function
IQ(-;y)I
= i
a.e.
Q
on
subon
AI
such
that M : {f* e LP(dx): The proof is divided an m-function
Q
on
f*/Q
of modulus
M ~ {f* e LP(dx):
f*/Q
character
And in the second
4D. p ~ ~.
of
Q.
Let Then
were doubly
M
for some
into two parts.
A I × F0(R) ~ h
~ h
for some
be a simply
h e ~P(R,~-I)}.
In the first part we define one a.e.
h • ~P(R,~-I)}, part we verify
invariant
subspace
of
in such a way that where
~
is the
the reverse
inclusion.
LP(dx)
i
with
{M} is a simply invariant subspace of LP(do). If it P invariant, then M would turn out to be doubly invariant
172
by our a r g u m e n t L~(do)
with
in 3C.
So, by T h e o r e m
lql = i
a.e.
on
(4)
~
{M)p
c(T)q
a.e.
complex
is T - i n v a r i a n t , on
~
number
the u n i q u e n e s s
for e v e r y
of m o d u l u s
T ÷ y~
numbers
of
T
a character T E T. to Ch.
F0(R)
~ E F0(R)*
This II,
of m o d u l u s
onto ~
it by
N(z;~),
on
~
w E ~
F0(R)
7C, Ch.
by s e t t i n g
~(yT)
as a line b u n d l e
group
isomorphism
= c(T)
over
which
star r e g i o n
where
l
is the i d e n t i t y
as in 4A.
on
and
Moreover,
= IN I o ~
= N(~(w);y
R
is h e l d
for e v e r y according
fixed. 6'(0)
of the g r o u p
we d e f i n e
for some
N1
We take and de-
F0(R).
an a n a l y t i c
Then
function
then,
= N(0;I). for any
everywhere
on
F • HP(~).
in NIF
By the
= c(T)NI(W)
f* • M.
Multiplying
same t r a n s f o r m a t i o n
function
T • T,
~.
Q, we take any n o n z e r o
o b e y the
k E HI(R).
NI(0)
) = ~(yT)N(~(w);~)
N1 o T = c ( T ) N 1
T
and
%(w) E 6'(0);
(5)
HI(~),
N1
Then on b o t h
= k o
formula
(12)
in Ch.
follows
that
~ o $ : ~i ~
a.e.
(f*/i) o $ : ( f * o $ ) / ~ ] ~
on
T
= q/Nl
f* o $ = sides,
rule w i t h r e s p e c t
so that
III we h a v e
H[k o $] = H[k] o ~ : k o ~ : NIF : H [ ~ I g ] . From this
defined
is e a s i l y
III, we can d e f i n e
N • ~(R,~),
is a T - i n v a r i a n t
for some
q o T =
into the m u l t i p l i o a t i v e
By use of the c a n o n i c a l
on the G r e e n
In o r d e r to d e f i n e
q
T ÷ c(T)
N
satisfy
and t h e r e f o r e
(6)
q G
by the c o n d i t i o n s
N 1 o T(w)
Since
T
that
is a u n i q u e l y
of
branch
INII
NIF
of
is a l s o r e g a r d e d
are d e f i n e d
qF a.e. we get
shows
c(~)
g i v e n by T h e o r e m
of
q
The c o r r e s p o n d e n c e
one.
Take any n o n z e r o m e m b e r
Let
a function
2B.
a single-valued
N(z;y)
of
~ E T, w h e r e
one.
seen to be a g r o u p h o m o m o r p h i s m of c o m p l e x
Nl(W)
exists
{M}p = qHP(da).
Since
note
2C, t h e r e
such t h a t
and t h e r e f o r e a.e.
to
T,
173
This m e a n s
that
the n o t a t i o n
f*/k
is i n d e p e n d e n t
introduced
Q(b;y) Then,
for e a c h
dependent
of the c h o i c e
of
f* E M.
on
AI
Using
in 4A, we set
y ~ F0(R) ,
of the c h o i c e
: f*(b)N(b;y)/k(b). Q(b;y)
of
is d e f i n e d
f* E M.
Moreover
a.e.
we h a v e
and is in-
Q(b;y)
: ~(y) ×
Q(b;~). Let implies
u = INI . that
E A(0).
Since
u
exists
a n d is e q u a l to
We thus have,
for a l m o s t recall
](£)
every
is a b o u n d e d
for e v e r y
£ E A(0)
Theorem
u(b£)
6B,
for a l m o s t
Ch. VI, every
y E F0(R) ,
and so
IQ(b;Y)I
= 1
a.e.
on
We n o w
A I.
the e q u a t i o n
(7)
f~(b)/Q(b;y)
where
k
is d e t e r m i n e d
[NIFI/INI[ longing
uniquely
~P(R,~-I).
Lemma.
Let
Q
and
by (5).
on
Since
k(z)/N(z;y)
fe/Q
To p r o v e the r e v e r s e
for some
a.e.
£i'
Ik(z)/N(z;y)I o % =
is a s e c t i o n ,
say
h, be-
Hence
M ~ {f* 6 LP(dx):
4E.
= k(b)/N(b;y)
= IFI, we see that
to
(8)
f*/Q
l.a.m.,
~
~ [
for some
inclusion,
we f i r s t n o t e
be as in 4D and let
f* E M}.
Then
J
h 6 A'P(R,<-I)}.
the f o l l o w i n g
J = {h e ~ P ( R , ~ - I ) :
h
has no n o n c o n s t a n t
common
inner
for e v e r y
Since
I(R)
factors. Proof. band Ch.
We set
(Ch.
II,
5A) and
IV, the f a m i l y
I(R),
which
that
lq'l
k(b)/N(b;y) on
u h = P r l ( l O g lhl)
R.
Ill,
is n o n p o s i t i v e . : e x p ( u o ~). with
uh S 0
If ~
Let
f* E M, then,
preserves
(7),
This m e a n s
f* o $ = q ( ~ o $)/Nl
h E J
by
be an i n n e r (7),
and h e n c e
q'
function
by T h e o r e m
divides
Since
such
: S u
6B, Ch.
the i n n e r
(k o ~)/N I E q ' H P ( ~ ) .
E qq'HP(d~).
4A, u, in
P r l ( l O g Ik/Nl)
the i n n e r p a r t s
that
say
f*(b)/Q(b;y)
Thus we h a v e
is a
by T h e o r e m
least u p p e r bound,
q' ~ H ~ ( ~ )
P r l ( l O g I(k o ¢)/NII ) ~ u o ¢ (k o %)/N I.
for e v e r y
has the
k/N e ~ P ( R , ~ - I ) .
S i n c e the m a p
f a c t o r of use of
since
{Uh: h E J}
h E J.
f* e M
So, by is a r b i -
174
t r a r y and
since
In v i e w of therefore
is i n v a r i a n t ,
(4) we c o n c l u d e that
as desired. 4F.
qq'HP(do) u
that
vanishes
q'
p'
= p/(p - i), o r t h o g o n a l
which
independent
of
side of
f~(b)/Q(b;y)
on
R.
This proves
the l e m m a
a.e.
f* E M
on
AI
s'f*
M
and
show t h a t
We take a n o n z e r o
fixed.
Clearly,
s'f*
and then c h o o s e
for e v e r y
is o r t h o g o n a l
~ K'(0).
(9)
4C, let us take any
s~ •
it is o r t h o g -
element
h0
h0(b;y)Q(b;y)
in
is
y • F0(R).
H~(dx)-module, s'f* • K(0
to
(8).
is a r b i t r a r i l y
Take any nonzero
such that
~ qq'HP(do). P of m o d u l u s one and
[]
onal to the r i g h t - h a n d ~(R,~-I),
{M}
is a c o n s t a n t
identically
To f i n i s h the p r o o f of T h e o r e m
LP'(d~),
we h a v e
= k0
exists
a.e.
AI
H ~ ( d x ).
so that
Since
y • F0(R). to
So t h e r e on
h • J
M
=
is an
By T h e o r e m
a meromorphic
h(b;y)
7A, Ch.
function
VII
k 0 • K'(0
and thus
s * ( b ) q ( b ; y ) h 0 ( b ; Y) : s * ( b ) f * ( b ) h ( b ; y ) - l h 0 ( b ; y ) = ko(b)h(b;y)-lho(b;y).
Since
h0
dent of
and y
h
and d e f i n e s
correspondence bounded h • I
have the
same c h a r a c t e r ,
a single-valued
meromorphic
z + k0(z)h0(z~y)/h(z;y)
characteristic, in v i e w of
is the c h a r a c t e r
(9). of
k I • ~I(R,6'-I).
say Since
u, w h i c h
It f o l l o w s
is i n d e p e n -
function.
is a m e r o m o r p h i c is i n d e p e n d e n t
k 0 • K'(0)
S '(0), we h a v e
h0(z;y)/h(z~y)
So the
function
of
of the c h o i c e
of
: S'(0)~(R,~'-I),
k 0 = S'(0)(z;Y)kl(Z;y)
where
~'
for some
that
~og (JuJls,(°)J -1) : log Ih01 + log l k l l -
log
Ihl
and
Pri[log
(lulls'(°)l-1)]
H e r e we f i r s t n o t e that over
J
and since
4E, we c o n c l u d e
J
: pri[log
(IhoIIkll)]
Prl[lOg (lh011kll)] has no n o n c o n s t a n t
Consequently,
Since
h
can v a r y
inner factors
by L e m m a
that Pri[log (lulls'(O)l-l)]
namely,
~ 0.
common
Ihl].
- pri[log
lul Is'(O)I -I
has a h a r m o n i c
~ O. majorant,
we have lu(z)Ig(0)(z)
~ v ( z ) e -g(0'z)
say
v, on
R;
175
In o t h e r words, lulg (0) that
u
is a m e r o m o r p h i c
has a h a r m o n i c
[ • LI(dx)
I
majorant.
function
s*(b)Q(b;~)h0(b;~)d×(b)
hand side of (8).
4G.
: I
closed
Suppose
of
if
for
for
(Ii)
(i)
%: ~
if and o n l y
÷ R
(B-closed,
on
~
i £ p < ~.
into
qHP(~) (Ifl/l) p
dX
HP(~).
is c l o s e d
on So
in
The ease (ii)
in
p = ~
This
finishes
the p r e c e d i n g
the-
i ~ p ~ ~
and let
Then,
exists
M
a bounded
M
be a
is an H=(R) inner
l.a.m.
a harmonic
majorant}
AI,
covering
map w i t h of
(i0) or
HP(R).
Since
: 0
on
D.
f ÷ fo %
function let of
is a c l o s e d
by T h e o r e m in
T h e n the
be a s e q u e n c e
in
M
the m e a s u r e
da
on
is an i s o m e t r y
to
similarly,
statement,
M0
q
fo %
in
which
from
HP(~) implies
As that
as was to be proved.
inner
function
maps
f o ~ • qHP(D),
majorant,
HP(dx )
$
converges
so
and let
qHP(~).
Since
p = ~) H = ( R ) - s u b m o d u l e
of
of
~(0)
I o ~ = lql
the map
for any
Every nonzero
of the f o r m
{fn: n = i, 2,...}
{fn o ~}
M 0 = {f: f • M}, then
M
p = ~) H ~ ( R ) - s u b m o d u l e
To show the c o n v e r s e
=) H ~ ( d x ) - s u b m o d u l e
subspace
we have o n l y to show its c l o s e d n e s s .
can be p r o v e d
if
is b o u n d e d } .
such that
HP(~),
H~(~)
(B-closed,
Ifl/l
f • HP(R).
has a h a r m o n i c
is B - c l o s e d
IV).
(8).
HP(R)
HP(R).
admits
is a s u b s p a c e Let
to some
to the m e a s u r e
closed
Let of
every
if
be a u n i v e r s a l
converges
we set
of
if t h e r e
(Ifl/l) p
M o ~ = {f o ~: f E M}
HP(R)
Ch.
(DCT 0) holds.
an H ~ ( R ) - m o d u l e ,
Suppose
T
in
to the r i g h t -
i ~ p < ~,
be an i n n e r f u n c t i o n
which
sign h o l d s
p : ~) s u b s p a c e
We show first t h a t
is a c l o s e d
set
= 0.
p = ~,
is c l e a r l y
Let
is o r t h o g o n a l
subspaces
M = {f • H~(R):
Proof.
: u(0)
[]
M = {f • HP(R):
(ii)
M
that
HP(R)
such that,
and,
and
the f o l l o w i n g
(B-closed,
(i0)
{(b)d×(b)
s*
the e q u a l i t y
4C.
As for the i n v a r i a n t
submodule I
is a r b i t r a r y ,
Hence
of T h e o r e m
orem implies Theorem.
= 0
we see
AI
h 0 • ~ P ( R , ~ -I)
the p r o o f
u(0)
(DCT0),
and
AI Since
such that
As we are a s s u m i n g
Mn
if we note that on
M
be a n o n t r i v i a l
~.
HP(R), (weakly*
3B, Ch.
cannot
qH~(~)
q
IV
vanish
i ~ p ~ ~. closed,
(Corollary
If
if
p =
5D,
identically
on
176
any n o n n e g l i g i b l e v i e w of T h e o r e m exists
subset 3B.
an m - f u n c t i o n
IQ(';Y)I
= i
a.e.
of
M0 Q
on
on AI
such that So
f • M
f*/Q
boundary
therefore
f(z)/hf(z;7)
(12)
istic
such that, every
easily
majorant
and,
shall
see in the f o l l o w i n g
that
I
is a b o u n d e d
Lemma.
on
inner
Q0
are
Proof.
We set
characteristic
u0(z)
function
y • F0(R) ,
every
for
5E, Ch.
v 2 = ( l o g u 0) v 0, and
u2
and
u 0 = U l / U 2.
functions
III.
Q0
if,
M
on
R.
Ql(Z;y)
Q2(z;y)
Q0(z;y) We n o w show t h a t
Q9
Setting
and
characterfor al-
to
M
i ~ p < ~, is bounded.
has
(Ifl/I) p As we
inner function
the d e s i r e d
inner
if
we see
so
form.
[]
function. u0
is an l.m.m,
of
= IQ(b£;Y)l = 1 l o g u 0 E SP'(R)
and
its
for = 0
We set
v I = ( - l o g u 0) v 0,
u 2 = exp(-v2).
without
there
belongs
for
Then
l o g u 0 E Z(R).
i n n e r l.a.m,
and
f.
6B, Ch. VI,
We k n o w that
Consequently,
It f o l l o w s
= IQo(Z;y)l,
IfI/l
Hence
identically,
u I = e x p ( - v I)
are b o u n d e d
f.
= Q(b~;y)
is a b o u n d e d
by T h e o r e m
So
of b o u n d e d
of
of b o u n d e d
l(z)
p : ~,
l.a.m.
Q0
p r Q [ l O g u 0] = H [ l o g ~0 ] = H[0] by T h e o r e m
of
~ P ( R , < -I)
y • F0(R).
function
f e HP(R)
if and o n l y
lemma,
~ E A(0).
part v a n i s h e s
for e v e r y
Q0(~;y)
By s e t t i n g
= [Q0(z;¥)I and,
in
= f(z)/hf(z;y),
G0(b £) = ~0(£) = LQ0(£;~)I for a l m o s t
such that
hf,
independent
is a ( m u l t i p l i c a t i v e )
bounded
quasibounded
AI
say
meromorphic
Thus a f u n c t i o n
that the l a t t e r o c c u r s
4H.
a.e.
meromorphic
f/Qo • ~ P ( R ' ~ - I ) "
has a h a r m o n i c
~
in
4C t h e r e
h • ~P(R,~-I)}.
is also i n d e p e n d e n t
for any f i x e d
~ • A(0).
and o n l y if
invariant
By T h e o r e m
of c h a r a c t e r
an e l e m e n t ,
values
Q0(z;y)
we get a m u l t i p l i c a t i v e
is not d o u b l y
invariant.
for some
exists
: Q(b;y)
whose
most
~ h
is a m u l t i p l i c a t i v e
characteristic, that
M0
simply
A I × F0(R)
there
~(b)/hf(b;y)
f(z)/hf(z;y)
and so
and
M 0 = {f* e LP(dx): For any n o n z e r o
AI
is thus
nontrivial
Then both common
exist multiplicative
such that
u I = IQII ~
inner
uI factor
analytic
u 2 = IQ2I
and
= Ql(Z~y)/Q2(z~y).
is a c o n s t a n t
function.
As we h a v e
seen,
an
177
element
f E HP(R)
(Ifl/u0)P f/u 0
has
is b o u n d e d
be c h o s e n
belongs
a harmonic on
to
M
R.
Suppose
as q u a s i b o u n d e d
by a p p l y i n g the p r o j e c t i o n -i p uf. Since P r i ( l o g IfI)
Namely, means
the
Q2
factor
if
h E I
independently
and
f
of
h(z;y)
and y
f(z)
and
But,
Q2 as
should shown
and
hence
the
same w a y
5.
Equivalence
Q2
5A. more
must
the The
p = ~,
Since
uf
can
log Ill + v I - v 2
v I A v 2 = 0, we get IfI ) + v I) ~ v I A v 2 : 0. by
QI"
then
to
M.
By w h a t
factor
has
uf
in turn
some f
f c M}. is w e l l - d e f i n e d
we h a v e
seen
above,
I f ( z ) / Q l ( Z ; y ) I p S uf.
inner
changing
This
of
= Q0(z;y)h(z;y),
7
of
h, as was
no n o n c o n s t a n t The
ease
to be proved.
common
p = ~
for a s u i t a b l e
can
inner
factor
be t r e a t e d
constant.
in
[]
(DCT)
direct
Cauehy
following
are
of i n v a r i a n t theorem.
equivalent
( D C T )a
holds
for
(b)
( D C T )a
holds
for all
(e)
an ideal
form
for
IV, we o b t a i n
inequality
factor
be a c o n s t a n t .
by just
of
the
Ch.
for
belongs
4E,
i ~ p < ~,
and,
= f(z)/Q0(z;y)
Our c h a r a c t e r i z a t i o n
about
Theorem. (a)
of
some
H~(R)
subspaees
Namely
enables
us to
say
we h a v e
for any r e g u l a r
PWS
R:
a E R; a E R;
is
B-closed
been
shown
if and
only
if it is of the
(ii).
Proof.
(a) ~
to r e p l a c e (c) ~ included
in
(c):
0
by
(b):
This
has
in T h e o r e m
4G,
for we h a v e
only
a. Take
K'(a)
to the d u a l i t y the
divide
in L e m m a
for
R
I ~ p < ~.
can be d i v i d e d
inner
lh(z;y)/Q2(z;y)I p = Thus
4A,
if,
on
that
to the
£ 0
of
only uf,
Ifl) + v I - v 2 ~ 0,
pr I
is a c o m m o n
I = {h E ~ P ( R , ~ - I ) : In fact,
first
Ifl) + v I = v I A ( P r i ( l o g
inner
that
say
by T h e o r e m
Pri(log
Pri(log
if and
majorant,
any
and
a ~ R, w h i c h
since
the
(L~(dXa),Ll(dXa))
orthocomplement
of
K'(a)
is h e l d
fixed.
orthocomplement is
H~(dXa )
is i n c l u d e d
in
of
Since K(a)
by T h e o r e m H ~ ( d X a ).
K(a)
with 7A,
We n o w
is
respect
Ch. set
VII,
178
f
M : {h • H~(R):
| J
h(b)f(b)dXa(b)
: 0
for any
f • K'(a)}.
AI Since
K'(a) ±
plies that ideal of in I
is weakly* closed in
M
is a B-closed subspace of
H~(R),
H~(R).
L~(dXa ), Corollary
for
K'(a)
h/l
Jn(a) ~ M
was defined in Ch. VII,
6B.
Ch. VII, IA) is bounded.
M
is an
(c), there exists a bounded inner l.a.m.
M = {h ~ H~(R):
We claim that
Moreover
is closed under m u l t i p l i c a t i o n by functions
By our hypothesis
such that
H~(R).
5D, Ch. IV, im-
is bounded on
for every In fact,
So for any
R}.
n = i, 2,..., where
if
]hl/g n(a)
h • Jn(a),
f • K'(a)
Jn(a) (ef
we have
n
Ifh[exp(- [ g(',zj)) j:l
:<
Iflg (a) • lhl'Ig n(a)
where the r i g h t - h a n d side has a h a r m o n i c m a j o r a n t on
f
fh
is X a - S U m m a b l e and
A^
£i fh dXa : f(a)h(a) Therefore
By the weak
R.
^^
Cauehy t h e o r e m (Theorem 4B, Ch. VII),
,
: 0.
h E M, as desired. U co
Since
n=l Jn (a)
6B, Ch. VII, we have H~(dXa ).
In
has no n o n c o n s t a n t common inner factors by Lemma I = i
and thus
M = H~(R).
Namely,
K' (a) ± --
partieular,
I
~
d× a
= 0
At for
any
f C K'(a),
(b)
~
(a):
which
This
is
is
clearly
trivial.
equivalent
to
( D C Ta) .
[]
NOTES There have a p p e a r e d so many papers on invariant case of Hardy classes~ with different
flavor are found in Gamelin
[34] and others. Forelli
the origin is Beurling
subspaces.
In the
Detailed accounts
[i0], Helson
[33], H o f f m a n
The case of compact b o r d e r e d surfaces was studied by
[9], Sarason
[60], Voichick
[66, 67] and Hasumi
As for doubly invariant subspaces, in Hasumi and Srinivasan [17].
[2].
[23].
As for simply invariant
was proved in Hasumi
an abstract general t h e o r e m is
The case of Riemann surface is in Hasumi subspaces,
the main t h e o r e m
[17] under a s t r o n g e r assumption.
sion is due to Hayashi
[16].
[27], t o g e t h e r with T h e o r e m 5A.
(Theorem 4C)
The present ver-
CHAPTER
IX.
In the invariant
preceding
subspaces
investigation these
CHARACTERIZATION
chapters
on PWS's.
further
we h a v e
We are n o w
a n d to e x h i b i t
OF P A R R E A U - W I D O M
studied going
intimate
Cauchy
to p u s h
TYPE
theorems
and
our p r e v i o u s
relations
existing
among
things. Our o b j e c t i v e
inverse
Cauchy
speaking, those the
two
OF S U R F A C E S
in this
theorem.
chapter
Here
we find
PWS's
are
characterized
for w h i c h
the
inverse
direct
Cauchy
theorem
exist
PWS's
for w h i c h
which
PWS~s
satisfy
Chapter
VIII,
5A,
(DCT).
(DCT).
theorem As we
holds.
shall
Thus
We h a v e
already
emphasis
we l o o k
fact
hyperbolic
fails.
the
First
a remarkable
among
Cauchy
(DCT)
so that
is t w o f o l d .
see
that,
should
the
roughly
Riemann
surfaces
Next
investigate
we
in C h a p t e r
it is n e c e s s a r y had
into
X,
as
there
for us to tell
a criterion
for this
n o w be p l a c e d
on o t h e r
in
conditions. In
§i we
terizes 2D. R
show that
PWS's,
And
in
satisfy
(DCT).
i.
to a v o i d
that
nonconstant
THE
R
INVERSE
IA.
point
fix
map
Martin
R
point
boundary da(9) 0
formations
A
: d8/2~
(Theorem for
~.
of on 7B,
role
theorem
which
will
F0(R)*
hyperbolic
stated
make
be p l a y e d
corresponding
complication
AND
SURFACES
notations.
covering
is a m e a s u r e - p r e s e r v i n g
sure
value
Riemann
in
a given
PWS
by c e r t a i n to
we a s s u m e
charac-
R.
through
surface
this
carrying
OF P A R R E A U - W I D O M
TYPE
Result
some
a universal
a mean
essentially
functions.
THEOREM
of the M a i n
We first
~ = ~R
principal group
a connected
analytic
theorem
of c o n d i t i o n s
unnecessary
CAUCHY
Cauchy
being
a couple the
denotes
bounded
Statement
and
There
inverse
on the c h a r a c t e r
In o r d e r
§i.
crucial
~2 we p r o v i d e
functionals
chapter
the
the
of the with
T Ch.
unit
respect
and
Let D
0
~ R
7C,
Let Ch.
be a f i x e d with
~(0)
circumference
T
TR III,
measure
be the TR
dX
group
point = 0.
in
the
Lebesgue on
R
Then
into
to the n o r m a l i z e d
the h a r m o n i c
III).
By T h e o r e m
map
AI
of c o v e r
is c a n o n i c a l l y
meaat the
transidenti-
180
f i e d w i t h the f u n d a m e n t a l A measurable acter
~ • T{
a c t e r of
Q
if
Q
F0(R). on
Q O T = ~(T)Q
is d e n o t e d
is an m - f u n c t i o n 0 < p ~ ~
group
function
Q
by
T a.e.
6Q.
on
T
with character
= {f • H P ( ~ ) :
~
~
an m - f u n c t i o n
for any
An i - f u n c t i o n
and for any c h a r a c t e r HP(~,~)
is c a l l e d
TR
T • T R.
The c h a r -
with character
such that
of
with char-
IQI = i
~
on
a.e.
For
we set
f o ~ = ~(T)f
for any
T • T R}
and HP(do,~)
= {f E HP(do):
fo T = ~(~)f
For the sake of s i m p l i c i t y function
on
stance,
F • HP(D,~)
notes
~
is c a l l e d p - o u t e r
means
if
nonconstant
common
for all
with
acter
p
HP(~,~)
acter common
HP(dx,Q)
inner factor
IB. R
on
T E TR}.
for a h o l o m o r p h i c on
while ~.
~.
For in-
F • HP(do,~)
A character
equivalently,
HP(do,~))
outer
G i v e n an i - f u n c t i o n
Q
~
de-
of
TR
has no
if it is p - o u t e r on
~
with char-
is c a l l e d
R
Q'
of
We now b r i e f l y
for
and
recall
g z E R t.
theorem
t(O)
If
meromorphie then there
q
IC,
u* • LI(dx) on
VII)
an
on
~
Cauchy
t h e o r e m on PWS's.
PWS and
Rt
V.
gt(a,z)
l.a.m,
satisfies
Let
the r e g u l a r i z a t i o n
f • HI(R)
be the G r e e n
points
according
in
Rf
of
to m u l t i p l i c i t y .
w e Z(0;Rt)}) on
R
and the i n v e r s e
Cauchy
the f o l l o w i n g :
fA I h ( b ) u * ( b ) d x ( b )
h(0)
so that
HP(dx,Q).
the set of c r i t i c a l
states
char-
the g r e a t e s t
is a g a i n an i - f u n c t i o n ,
w h i c h we r e p e a t
R, such that
exists
3B, Ch.
is an i n n e r Ch.
Q
for
(z) = exp(- [ {gt(z,w):
Then
(Theorem
if the c o r r e s p o n d i n g
the i n v e r s e
regular)
Z ( 0 ; R t)
the f u n c t i o n z ÷ gt(0,z), Set q = gt(0)IR , where
I)
e x p r e s s i o~n
sense of T h e o r e m Rt
standard
HP(do,~
is the s t a n d a r d
in the
fo $ • QHP(do,<~I)}.
For any i - f u n c t i o n
be a (not n e c e s s a r i l y
function
(ICT)
~,
It is c a l l e d
: {f • LP(dx):
is p-outer.
H P ( d x , Q Q ')
for
(or,
for any
~Q, we set
An e x p r e s s i o n
of
~
function
on
function
factors.
i ~ p ~ ~.
HP(dx,Q)
Let
value
a function
boundary
inner
on
we use the same l e t t e r
and for its b o u n d a r y
the c o r r e s p o n d i n g
a.e.
= 0
and
such that
lhlq u* = f
= 0
for any
is b o u n d e d a.e.
on
on AT"
h, R,
181
Let
Q
IQI = q O ~. i.e.
be the inner function on
•
Then the character
is identified
~Q : ~q h
says that
h O @(0)
{T(0): tion
T • T R}
D,
{T(0):
ulus one such that and
to
(hO ~)(T(0))
of
T~
onto
= { F e H (D):
= 0
for any
so that we can find a Blaschke
with the same zeros as
belongs
isomorphism
Q(0) ~ 0
and
with that of F(0)
Since
BO m
product
Thus,
namely,
have no common (~,n
~Q);
B
zeros,
for
We also
So
ho
h • H (dx,B/Q).
follows that the inverse
Cauchy theorem is expressed as
(i)
H~(dx,B/Q) ± ~ HI(dx),
where the orthocomplement
of mod-
~.
0 ~ Z(0;Rt).
in other words,
whose
product
n(T)
has character
func-
B
is a Blaschke
is formed with respect
The
= 0}.
• • T R.
B, there exists a complex number
B o T = n(T)B; B
(B/Q)H
T • TR}.
q,
F0(R).
is a subset of the zeros of the bounded analytic on
zeros are exactly
Q
such that
(hO ~)Q E H ~ ( ~ )
: 0, we have
(ho ~)Q
see that
Q
under the canonical
condition on Since
of
It
to the dual pair
(LI(dx),L~(dx)). The inverse LI(dx)
Cauchy theorem shows that the invariant
given by
H~(dx,B/Q)
H~(dx )±
~ HI(dx,B/Q),
has a special we infer from
form.
In fact,
subspace
in
since we have
(i) that
HI(dx,B/Q) ± ~ H~(dx,B/Q) ± ~ HI(dx) and therefore
that
HI(dx,B/Q) ± ~ HI(dx ) N L ~ ( d x ) : H~(dx ).
that
H~(dx) ± ~ HI(dx,B/Q).
have
{H~(dx)±} I ~ (B/Q)HI(dc~); namely,
simply invariant IC.
subspace
Using the notations
of
This means
in Ch. VIII, we thus
{H~(dx)±} I
is seen to be a
Ll(do).
Using the notations
in IA, we now state our main result of
this section. Theorem.
Consider the following
mann surface
R
three conditions
carrying nonconstant
(a)
R
(b)
There exists an inner l.a.m,
for a hyperbolic
bounded analytic
Rie-
functions:
is a PWS.
Cauchy theorem
(ICT) is valid:
I
namely,
q if
h(b)u*(b)dx(b)
on
R
for which the inverse
u* E Ll(d×)
satisfies
0
41 for any on
h, meromorphic
R, then there exists (c)
on an
H~(dx )± ~ HI(dx,Q)
R, such that f E Hl(R)
h(0)
= 0
such that
for some i-function
and u* : Q
on
lhlq a.e.
is bounded on
T, where
AI .
182
H ~ ( d x )i : {f* E LI(dx):
[ J
Then,
we h a v e If
are
= 0
for any
h C H~(R)}.
(b) <=> (c).
separates
the
points
of
R,
then
all
these
conditions
equivalent.
ID. show
We h a v e
explain
our
given
(c) ~
for r e a d e r s '
(and h e n c e
all)
ml(a)
(b) ~
(c).
proof
is not
convenience.
The p r o o f
the
of
R
(c) ~
a E R, w h e r e
instead
of
result
(b)
if m(a)
m(a).
was
More
defined
a mean
in in
if)
generally,
we
3A.
is devalue
The
3B-3J.
m(a)
> 0
in Ch.
V,
to
first
subsection
being
is g i v e n
(and o n l y
only
so short,
is s t a t e d
assumption
is a PWS
So we have
The next
the m a i n
additional
V, a s u r f a c e
now w r i t e
(a) ~ As the
observations,
in 2D.
(a) u n d e r
in Ch.
some
plans
in IB that
implication.
to p r e l i m i n a r y
theorem
saw
seen
the r e m a i n i n g
voted
of
(a) ~
H~(R)
~f*dx AI
proof
As we for 8A.
we use the
We
follow-
ing n o t a t i o n s : mP($,a) for
a E R
and
= sup{if(a)I:
shall
finally
separates steps,
on
that
R
(i)
measure
and
of the
dx).
IIflIp,a =<
i)
R.
This
~ K
will
for any
the
(iii)
every
outer
if
Blaschke
(c) h o l d s
and
by showing,
character
of e v e r y
character
to the proof,
of
~, w h e r e
finite
F0(R)
if
H~(R)
in t h r e e K > 0
Blaschke
product
can be a p p r o x i -
products.
we n o t e
of the o r i g i n
To see this,
> 0
be d o n e
character
of f i n i t e
choice
6 E F0(R)*}.
m ~( 0)
3J that
(ii)
proceeding
independent
in
m~(6,0)
by c h a r a c t e r s Before
= inf{mP(~,a):
of
constant;
is outer;
mated
prove
the p o i n t s
is a f i x e d
, ~),
~ E F0(R)* , and also mP(a)
We
f E ~P(R
(or,
that
the c o n d i t i o n
equivalently,
(c)
is
the h a r m o n i c
we d e f i n e
N a = {f* e L l ( d X a ): J r
hf*dx a = 0
for any
h E H~(R)}
AI for
a E R, w h e r e
i.e.
dXa(b)
HI(dx,Q) simply
for
b E A I.
such
that
is the h a r m o n i c
= kb(a)dx(b) some
invariant.
for
dXa
(Ch
i-function N o w take
By use
III
•
Q
any
of H a r n a c k ' s
c -I ~ s ~ c
a.e.
on
~
measure
2C)
on
T
Then
.
R
and
inequality This
we
at the p o i n t
it is c l e a r
if and o n l y
a, a' E R
A I.
of
set
{Na} I
s(b)
find
implies
if
that
N a =C is
= kb(a')/kb(a)
a constant
that
sNa,
of
dXa , = sdxa , and
therefore
that
c > O
= Na,
A
because
a,
{Na} I : (s o @ ) { N a , } l .
183
Since the multiplication of
by
so $
Ll(do), we conclude that
only if
eiS{Na'}l
defines a bicontinuous
ei@{Na} I
is Ll-dense
in
is Ll-dense in
a E R,
H=(dXa )± ~ HI(dX,Qa )
I
(c), IC, holds.
to the assumption that, for every
for some i-function
H~(dXa )± = {f* E LI(dx):
if and
{Na,} I, as was to be proved.
In what follows in §i, we assume that the condition As shown above, this is equivalent
isomorphism
{Na} I
hf*dXa = 0
Qa
for any
on
T, where
h C H~(R)}.
A1 IE.
Remark.
We just look into the excluded case in which
contains only eonstant functions. tions
f* E LI(dx )
function in
We also know that every
So if the condition AI
(e), IC, holds, then
cannot be divided into three disjoint
subsets of positive measure.
most two linearly independent harmonic this matter further.
2.
H~(R)
consists of all func-
cannot vanish on a set of positive measure with-
identically.
the Martin minimal boundary measurable
H~(dx) ±
~A I f*dx = 0.
such that
HI(dx,Q)
out vanishing
Then
This means that functions.
R
carries at
We will not go into
A Mean Value Theorem 2A.
We now begin our preliminary observation
(b) and (a) in Theorem IC. surable function,
say
QA' on
By the condition T
{H~(dx)±}I Since
{Hm(dx)±}l
with
for the proof of (e)
(c) there exists a mea-
IQAI = I
a.e. such that
: QAHI(d~).
is invariant under
TR,
QA
is seen to be an i-func-
tion and H~(dx) ± ~ HI(dx,QA ), the right-hand acter of
Q~I.
inner factor of
side being a standard expression. Then
6A
is 1-outer.
HI(d~,~A).
Let
To see this, let
~A
be the charQ'
be a eommon
Then
H~(dx )±o $ ~ QAHI(do,{A ) ~ QAQ'HI(d~) and therefore
QAHI(d~)
= {H~(dx)±}I ~ QAQ'HI(d~).
Hence,
Q'
should
be a constant function, as desired. We set I 0 = HI(dX,QA)±~ which is seen to be a weakly ~ closed ideal of
H~(dx ) .
This ideal plays an important role in the following inves-
184
tigation. In the following, [.] denotes the closed (weakly* closed, P if p = =) linear envelope in the space LP(dx). First we show: Lemma.
H~(dx )± = [10HI(dx,QA)] I.
Proof. If f* @ I0, h* E HI(dx,QA ) and longs to HI(dx,QA ) and thus f* ± h'u*.
u* E H~(dx), then h'u* beIt follows that f'h* is
orthogonal to H~(dx ). Namely, [IoHI(dx,QA)]I ~ H~(dx) ±. Next we take any f* E L~(dx) which is orthogonal to the set IoHI(dx,QA ). Then, for any h* E HI(dx,QA ), f'h* C I0 ± : HI(dx,QA )±± = HI(dx,QA ), which implies (f* o $)(HI(dx,QA ) o $) ~ HI(dx,QA ) o $. Since
~A
is 1-outer, we have
f* E H~(dx ). So obtained. [] 2B.
Lemma.
(f* o $)QAHI(do)
[IoHI(dx,QA)]I ± ~ H~(dx)
I0 o $
$ QAHI(do)
and thus
and the desired result is
has no nonconstant common inner factors.
Proof. Let Q' be the greatest common inner factor of I 0 o $. I 0 o $ ~ Q,H~(do) and therefore I 0 ~ H~(dx,Q'). So we have
Then,
10HI(dx,Q A) ~ H~(dx,Q')HI(dx,QA ) ~ HI(dx,QAQ'). Using the preceding lemma, we get QAHI(do) 2C.
= {H~(dx)±}I ~ QAQ'HI(do). Here we determine
Lemma. Let Q p ~ ~ and let HP(dx,QQ'), (2)
H~(dx )± ~ HI(dx,QA Q') Hence,
Q'
and so
is a constant.
[]
HP(dx,Q) ±.
be an i-function such that H=(dx,Q) ~ {0}. Let i Q' be an inner function on ~ such that HP(dx,Q)
the right-hand
side being a standard expression.
=
Then,
HP(dx,Q) ± = [IoHP'(dX,QA/QQ')]p,
and (3)
[IoHP(dx,Q)] p i = HP'(d X 'QA/QQ, ) ,
where p' = p/(p- l) and the orthocomplement the dual pair (LP(dx), LP'(dx)). Proof.
is formed with respect to
In view of Lemma 2A we have IoHP(dx,Q)HP'(dX,QA/QQ')
~ IoHI(dx,Q A) ~ H~(dx )±,
185
which in turn implies (4)
10HP'(dX,QA/QQ')
~ HP(dx,Q) ±
and (5)
HP'(dX,QA/QQ ,) =c [10HP(dx,Q) ]p ±.
Next, let
s* • [10HP(dx,Q)]p ±
If
f* • HP(dx,Q)
and
h* • I0, then
f*h*s ~ • H~(dx) ± ~ HI(dx,QA ). We employ the fact f* o $ = QQ'F with ,~QQ,-I) -I F • HP(do and get (s* o ~)(h* o ~)QQ'F e QAHI(d~). Since ~QQ, is p-outer, we have Lemma 2B,
I0 o $
(s* o $)(h* o $) • (QA/QQ,)HI(do).
has no nonconstant
s* o $ • ((QA/QQ,)HI(do)) NLP'(do) belongs to
HP'(dX,QA/QQ').
Moreover,
by
common inner factors and therefore
= (QA/QQ')H p (do).
Consequently,
s*
Combining this with (5), we have the T
equality
(3).
On the other hand,
suppose
s* • [10HP (dX,QA/QQ')]p, ±
If h* • I0i then h's* • HP'(dX,QA/QQ') ± = [10HP(dx,Q)] p ~ HP(dx,Q). Since I 0 o ~ has no nonconstant common inner factors, we get s * • HP(dx,Q). Namely, [10HP'(dX,QA/QQ')]p, m ~ Hp (dx,Q) , which, together with (4), implies the equality 2D.
~
such that
Qg(0) ~ 0
and
Let
Qg
be
IQgl = exp(_g 0 o ~),
g0(z) : g(0,z) is the Green function for R with pole 0. Let denote the ideal of H~(R) consisting of functions vanishing at
the origin 0. Since R lytic functions, we have
is assumed to carry noneonstant
H~(R) We see that
(exp g0)H~(R)
therefore that function
Q~
~
! H~(dX,QgQg)
Let now
QC
dard expression
consists of bounded functions on
R
and
By Lemma 2C there exists an inner
such that ±
= H~(d×,Qg
)±
=
[IoHI(dx,QA/QgQg)]I, ,
is the standard expression for be an i-function
for
bounded ana-
~ {0}.
H0(d X) = H~(dX,Qg). on
H0(d X) where
[]
We are now able to prove a mean value theorem.
the inner function on where H~(R)
(2).
HI(dx,QA/QgQ~)
such that and let
H~(dX,Qg)
HI(dX,Qc -I) ~C
is the stan-
be the charaeter of
QC" As we have i • HI(dX,Qc-I), so we see that QC represents inner function on D. We may suppose, in what follows, that Qc(O) > o.
an
186
Thus every element f* in H0(d X) is regarded as the boundary function of a meromorphic function f, of bounded characteristic, on R, so that its value at 0 is determined. Theorem.
For every
f* E H0(dx )±
we have
f(0) = I
f*(b)dx(b)" AI
Proof. Since H~(dx )m = [10HI(dX,Qc-I)]I ~ HI(dX,Qc-I), each f* in Ho(dx )± determines an F E HI(~) such that f o ~ = Qc-IF, where f is the meromorphic extension of f* into R. We define a linear functional L on H0(dx )± by setting L(f*) = F(0). Since we have IL(f*)I = IF(°)I ~ S
IF(eiS)Id°(8)
t = J
If*(b)Idx(b)
: I T
IQc(eiS)-iF(eie)id°(e)
: IIf*IJl,
AI the Hahn-Banach theorem says that L has a norm-preserving extension to LI(dx). So there exists a function u* @ L~(dx ) such that Iiu*II = IILII < i and =
F(D) : I
f*(b)u*(b)dx(b) AI
for every f* E H0(d X) ± . belongs to H~(dx )± and that I
If f* E H ~ (dx) ± and h E Ho(R) , then ~f* (fif*) o $ = (~o $)(f* o $) = (~o $)Qc-IF, so
hf*u*d X : L(hf*) = (hO %)(O)F(0)
: 0.
AI As h E H~(R) is arbitrary, f'u* E H~(dx )± ~ HI(dX,Qc-I). Therefore, Qc-IF.(u * o $) E Qc-IHI(do), where F ranges over (I 0 o $)Hl(do,~C ). Since (I 0 o $)Hl(do,~C ) has no nonconstant common inner factors, we conclude that u* belongs to HI(dx ) and consequently to H~(dx ). It thus follows that, for any f* E H~(dx )±, (6)
F(0) = S
f*u*dx = I Al
f*(u*-u(0))dx
+ u(0) I
£i
: u(0) S
f*d X AI
f*dx. A1
Since
HI(dX,$c )
has no common inner factors,
it has no common
187
zeros. over, an
Namely, since
there
I0 o $
h e I0
with
exists
an
F 0 E Hl(d~,[C )
has no noneonstant h(0)
# 0.
Let
common
f~ e LI(dx )
(~ o ~) Qc-IF0 " Then, f~ E H0(d ~ X) ± and fl is the meromorphic extension of f[ corresponding FI(0)
~ 0
we have any
to this
f[
and hence, F = QC
u(0)
~ 0.
and so, again by (6),
f* C H0(d X)
FD(0)
be defined
by
# 0.
More-
there
is
f{o $ =
fl o ~ = (hO ~)Qc-IF0 , where into R. The function FI
is thus equal to
by (6),
with
inner factors,
(hO %)F 0.
Consequently,
In particular, QC(0)
= u(0)
for
~ 0.
f* ~ i
Hence,
for
, S
f*dx
= u(0)-iF(0)
= QC(0)-IF(0)
AI =
as was to be proved.
3.
= f(0),
[]
In the proof we have Corollary.
(f o ~)(0)
shown the following
IQc(O) I # o.
Proof of the Main Theorem 3A.
We are now in a position
Theorem. Let
Let
phic on
Let
can find an function h
satisfy
R, such that
exists
Proof.
Let
be the inner l.a.m,
u* 6 LI(dx )
there
Then hand,
qc
h*
an
Ihiq C
is bounded such that Since
F E Hl(da,~C )
such that
being bounded,
F
function
h(b)dx(b) A1
the last equality hypothesis
is arbitrary, proved.
[]
we conclude
= 0
on
R
u* = f
q c ° % : IQCI.
for any
and a.e.
h(0) on
h* o $ = Qc-IF
on
h, meromor= 0~ then
A I.
R
with
= I
a.e.
on
T.
we The
i.e.
F E H~(da,~C )D. h O # = Qc-IF on
h* : h a.e. on 2D implies h*(b)dx(b)
On the other
A I.
= O'
A1
sign being true because
in the theorem
such that
is also bounded,
is bounded on R and h* E H~(dx) l, Theorem = I
R
(c) ~ (b).
HI(dx) ± ~ H0(d X) ± ~ H I (dX,Qc-I),
h* 6 HI(dx) m.
h(O)
on
/£I h(b)u*(b)dx(b)
f E HI(R)
be a meromorphic lhlqc since
to prove the implication
h* A I.
and thus
/A I u*h*d X = 0.
that
belongs
u*
to
So As
HI(dx),
h
satisfies h* C HI(dx) ±
as was to be
the
188
3B.
We now begin the proof of the implication
assumption that H=(R) separates the points of we have to look into HP(do,<) more closely.
R.
(e) ~ (a) under the For this purpose
Lemma. Let ~ • T[ with H~(do,[) ~ {O} and let Qp be the greatest common inner factor of HP(do,[), i ~ p ~ ~. Then Qp are the same up to constant
factors of modulus
one.
Proof. Take any nonzero F • H~(do,[) and set Q : [F[/F. Then Q is an i-function with character [-i. So QHP(da,[) consists of T Rinvariant functions and HP(dx,Q) o $ = QHP(do,6). Our definition of Qp shows that HP(dx,QQp) is the standard expression for HP(dx,Q), i p ~ =. Since Qp divides Qq for p < q, we have only to show that Q~
divides
QI' i.e.
QI/Q~
is an inner function.
By Lemma 2C
HI(dx,Q) ± = [ 1 0 H ~ ( d X , Q A / Q Q I ) ] (7) H~(d×,Q) ± : [10HI(d×,QA/QQ Since in
H~(dx,Q)
H=(dx,Q) m.
)]i .
= HI(dx,Q) n L~(dx ), we see that Combined
this with
HI(dx,Q) ±
is Ll-dense
(7), we have
H I (dX,QA/QQ I) ~ [10H (dX,QA/QQI)] I = [HI(dx,Q)±]I = H=(dx,Q) ± = [10HI(dx,QA/QQ~)]I . Since I0 o $ has no nonconstant common inner factors, we infer that H I (dX,QA/QQ I) ~ H I ( d X , Q A / Q Q ) . Since QI divides Q~, we thus have HI(dx,QA/QQI ) = HI(dx,QA/QQ ). Consequently, H=(dX,QA/QQI ) = HI(dx,QA/QQI ) A L ~ ( d x ) = HI(dx,QA/QQ
) NL~(dx)
= H=(dX,QA/QQ
)
and therefore (8) Since
[IoH~(dX,QA/QQI)]~ H~(dx,QQ
)
is standard,
= [10H~(dX,QA/QQ=)] so is
HI(dx,QQ~) ± = [IoH~(dX,QA/QQ
HI(dx,QQ
that
HI(dx,QQ
By (8) and Lemma 2C
)]~
= [IoH~(dX,QA/QQI)]~ This implies QI" []
).
.
) = HI(dx,QQI )
= HI(dx,QQI )±. and hence that
Q~
divides
189
3C.
Consider any
~ • T~
i ~ p ~ ~
and let
HP(d~,~).
Take any nonzero
so that Q and define
Q~
with
HP(do,~)
~ {0}
for some
p
with
be the greatest common inner factor of the space F0
from
HP(do,$)
and set
Q = IF01/F0,
is an i-function with character ~-i. We set M = HP(dx,Q) M A as the orthoeomplement, in L p' (dx), of the space
H0(dx)M , where
p' = p/(p - i).
Lemma. in 2D.
M ~ $ HP'(dx,I/QQ~Qc) , where
Proof.
Let
h* • M ~.
Then,
(h* o $)QQ6HP(do)
QC
is the inner function defined
h*M ~ H~(dx) ± ~ HI(dx,I/Qc )
and so
= (h* o $){M}p ~ {h'M} 1 ~ (I/Qc)HI(do).
This means that h* o $ • [(I/QQ~QcHI(do)] N L P ' ( d o ) Hence,
M A ~ HP'(dx,I/QQ~Qc).
3D.
Lemma.
outer, then
Let
[]
$ • T~
and
HP'(do,$-I~c ) ~ {0}
i ~ p < =
Let
F0
be any nonzero element in
= IF(0)] ~ I
If
~
is p-
~ IQc(0)i. HP(do,~)
IF0r/F 0. We then define a linear functional L setting L(f*) = F(0), where f* o $ = Q0 F with F • HP(do) ~ Hl(do), we have
IL(f*)i
be given.
and
mP(~,O)mP'(~-I$c,O) Proof.
~ (I/QQsQc)HP'(do).
IFldo = I
and set
Q0 =
on M = HP(dx,Q0 ) by F • HP(do,~). Since
IQoFldo = I
~
If*Idx AI
= ilf*liI ~ Elf*Up. By the Hahn-Banaeh that
theorem there exists a function
llv*lip, = IILII and
If f* • M so that
and
I
F(0) = L(f*)
h • H~(R),
then
hf*v*d X = L(hf*)
= fA I f*v*d X
hf* • M
and
v* • LP'(dx) for every
such
f* E M.
(~f*) o $ = (~o $)QoF,
: ((ho %)(0))F(0)
: 0.
Al As h C H (R) is arbitrary, f'v* • H0(dx) ±. This implies that v* belongs to M A. Since M m ~ HP'(dx,I/QoQc) by Lemma 3C, there exists
190
a
V e HP'(do)
with
v* o $ : (QoQc)-Iv
and therefore
Qc-IFv with FV E Hl(do,6C ). Namely, Qc-IFv meromorphie extension of (f'v*) o $ into D. (9)
QC(0)-IF(0)V(0)
: I
(f'v*) o $ =
is the TR-invariant By Theorem 2D we get
f*v*dx = L(f*) = F(0). Al
Since
$
has been assumed to be p-outer,
and thus one can find an
f* E M
HP(~,~)
such that
has no common zeros
F(0) ~ 0
with
f* o $ =
Q0 F. It follows from (9) that V(0) = QC(0) ~ 0, the last inequality sign being true in view of Corollary 2D. Finally, Since
our definition of
V E H p' (do,~-16 C)
Iv(0)I/llV*Up,.
and
mp
3E.
We know that
= IILIJ = llv*HpT. m p' (~-i~ C ,0) =>
H~(d~,~C ) ~ {0}.
Suppose now that
~ IV(0)1 : IQc(0) I > 0.
HI(dx,Q~ -I)
On the other hand,
so that outer.
mP(~,0)
Hence,
mP($,0)mP'(~-I~c,0)
1-outer.
shows that
llVllp, = IIv*11p, , we have
[]
is standard and therefore
H (do,~ C)
It then follows from Lemma 3B that
~ E T~
is 1-outer.
is
~C
QC
is
Then, because of the inclu-
sion relation Hl(d~'~)H~(d°'~C ) ~ H l ( d ° ' ~ C )' So, by Lemma 3D, m ~(~-i ,0) ~ m l ( ~ c , O )m~((<
~C
contains the inner function
~C
is also 1-outer.
~ ]Qc(O)I
H~(d~,~ -I) ~ {0}.
> O.
We further see the
following Theorem. Proof.
If
~
is 1-outer,
We have shown that
then
~-I
is outer.
H=(do,6 -I) ~ {0}.
common inner factor of H~(do,$-l). P, then 6-1~p-I is outer. Since
If
~p
Let
P
be the greatest
denotes the character of
H=(dO,~p)H=(do,~-l~p -I) ~ H=(do,$-l), H~(dO,~p)
should be divided by
PH=(do,Id), where Id of induction we have
oo ]1 H (dO,~p)
(lO) for
n = i, 2, . . . .
P.
We thus conclude that
denotes the identity character of
= pnH~(do,ld)
On the other hand,
H~(dO,$p) T R.
By use
=
191
H~(dO,~c)Hl(do,~)H~(do,~-l~p-l) In view of our h y p o t h e s i s , inner
factors
is 1-outer. i, 2, . . . .
By Lemma
n
3D and
~
3F. that Let
then
and
Let
that ~-i
Q0
Namely,
~0
above
~
~0
(a)
IlTII < i
~p-l~ C
~
for
n =
IQc(O) I > 0.
is a constant,
as was
T
the f o l l o w i n g
for some
Using
common
of
p
with
i ~ p < ~.
operator
T
is a n o n z e r o
of
H~(R) o $
in 2D, we have
So there
and
exists
liP011~ ~ 1/2.
Q0 =
function
a function
For any
in
H~(D),
h o ~ = (p0/Q0)(f o ~ - f(0)).
in
so
e x p r e s s i o n for H~(dX,Qg). -i ~0 is o u t e r and, by the
Then
too.
~ 0
factor
standard
Q0"
with
inner
the n o t a t i o n s
is the
is a T R - i n v a r i a n t H~(R)
bounded
by setting
linear
P0 ~
f E H~(R), so that we We then
Tf = h.
operator
in
H~(R)
with
and
(Ii)
T(fg)
for any
= (Tf)g
+ f(0)Tg
f, g E H~(R).
(b) Then,
P
immediately
is p - o u t e r
P0(0)
h E H~(R)
a linear
almost
is outer,
such that
(p0/Q0)(f o ~ - f(0))
Lemma.
and h e n c e
be the g r e a t e s t
be the c h a r a c t e r
find a unique define
i.e.
is 1 - o u t e r
are outer.
H~(dx,Q0 )
corollary,
H~(do,~0 )
= i
implies
H 0 ( d X) = H ~ ( d x , Q 0 ).
QgQg.
side,
~p-n~c
(i0) we get
IP(0)I
Suppose
Then both
the r i g h t - h a n d
we see that
common
[]
The t h e o r e m Corollary.
side has no n o n e o n s t a n t
~ ml(~p-n~c,0)m~((~p-n~c)-l~c,0)
is a r b i t r a r y ,
to be proved.
so does
by i n d u c t i o n
IP(0)I n = m ~ ( ~ p n , 0 ) As
the l e f t - h a n d
and t h e r e f o r e Again
~ Hl(do,~p-l$c).
Define
T~f = (Tnf)(0)
IIT~II ~ i
for
for
n = 0, i,...
f E H~(R)
and
n = 0, i, . . . .
and
(i2) j=0 for any Proof. f(0)
f, g E H~(R). (a)
= Q0F
T
is o b v i o u s l y
with IITfll
linear.
F E H~(do,~0-1). = II(Po/Qo)QoFII
For
f E H~(R)
we w r i t e
Then ~ = IIPoFII ~ ~
IIPoII
IIFII ~
fo $ _
192
= lip011 IIf-f(0)II ~ % 211P011 IIfll~ =< IIfII~. This means there
that
exists
and t h e r e f o r e
of (ii)
For
IIToII < 1.
hand,
such that
: P0(0)F0(0)
since
~0 -I
f0 o % = QoF0
~ 0.
Thus
T
is outer,
with
F0(0)
~ 0
is n o n t r i v i a l .
The
is easy and is omitted.
f E H=(R)
IT0fl so
On the o t h e r
f0 E H0(R) (Tf0)(0)
verification (b)
IITU ~ i.
an
we have
= l(Tnf)(0)l
= II
(Tnf)dxI __< llTnf'l < "fI' ; 41 (12) follows i m m e d i a t e l y from the r e l a t i o n
The i d e n t i t y
n
Tn(fg)
which
can be shown 3G.
ivation set
s
Lemma. in
by an easy
We now expand T.
Since
and
For every
< i}
For every The map For every
(14)
(b) (c) 3F.
If
with
(a)
by means
the f u n c t i o n
%
This
of the point
for
I[I < I.
% ÷ ~ f
is h o l o m o r p h i c
I~l < i, the f u n c t i o n a l on
f ÷ ~ f
H~(R).
l~I < I, is injeetive.
h E H0(R)
and
f E H (R)
we have
f) : ( T h ) ( f - ~[f)
I[[ < i. is almost
follows
Let
f0 E H0(R) with
clear,
easily
satisfy l[I,
for
from Lemma I~'I
S
= ~n=0 3F and
~nTn"
(13).
T0f 0 f 0, as in the proof
of Lemma
< i, then
¢~((I- ~T)(I- {'T)f 0) = ¢~,((I- ~T)(I- {'T)f 0) and thus (d)
derWe
~n(T~f).
with
~ ÷ ~%,
This
~{ = }~,
[ n:0
homomorphism
(h - ~Th)(TS
Proof.
H~(R)
is i n v e r t i b l e
= (S f)(0).
f E H~(R)
fixed
complex
(c)
%
in
[]
and
(d)
for any
(Tn-]f)(0)TJg,
induction.
~ f =
(b)
[ j:l
I - IT
~f
(13)
a nontrivial
+
functions
IITH ~ i,
= (I - IT) -I (a)
{I%I
: (Tnf)g
~'(T0f 0) = ~(T0f0). Since T0f 0 ~ 0, we have In view of the i d e n t i t y (ii), we have
~ = ~'
is
193
T(hS{f)
: (Th)(S%f) : (TS{f)h
so that
(TS~f)h
= (Th)(S
f- ~f).
( h - ~Th)(TS~f) = (Th)(S for
( I - ~T)S~ 3H.
of
R.
= I.
an
= h(TS{f)
Since
f0 E H~(R)
by setting then
shows
for any ation
and
and @(z)
that
= ( T h ) ( f - ~%f),
[]
Tf 0 E H~(R) 0
follows
- ~(Th)(TS~f)
f - ~ { f - ~(TS%f))
H~(R)
separates
T0f 0 = (Tf0)(0)
(Tf0)(z)
(Tf0)(0)
R \ U0
that
with
U 0 : {z @ R:
the point
+ (S~f)(0)Th, From this
We now use the a s s u m p t i o n Choose
+ h(0)(TS~f)
# 0,
= f0(z)/(Tf0)(z).
and set
# 0}.
U0
is discrete.
~ 0
the points
is an open
We define
set c o n t a i n i n g
a function
An a p p l i c a t i o n
of
@: U 0 +
(14) to
h = f0
that
f E H~(R)
functional
and ~
f(z)
: %~(z)f
z E U O.
Namely,
at the point
z.
~(z)
Choose
is e x a c t l y any compact
the evalu-
neighborhood
z
U~
of the origin
morphic
function
a disk
{I61
Theorem.
0 on
U0
< r 0}
Suppose
Proof.~
We have
that
tinct
evaluation
means
that
spect
~
not vanish
R.
Let
0.
(c),
~g
IC, holds
and that
be the c h a r a c t e r
Q~
is a c o n s t a n t
R, d i s t i n c t
It follows
coordinate
at
T0f 0 ~ 0.
is an inner
Moreover
holo-
includes
that
0.
Q~
So factor
in
(d~/dz)(0)
Consequently,
f0 of
has no zeros
R
Since give dis-
remark,
this
So, by Lemma ~ 0
with re-
~ 0 zero at the
f0' we see that R.
Then
we have
has a simple in
H~(R)
Q~.
function. z
: (d~%f0/d6)(0).(d@/dz)(0)
with
QgQN'
z
points
of
E . C o m b i n e d with the above z for any d i s t i n c t z, z' E U0.
~ ~(z')
is an injection.
at
~(U~)
functionals
~(z)
Since
0, the image
of
f0 E H~(R) 0.
is a n o n c o n s t a n t
the points
to any local
for any
at
~
r 0 > 0.
the c o n d i t i o n
of
(df0/dz)(0)
point
Since
and v a n i s h e s
only to show that
separates
3G-(c),
U~ ~ U 0.
for some
separates the points -i ~9 is outer.
H (R)
with
Q~
If this were
cannot
194
the case, any
then
Q~(a)
f E H~(R),
contrary
= 0
so that
for some H~(R)
be a s i n g u l a r
inner f u n c t i o n .
T, we c o u l d c h o o s e would
IP01
Thus
f(0)
separate
: f(a)
the p o i n t s
= 0 of
for R,
to our b a s i c h y p o t h e s i s .
To get the final c o n c l u s i o n ,
P0/Q!~
a ~ 0.
c o u l d not
and
P0 E H ~ ( d ~ , ~ 0 )
be u n b o u n d e d .
k 0 o % = IQ~I.
bounded.
Since
there would
we suppose,
Then,
k0
exist
Let Thus,
h0(0)
P0(0)
be the l . a . m . ' s ~ 0
and
h0/k 0
~ 0
with
such that
(h0/k0)(Zn)
Q~
and
h0 o % =
w o u l d be un-
a w a y f r o m zero on the c o m p a c t
z n E U 0 \ U 0'
that
of the o p e r a t o r
in such a way that
h0, k 0
is b o u n d e d
on the c o n t r a r y ,
in the d e f i n i t i o n
÷ ~.
set
U~,
T h e n we
w o u l d have I¢(Zn) [ : I f o ( Z n ) [ / I ( T f o ) ( Z n ) I ~ k o ( Z n ) / h o ( z n) ÷ O. So, for a s u f f i c i e n t l y i n i t i o n of ~(Zn).
r0
This
shows
is, h o w e v e r ,
As we n o t i c e d of the o r i g i n Corollary.
q(z)
set
large
impossible,
n
= exp(-~j=l
Lemma.
be any c h a r a c t e r of
R, t h e r e
such that
~q(y)
denotes
~q
taken
R~,...,
let
yj,
R~'
{Uk:
that
YI'''''
Y~
CI(V). Fh0(R)
o k = O(yk ),
representing
i ~ k ~ N} in
Yk
V, then,
are linearly V
such that
of p o i n t s
in
[]
q(z)
y e F0(R)
q
R
of
and
q.
of
R.
subregion
= exp(-~j~l contained
and the p o i n t s
Then,
is outer.
the p o i n t s
for any c a n o n i c a l
Let G
g(~j,z))
in
G,
can be
same lines as that of Lemma
8B, Ch.
G.
of the c o m p o n e n t s contour
of
So a h o m o l o g y
nondividing
d i s k s u c h that
Let
=
of the c h o i c e
{¢j}
be an e n u m e r a t i o n
i ~ k ~ N, in
al,... , a N
of
s u b s e t of
G.
number
of the f o r m
for any curve
and c e r t a i n
@(z*)
is an i n j e c t i o n .
(c) is i n d e p e n d e n t
separates
Then, q
the c h a r a c t e r
to
The def-
with
~q
H~(R)
F0(R).
with respect
be a p a r a m e t r i c
in
R
an l.a.m,
= ~(y)
~
z* E U 0'
be t h e c h a r a c t e r as in the t h e o r e m , ~q - i
0 ~ j ~ ~, be the b o u n d a r y
positively
VkdY ,
Let
The p r o o f goes a l o n g the
Let
off
on
f r o m any f i x e d o p e n
Proof.
of
of
exists
where
for
be a f i n i t e
g(aj,z)).
Suppose
19(Zn) I < r O.
a point
we get the f o l l o w i n g
al,... , a n
u n d e r the same h y p o t h e s i s
31.
exists
in IC, the c o n d i t i o n
and t h e r e f o r e
Let
n, we w o u l d h a v e
that t h e r e
CI(V)
R \ CI(G)
Rj, ' which
basis
cycles
$ G
of for
Y~+I'''''
YN"
I, 9B).
If we w r i t e on
V.
Let
V
lie
differentials ok = U k d X +
as we saw in the p r o o f of L e m m a independent
consists
Yk'S
i ~ k ~ N, be the h a r m o n i c (Ch.
is o r i e n t e d
CI(G)
a n d the c u r v e s
V.
and
So t h e r e
8B, Ch.
exist
points
V,
195
A(al,...,a N) = det (uj(ak))l<j,k< N ~ 0. By identifying
V
with the unit disk,
~(Xl'''''XN) which
is defined
k = i,..., ~(U)
N}.
in
= ( ~
U = {(x I ..... XN):
an open set in
cube with sides of length By use of Lemma
M( ~ k:l
~N )'
%
with
at the origin
and thus
~ k=l
*dg(.,ak),... , of
M
implies 2~
(bl,...,b N) E IRN M ~ k=l
contains
large integer
an NM > 0.
~ k=l
(Xl,...,x N) exists
*dg(. yj
*dg(-,ak))
- 2~M~(Xl,...,XN).
YN
that the right-hand
when there
*dg(.,a k + x k)) YN
an
side covers
ranges
+ x k) = b 'ak
Thus,
given
an N-cube
U.
So, for
such that
(mod 27) J
~ f yj*dg(-,~k ) --- b 3. k=l N.
over
(Xl,...,x N) E U
for j = i,..., N. If ~i''''' ~n are the points each repeated M times, then ~k'S belong to V
j = I,...,
does not vanish,
(2~M)~(U)
for a sufficiently
YI
with sides of length
for
r = min{l-[akl:
7E, Ch. V, we have
*'dg(.,a k + x k),...,
The definition
~
k=l
[Xk[ < r}
of
I~N
2z
YI = M( ~ k=l
any
~i .... '
k=l
Since the Jacobian
contains
we set
a k + Xk, and
i < k < N,
(mod 2~)
~ @ F0(R)* , we find
~i'''''
~n E V
such that
[ k=l for
y = yj,
We set
q(z)
l.a.m,
q(z).
3J. Theorem. points
of
the l.a.m,
(mod 27)
*dg(',~ k) - - a r g ( ~ ( y ) ) y
i ~ j ~ N, and therefore = exp(-[k~l Then
g(z,~k))
~q(y)
= ~(y)
for any
y 6 F0(R)
and let
~q
for any
y e F0(R)
lying in
be the character lying in
We are now able to prove our final objective
easily.
Suppose
separates
R.
that
Then
defined
R
(c), IC, holds is a PWS and
in IB.
and that
H (R)
qc = g~(0)[R'
where
g~(0)
G.
of the G.
the is
[]
196
Proof. Ch.
Let
{G : n = i, 2,...} be a c a n o n i c a l e x h a u s t i o n of R (see n 0 E G I. Take any c h a r a c t e r [ of F0(R). By Lemma 31
I, IC) with
and C o r o l l a r y F0(R)
3H there
such that
In -I
exists,
~n(y)
is also outer,
for each
= ~(y)
[n-l[c
for
n, an outer
y e F0(R)
is outer
character
lying
in
and t h e r e f o r e ,
In
G n.
of
Since
by Lemma
3D,
m "( ~n ) => IQc(0) I > 0. So we can choose, and of
Ifn(0) I ~ TR
for each
n, an
and denote
by
Fn
in some n e i g h b o r h o o d
principal
branch
we may assume, that
F
passing
Moreover,
so that
YT
such that
YT ~ Gn
that
) : [(yT)
[n(y
of
(G n} for
Letting
n ÷ ~, we have that
phic
it is clear follows
on
R
that
that
nally have
m
f e H~(R,~),
In o r d e r
qalR .t
with Let
defined admits
by
a # 0
q](z)
R
is a PWS
(resp.
qa ). f(a)
and t h e r e f o r e equal
bounded
extension : 0}, then
of
H ~% ()Ra to
= {f E H~(R):
f/qa
implies
we
holomor-
of
0, then
IQc(0) I .
holomorphic
let
fi-
Rt
V, 3B.
R t.
(resp. function So,
be
For each qa = F0(R)) on
R
if we set
= {f • H~(Rt):
f/q~
R, of f u n c t i o n s
in
is bounded}.
It
we
z • R t, and
to H~(R)
TR
°
F0(Rt)
to the whole
the r e s t r i c t i o n s ,
~
in Ch.
= exp(-gt(a,z)),
q~
holomorphic
In
is a r b i t r a r y ,
of the theorem,
~a ) be the c h a r a c t e r Every
of
of
N > 0
is a r b i t r a r y ,
If(0)l
and use the n o t a t i o n s
we set
an
the m u l t i p l i e a t i v e
and
assertion
and
0 £ t ~ i,
isomorphism
exists
in a n e i g h b o r h o o d
(resp.
a unique
is e x a c t l y
Hence
~ • TR
: [(X)Fn.
~ e F0(R)* ,
con-
that
T E TR
~at
H~(R ¢) : {f e H~(Rt): bounded}
R
As
°
to show the second of
As
denotes
llfll ~ i
IQc(0) I .
=
the r e g u l a r i z a t i o n a • Rt
~
there
family,
IF(0)[
x(0)t,
the d e f i n i t i o n
f0 o ~ = F
0) > IQc(0) I > 0
~(
Then
f
Fn :
is the
and
let
segment
= i
it is clear
IIFILo~ ~ 1
In fact,
It follows
If
(fn)0
Then,
the c a n o n i c a l
F O T = ~(T)F.
such that
m~(<,0)
~.
: [n(YT)F n : [(yT)Fn
F E H (~,~).
function
under
n ~ N.
F n o T : [n(T)Fn
conclude
on
satisfying
n ~ N.
such that
{F } is a b o u n d e d n if n e c e s s a r y , that {F n}
is an e x h a u s t i o n ,
for all
llfn II
as c h a r a c t e r s
0, w h e r e
of the r a d i a l T
In
Since
uniformly
~
such that
and
H~(~,[n )
F • H~(~,~).
under
Since
2D).
function
is the image
F0(R).
II,
almost
we have
be the image
in
to a s u b s e q u e n c e F
[
of the origin
(Ch.
n
is a h o l o m o r p h i c
YT
onto
f
to a f u n c t i o n
IQc(G) I . let
of
We r e g a r d
the f u n c t i o n
(fn) 0 o @
verges
fn • H ~ ( R , [ n )
[Qc(0)I/(I + n-l).
is H~(R t) a
197
Let
St(z) a
tion of [a ).
: exp(-gt(a,z) - igt(a,z))
S at
to
R, so that
S at
for
(resp.
Then we have in an obvious sense
H~(R)a = S a ~ ( R , [ a - l ) .
Therefore,
z E Rt
and
Sa
the restric[at (resp.
S a ) has character H~(R t) = s at ~ ( R t a
~(R,[a-l)
[at-l) and
is regarded as the re-
striction of ~ ( R t '[at-i ) to R. Since [~-i is outer by Theorem 3H, ~ ( R t '6a¢-1 ) has no nonconstant common inner factors and so does the space
~(R,~a-l).
Let now n = i, 2,...
Hence
~a -I
{Zl, z2,...} let
is outer for any
be an enumeration of
a E R %. Z(0;Rt).
For every
n
qnt : exp(-j:l [ gt(zJ'z)) for z E R%' qn : q~[R, and let ~n be the character of F0(R) determined by qn" Then the above observation shows that each ~n is an outer character. Let Qn be the inner function on ~ such that Qn(0) ~ 0 and IQnl = q n ° %. Let f be meromorphic on R such that Iflq n has a harmonic majorant on R. As is seen easily, f has a unique meromorphic extension to R t, which we denote by the same letter. Take any Then
h e H~(R), which is also regarded as an element in
Ifhlq~
has a harmonic majorant on
R t.
H~(Rt).
It follows from Theorem
4B, Ch. VII, and Theorem 3B, Ch. V, that I
ffidx : Y AI
This means that
ffidxt = f(O)h(O)
= 0.
&I(R t )
HI(dx, Qn-l) ~ H0(dx )m ~ HI(dX,Qc-I).
outer, we see that Qc/Qn on R~ or, equivalently,
is inner.
Namely,
qc/qn
Since
~n
is
is an inner l.a.m.
n
qC(z) < exp(- ~ gt(zj,z)) j=l on R for any n = i, 2, . . . . Letting is divided by q = gt(0)IR , where g t(0) (z)
=
n ÷ co, we conclude that
qc
exp(- ~~ gt(z j ,z)). j:l
In other words, if Qt(0) is the inner function on ~ such that Qt(0)(0) ~ 0 and IQt(0) I = q O ~, then Qt(0) is an inner factor of QC"
I
On the other hand, we claim that H~(dx,11Qt(0) )± ~ H~(dx). To see this, let f* E H~(dx,I/Qt(0)) ±. This means that f* E LI(dx ) and
lg8
f£1 f*hdx = 0
for any
h, meromorphic
bounded.
By the inverse
a unique
f e HI(R)
contains
constant
Cauehy theorem
with
f* = f
functions,
f(0)
R, such that
lhlq
is
(Theorem IC, Ch. VII) there is
a.e.
on
A I.
Since
H~(dx,I/Q t(0))
we have
= I
~dx : I AI
f*dx = 0. AI
f C H I(R) 0 , as claimed
Hence,
on
We now repeat our argument
in IB and get
H0(dx )i ~ HI(dx,I/Q %(0) So, in view of the definition of QC (see 2D , [10HI(dX,Qc-I)]I HI(dx,I/Q t(0) ). Since I 0 has no nonconstant common inner factors ~C
is an outer character,
function.
this implies
Summing up, we have shown that
by a constant
factor of modulus
assumed that
QC(0)
§2.
4.
that
CONDITIONS
> 0
and
EQUIVALENT
Qt(0)/Qc
QC
one.
(Indeed,
Qt(0)(0)
> 0.)
TO THE DIRECT
and
Qt(0)
differ only
QC = Qt(0) Hence,
and
is also an inner
because we
qc = gt(0)IR"
[]
CAUCHY THEOREM
General Discussion 4A.
The direct
chapters.
count of the results "direct
Cauchy theorem was studied in §i.
Cauchy theorem"
possible
in the preceding
We are now able to deepen our discussion
choice of
bolic Riemann Definition.
Our present
which contains
{zj}.
objective
by taking
two
into ac-
is to seek for a
Theorem 4B, Ch. VII, for every
We need a definition
valid for general hyper-
surfaces. Let
Cauchy theorem
q
be an inner l.a.m,
(abbreviated
on
R.
We say that the direct
to (DCT)) holds for
f(0)
: I
q, if we have
f(b)dx(b)
J
£i for any meromorphic
function
f
on
R
such that
Iflq
has a harmonic
majorant. There are two types of (DCT), which are valid for any (i) (DCT),
It is trivial
for we have
that the constant
f E HI(R)
function
in this case.
q ~ i
R. satisfies
199
(ii) 4B, Ch.
If VII,
{Zl,
z2,...]
is an e n u m e r a t i o n
shows t h a t any i n n e r q(z)
satisfies
(DCT)
Suppose
for
Then
q
= exp(-
q
R
carries
includes
can be d i v i d e d
by
the set of i n n e r l . a . m . ' s .
for some
z.
an i n n e r
the c a s e
the
q
for all
such that
q
for
s h o u l d be d i v i d e d
that
q
sat-
n : i, 2, . . . .
It f o l l o w s
and t h e r e f o r e
We thus a s s u m e , PWS.
in Ch.
n = i, 2,...
in w h a t
VII,
by (DCT).
Lemma.
R
regular
in by
that
follows
R
should converge
in the
sense of po-
is a PWS.
in this
section,
that
C a u c h y t h e o r e m we w i s h to h a v e
3C.
be a r e g u l a r
~j=l g(zj,z)
implies
equivalent,
collectively
that
is a s s u m e d
T h e n the d i r e c t
are m u t u a l l y
Let
R
t h e n our r e s u l t
(DCT a) g i v e n
a • R
l.a.m,
(ii)
e x p ( - [ j=l n g(zj ,z))
If, m o r e o v e r ,
theory,
4B.
then Theorem
co
g(zj,z))
a regular
Z(0;R),
n [ g(zj,z)) j=l
co
exp(-~j=l
tential
of
of the f o r m
n = i, 2, . . . .
now that
isfies a (DCT) w h i c h
l.a.m,
By T h e o r e m
5A, Ch. VIII,
so that t h e s e
PWS for w h i c h
conditions
(DCT)
holds.
R
is
is just
(DCTa)'S
with
are d e n o t e d
Q(O) be Q(O)(o) >
Let
the i n n e r f u n c t i o n on ~ such that g(0) o % = IQ(0)I and (0) 0, w h e r e g was d e f i n e d in Ch. VII, IA. Then we h a v e oo
H 0 ( d x )± : H I ( d x , I / Q ( 0 ) ) . Proof. that
Let
f* E H I ( d x , I / Q ( 0 ) ) .
f* o $ = (I/Q(0))F.
is T R - i n v a r i a n t on
R
on
such that
Take any
D.
Then t h e r e
Since Thus
(I/Q(0))F
there
f o ~ = (I/Q(0))F
h • H~(R).
Then
exists on
Ifhlg (0)
•
exists
an
F E Hl(d~)
is T R - i n v a r i a n t a meromorphie and
f~ = f
has a h a r m o n i c
on
T,
function
such it f
a.e.
on
A I.
majorant
on
R, so
that f
^^
fhd x : f ( O ) h ( O )
: 0
AI by (DCT). cluded
in
Namely,
H 0 ( d ×)
T h e o r e m 3J t h a t 4C. Theorem. conditions
f* E H 0 ( d x )±
.
On t h e
other
hand,
we h a v e
H~(d×) ± ~ HI(d×,I/Q(0)).
It is n o w e a s y to p r o v e Let
and t h e r e f o r e
R
be a r e g u l a r
are e q u i v a l e n t :
our first
H I ( d x , I / Q (0))
shown in the
H e n c e we a r e
PWS w i t h o r i g i n
$.
proof
done.
characterization T h e n the
is in-
of
[] of
(DCT).
following
200
(a) (b) (c) the form Proof.
(DCT) holds. H0(d X) • = H I (dx,I/Q (0) ). Every simply invariant subspace of
LP(dx),
HP(dx,Q)
T.
for an i-function
By Lemma 4B,
satisfied.
Let
f
(a) implies
has a harmonic majorant jorant on
~
Theorem
2D,
Theorem
4C, Ch. VIII,
that
(c) holds.
subspace of
on
R.
and therefore f(0)
(b).
be a meromorphic
Conversely, function on
Then, Hence,
states that H0(d X)
I < p < ~, is of
suppose that R
such that
I( f o ~)Q(0)] (DCT) holds.
(a) implies
(b) is Iflg (0)
has a harmonic ma.
So, by
On the other hand,
(c).
Finally,
suppose
is easily seen to be a simply invariant
LI(dx ), there exists
H[(dx )& = HI(dx,Q).
on
f @ HI(dx,I/Q (0)) = H0(d X)
= fA I fd X.
Since
Q
an i-function
Q
on
T
such that
Then [10HI(dx,I/Q(0))] I = HI(dx,Q),
by use of Theorems
2D and 3J.
Lifting to
~, we see that
(I 0 o $)(I/Q(0))HI(do,~C ) ~ QHI(do,~Q-I). Since
io o $
has no nonconstant
outer,
we see that
(QQ(O))-I
common inner factors and since
is an inner function,
say
P.
~C
is
Thus
HI(dx,1/Q (0)) ~ HI(dx,I/PQ (0)) = [IoHI(dx,I/Q(0))] 1 $ HI(dx,I/Q(0)), which shows the statement
5.
Functions SA.
mP(~,a)
(b).
and
This completes
the proof.
(DCT)
We will give our second characterization
the functions
mP(6,a)
(see ID) play a principal
notations
given in Ch. VII,
Theorem.
Let
R
[]
of (DCT), role.
in whieh
By use of the
IA, we first get the following
be a regular
PWS.
Then it satisfies
(DCT) if and
only if ml(~(a),a)
(is)
for some Proof.
(and hence all) Suppose that
~(-~,~(a)) morphic
with
: g(a)(a )
a E R.
(DCT) holds and choose any
a E R.
Let
h
be in
ilhll < i and set f = h/S (a). Then f is a merol,a = function on R such that rflg (a) has a harmonic majorant on
201
R.
Setting
H[~]
and
u(z)
= lh(z)I,
i~ I = ~/~(a)
we get an l.a.m,
= @
a.e.
f(a)
t : |
on
41 .
u
such that
LHM(u)
As we are assuming
=
(DCT),
we
have
with
f(b)dXa(b),
J A1
dXa(b) = k b ( a ) d x ( b ) , and t h e r e f o r e If(a)[
~ [
If(b)IdXa(b)
: [
41 =
So
lh(a)l
= If(a)l
u(b)dXa(b) £1
llhlil, a ~ i.
g(a)(a)
~ g(a)(a).
As
h
is arbitrary,
we have
(a) g
(a) ~ sup{lh(a)]:
h • ~(R~,6(a)),
llh111,a ~ i}
= ml([(a),a). On the other hand, properties: ml(~(a),a)
Suppose We denote
such that extends
(i)
by
belongs
to
Is(a)(a)I
Hence the equation
(15) holds
B
that the equation
the set of functions
has a harmonic
to a meromorphic
function
majorant on
R.
with the
~ ( R , [ (a))
and
conversely
|h i
S (a)
=< irs(a)ll~ =< 1
JIs(a)Ell,a
~ g(a)(a).
(b) a E R.
the function
= g(a)(a). for all
Thus
a e R.
(15) holds
for some
h
on
on
defined R
and
(ii)
R \ Z(a;R) h/g (a)
In other words,
B = (exp(i[(a)))~(R,~(a)). Take any by Lemma have and,
h E B.
Then
3B, Ch. VII,
~(a)
= i
in fact,
a.e.
h/g (a) admits
on
belongs
41
is a meromorphic
fine boundary (Lemma
to the space
IBhiJB = I
values
2A, Ch. VII), LI(dx).
function a.e. so
on
on
R, which,
41 •
As we
h
exists
a.e.
B
is identified
We set
Ifi(b)ldXa(b)' A1
which defines
a norm in the linear
with a subspace setting
L(h)
of
Ll(dXa ).
= h(a)/g(a)(a)
h.exp(-i~ (a)) e ~A(R,~(a))
space
Define for
B, so that
a linear
h E B.
If
functional
on
B
h e B, then we have
and so
lh(a) l : lh(a)exp(-i~(a)(a)[ ~hllB'ml(<(a),a)
L
by
202
: lih11B.g by use of
(15).
This m e a n s
we see via the H a h n - B a n a c h sion to
Ll(dXa )
ilwll : IILII ~ i
IL(h) l ~ ilhllB
theorem
that
and that t h e r e e x i s t s
L
h • B.
: i J
has a n o r m - p r e s e r v i n g
a function
w • L~(dXa )
So exten-
with
h(b)w(b)dXa(b)
=
for
h = g(a) f
] w b) Xa
J
AI w -- i
h • B.
AI
In p a r t i c u l a r ,
i = L(g(a))
Thus
for e v e r y
and
L(h) for e v e r y
that
(a)(a)
a.e.
on
AI
we h a v e
lw b)Id a b)
i.
AI and t h e r e f o r e
L(h)
= I
h(b)dXa(b) AI
for e v e r y
h • B.
To f i n i s h R and
such that ~ = ~
f(a)
the proof, Iflg (a)
a.e.
on
let us take any m e r o m o r p h i c
has a h a r m o n i c A I.
majorant.
F r o m what we h a v e
= h(a)/g(a)(a)
: L(h)
= I
Then
h(b)dXa(b)
(DCT a) holds,
5B.
Let
positive
{an:
: I
numbers
is d i s j o i n t
tending
from
to
Z(0;R) •
0
• B
that
f(b)dXa(b)"
[]
be a s t r i c t l y
such that each
We set
follows
on
AI
as was to be proved.
n = i, 2,...}
f
h = fg(a)
seen a b o v e
AI Hence,
function
decreasing
sequence
{z E R: g(0,z)
R n = R(en,0)
and denote
by
of
= a n} gn(a,z)
the G r e e n f u n c t i o n for R . Let ~n be the c h a r a c t e r of the l.a.m. (0) n un (z) = e x p ( - [ {gn(W,Z): w • Z ( 0 ; R n ) } ) . Since gn(0,z) = g(0,z) - an, we h a v e Z ( 0 ; R ) : Z(0;R) A R for n = i, 2, . . . . We d e f i n e a m u l t i n n plicative holomorphic function B • ~{~(R,~ (0)) (resp. Bn • ~(Rn,nn)) by the c o n d i t i o n s 0
and
branch
iBn(z)i at
0.
most uniformly may assume
that
for e a c h f i x e d
B0(0)
and
IB(z)I
= g(0)(z)
: u(0)(z)) w h e r e the s u f f i x n For any f i x e d a • R, gn(a,z) on
R \ {a}. Bn(Z)
Passing
converge
l e m m a gives
(15) to an a r b i t r a r y
B(z)
converge
almost
R.
which
(resp.
denotes
(Bn)0(0)
to
g(a,z)
if n e c e s s a r y ,
as
>
the p r i n c i p a l
uniformly
~n(y ) + ~(0)(y)
a result PWS
0
to a s u b s e q u e n c e
to
y • Fo(R) , we h a v e
The f o l l o w i n g equation
> 0
on
R.
alwe So,
n ~ ~.
is an a d a p t a t i o n
of the
203
Lemma.
Let
i ~ p < ~ g (0)
for any Proof.
(0) ~
mp'
p' = p/(p - i).
Then
(~,O)mP(~-l~(O),o)
~
mP'(~,0) 61 n
denotes
= lim mP'(~In,0), n÷~
the restriction
of
~
to
R n.
Next we recall that
(7) in Ch. V, 4C, asserts
inf{llfl[p,: f • ~ ( R n , ~ [ n ) = sup{lh(0)[:
, If(0)l
: i}
h • ~ P ( R n , ~ I n - l ~ n ) ' llhllp,n
where
llhfl p,n = [-(i/2~)f$ R lhlPdgn(.,0)] I/p n then implies (17)
mP'(~In,0)mP(~In-lnn,0) We now estimate
aim we choose
the limit of
by Theorem
F0(R n)
as
n ÷ ~.
n, such that
Since
R
is the restriction
For this llhllp,n = i
is a PWS and since of some character
~ inf{mP(~',0):
~' • F0(R)*}
lhn(0) I ~ (n- l)mP(0)/n
for
>
= mP(0)
n = i, 2,...
5A, Ch. V,
on any compact
and, by passing to a subsequence
subset of
R
{lhn(Z) I }
.
seen in the proof of Theorem
sary, we may assume that the sequence
{hn(Z)}
formly to some m u l t i p l i c a t i v e
function,
immediate
that
(18)
ilh[Jp =< i
and
mP(~-l~(0),0)
Combining (19)
(16),
(17) and
analytic
of
As we have
say
bounded
if neces-
almost uni-
h, on
R.
It is
So
~ lim sup mP(~In-l~n,0).
(18), we get
In order to get the desired
~ lim sup r n. n÷~
inequalities,
side of (19) is not smaller than
g ( 0 , z ) - an, we have
0
is uniformly
converges
h • ~P(R,~-I~(0)).
mP'(~,0)mP(~-l~(0),0)
right-hand
This
3B, Ch. I and Theorem IB, Ch. If, we have
mP(~[n-lnn,0) and therefore
n
= r n.
h n • ~ P ( R n , ~ I n - l ~ n ), for each
of
-i]
=r
r n : u(0)(0). n
and
mP(~In-l~n,0)
Jhn(0) i ~ ml(~In i n n , 0 ) ( n - l)/n.
every character F0(R)
,0)
By the normal family argument we easily see that
the formula
and
m I (~( 0)
~ • F0(R)*.
(16) where
and
we first show that the
g (0)(0).
Since
gn (0,z)
=
204
log r n = ~{g(0,w) - ~n: w e Z(0;Rn)}
-
~{g(0,w) - an+l:
w e Z(0;Rn)} =
So,
lim l o g r n
and,
for any fixed
~{g(O,w) - ~n: w E Z(0;Rm)} for all to
n $ m.
g(0)(0),
Letting
which
Finally ml(~(0),0).
shows
n ÷ ~
m > 0,
~ - lim log r k ~ - log g (0)(0) k÷~ and then
m ÷ ~, we see that
the l e f t - h a n d
easily
follows
side of
from the
(19)
finishes 5C.
the proof.
We will
group
F0(R)
now study
F0(R)*
characters for each
with
with
the c o n t i n u i t y
fixed metric
space.
PWS
(DCT)
implies
(20)
Since
~ F0(R)
~ E F0(R)*
an i m m e d i a t e
and t h e r e f o r e
namely,
and any
if
~n(y)
is c o u n t a b l e , that,
{~n }
of
÷ ~(y)
F0(R)*
is a
for any r e g u l a r
= ml(~(0),0)
i S p S ~, w h e r e
of T h e o r e m
we equip
its c h a r a c t e r
a sequence
if and only
We b e g i n with r e m a r k i n g
consequence
~ ÷ mP($,0),
For this p u r p o s e
topology
mP'(~,0)mP(~-I~(0),0)
for any
).
of f u n c t i o n a l s
F0(R)*.
topology;
to a c h a r a c t e r
y E F0(R).
compact R,
group
the d i s c r e t e
the c o m p a c t
converges
than
relation
[]
i S p ~ ~, on the c h a r a c t e r the group
tend
is not larger
inclusion
~p' (R , ~)~P(R, ~-l{(O)) =C ~(R,~(O) This
rk
our claim.
we show that But this
w • Z(0;Rn+ I) \ R n}
(0)(0).
l ~ - log g
-logrn+
exists
+ ~{g(0,w) - ~n+l:
p' = p / ( p - i).
5A and Lemma
5B.
We next
This prove
is the
following Lemma. mP($,0) Proof.
If (20) holds is c o n t i n u o u s
for any on
Take any s e q u e n c e
~ E F0(R)* , then the f u n c t i o n a l
F0(R)* {~n:
for every
n = i, 2,...}
p
C F0(R)*
to the i d e n t i t y c h a r a c t e r Id. Since m~(~n,0) implies that ml(~n-l~(0),0) ~ ml(~(0),0) for lim inf m l ( ~ n - l ~ ( 0 ) , 0 ) n~
We now c l a i m
the r e v e r s e
inequality:
with
~ ÷
i ~ p ~ =. which
converges
~ i, the e q u a t i o n (20) n = I, 2,... and thus
~ ml($(0),0).
205
lim sup ml(~n-16(0),0)
£ ml(~(0),0).
n+~
If this were not the case,
then we could assume,
quence
if necessary,
ml(~n-l<(0),0)
2,...
and for some fixed
with
llfnllI = i
By passing
that
and
~ > O.
[fn(0)[
to a further
> ml(~ (0),0) + s
Then,
choose
shows our claim.
this with
(20), we have
(21) Now take any
p
for any
with
=
and using
the role of
6
These two inequalities
5D.
Let
R to a multiplicative If(0)l ~ m l ( ~ ( 0 ) , 0 ) + s/2.
i = m ~( Id,0).
I £ p £ ~.
Since
~(R,q)~(R,n-l~)
and
{z6:
let
e
inequality:
£ mP(~,0).
show that
F0(R)*.
mP(~,C)
is continuous
in
[]
j = i, 2,...}
n = i, 2,...
~ mP(n,0).
~, we get the reverse
together
group
~ mP(~,0).
(21), we have
lim sup mP(~,0)
every
n = i, 2,...
we could also assume
~, q e F0(R)* , we have
~ ÷ q
on the character
(0))
shown
lim inf mP(~,0) Changing
n = i,
: ml(~(0),0).
mP(D,0)m~(q-l~,0) By letting
for
Hence we have
lim m~(~,0) ~÷Id
~P(R,~)
to a subse-
fn E ~ ( R , < n - l {
for each
if necessary~
lim ml({-l$(0),0) ~÷Id Combining
an
> ml(~(0),0) + e/2
subsequenee
that {fn } would converge almost unformly on function f C ~ ( R , ~ (0)) with llfU1 ~ 1 and This contradiction
passing
be an enumeration
be the character
of
Z(O;R).
For
of the l.a.m.
n n
exp(-
and l e t and
Cn(Z) E ~ ( R , 8 n)
(Cn)0(0 ) > 0.
Since
~ g(zj,z))
j=l
be d e f i n e d by
IOn(Z) I = exp(-~ j =n l g ( z j ' z))
llCnllp =< llCnll~ = i, we see first that
n
exp(for
~ g(z~,0)) j=l
= ICn(0) I £ mP(en,0)
i £ p £ ~. Let
p,
i ~ p ~ ~, be fixed and take any
f E ~(R,Sn).
The
.
206
quotient f0/(Cn) 0 of the principal branches then extends uniquely to a meromorphic function, say hf, on R. Since lhflexp(-[j~l g(zj,.)), being equal to Ifl, has a harmonic majorant, the weak Cauchy theorem (Theorem 4B, Ch. VII) shows that Since
hf • LI(dx)
lhf(0) I = If(0)I/ICn(0) I
and
If(o)l ! ICn(O)I I
and
hf(0) = fA I hfdx.
ILhfllI = NfilI S IIfNp, we have
I~fldx
=
ICn(O)lFIhfll 1
A1
= ICn(O)IllfllI ~ ;Cn(O)lllfH p. As f • ~P(R,8 n) and thus
is arbitrary,
mP(~n,O) ! ICn(O)l
= exp(-[j~ I g(zj,O))
n
mP(Sn,O) for
= exp(- ~ g(zj,O)) j=l
i S p S ~• oo
Since
~j=l
of
R\ Z(0;R),
the
function
verges to
g(zj,z)
we s e e B, w h i c h
~(0)
ml(6(O),o)
If
is that
uniformly {C n}
was d e f i n e d
ml($;0)
convergent
converges in
5B,
on a n y c o m p a c t
almost
uniformly
and therefore
is continuous
in
that
on
subset R
{0 } n
to con-
~, then
= lim ml(@ O) : exp(- ~ g(zj,O)) n+~ n' j:l
: g(O)(o),
which implies, by Theorem 5A, that R satisfies (DCT). Summing up our considerations in §2, we finally get the following characterization of (DCT): Theorem. conditions (a) (b) (c) the form (d)
Let R be a regular PWS with origin are equivalent: (DCT) holds. H~(dx) ± = HI(dx,I/Q(0)). Every simply invariant subspace of
0.
Then the following
LP(dx),
i ~ p ~ ~, is of
HP(dx,Q) for some i-function Q on T. ml(~(0),0) = g(0)(0), where ~(0) is the character of the
l.a.m, g(0)(z) = exp(-[ {g(w,z): w e Z(0;R)}). (e) m~(6,0)ml(~-l~(0),0) = ml(~ (0) ,0) for any ~ • F0(R)*. (f) 6 + ml(~,0) is continuous on F0(R)*. (g) ~ ÷ mP(~,0) is continuous on F0(R)* for every p with i~pS~.
207
NOTES Most of the o b s e r v a t i o n s Hayashi
stated above are based on the idea of
[28] with a couple of m o d i f i c a t i o n by the author.
involving the function
m~(~;0)
is also in Pranger
[55].
A discussion
CHAPTER
The faces sion
EXAMPLES
objective
of this
of P a r r e a u - W i d o m is by no m e a n s
Riemann The
X.
surface
emphasis
we are
going
should
(DCT)
but the
examples
§i we g i v e
surface
of M y r b e r g (DCT).
type
three
type
for which
problem
in the m a x i m a l
shown here
functions positive corona
as w e l l
problem.
the o t h e r ,
i.
OF I N F I N I T E
PWS's
of M y r b e r g
of M y r b e r g
ing
type
surfaee
counting
over
R ÷ ~ of
in
§3 t h a t
of
Ha(R)
is d e n s e
of a l m o s t
~,
are
condition
corona
exist
PWS's
FOR WHICH
(DCT)
for which out more
s u c h a PWS a l w a y s
every
for
spaee
of P a r r e a u -
discussing
PWS
R
as an o p e n
can
that
the
our
the
be em-
subset.
It is
o f all h o l o m o r p h i c
convergence.
theorem
for which
PWS's
for a R i e m a n n
regions
constructed
one h a n d ,
the
Here
for which
PWS's
show that
in t h e
uniform
examples
on t h e
GENUS
Finally
concerning
examples
but not corona
in
(DCT)
in
§4,
the §2 c a n
and,
on
theorem
fails.
PWS's
of i n f i -
HOLDS
Type
for w h i c h
~:
show
of PWS's.
(i)
PWS's
is to f i n d
As a p r e l i m i n a r y
space
satisfy
Our o b j e c t i v e
genus,
function
we
ideal
show,
there
PWS
IA. nite
that
fails.
as n e g a t i v e We
sufficient
in
bordered
of PWS's.
§2 p l a n a r
H~(R)
so as to
problem
sur-
discus-
connectivity.
(iii)
then
PWS's,
that
and
classification and
compact
be t y p i c a l
planar
to be a PWS a n d
in the t o p o l o g y
be m o d i f i e d
§i.
for
is true;
of
foregoing
of c o n s t r u c t i o n :
(ii)
we c o n s t r u c t
(DCT)
corona
types
A remaining
a necessary
every
never
TYPE
examples
our
of i n f i n i t e
holds;
theorem
is false.
Next,
Although such can
on P W S ' s
(DCT)
some
to s h o w t h a t
different
corona
bedded also
a PWS,
at a r e a s o n a b l e
In
Widom
in vain.
for which
theorem
aiming
satisfies
a labor
be p l a c e d
OF P A R R E A U - W I D O M
is to p r o v i d e
in o r d e r
to g i v e genus
the c o r o n a
chapter
type
is e v i d e n t l y
of i n f i n i t e fails
OF S U R F A C E S
in t h i s
(DCT)
the unit which i.e.
multiplicities.
section
holds. disk
makes
• R
each point In
§i
R
is to c o n s t r u c t
A Riemann
surface
if t h e r e
exists
an n - s h e e t e d , of
~
denotes
has
R
is s a i d to be an a n a l y t i c
branched,
exactly
a Riemann
n
full
cover-
pre-images,
surface
of t h i s
209
type and
{~j} = {6j:
over which Theorem.
~
j = i, 2,...}
is branched.
Let
R
fined above.
is the sequence
surface of Myrberg type over
Then the following conditions
R
(b)
The set
(e)
The sequence
in
~D
Then the following holds.
be a Riemann
(a)
of points
D
as de-
are equivalent:
is a PWS. H~(R)
separates {%j]
the points
of
R.
satisfies
the Blaschke
(i-l{j[)
< ~.
condition,
i.e.
j=l The proof will be given in IG below,
after some preliminary
obser-
vations. IB.
Lemma.
Suppose that a bounded analytic
separates
the points
satisfies
the Blaschke
Proof.
We define,
in
~-i(~,)
where
~-I(~)
function
for every
function whole
in
= {al,..., of
n
~* • ~ \ {~j}.
on
R
Then
{~j}
< • D \ {%j},
= (-l)kak(f(al),...,f(an)), a n}
and
~k
variables.
~ \ {~j)
~.
f
condition.
Ak(%)
metric
for some
function
denotes
Clearly,
the k-th elementary
Ak
and thus can be continued
The definition
of
Ak'S
sym-
is a bounded analytic analytically
to the
implies that
f n + (A I o ~)fn-I + ... + A n O ~ = 0 holds on
~ - i ( ~ \ {~j})
discriminant
and thus everywhere
of the equation
see that the function
D(~)
and only if the equation arates the points the points
{j
in
iC. verges,
condition.
(z E R: g(a,z) choiee of distinct
to
X
n
has
D({j)
D(~) = 0.
function
H~(~)
B(~,a) > e}.
D(~) = 0
roots.
be the
in
X.
D(~)
~ 0
Since
f
We if sep-
does not vanish identically. Namely,
D(~)
on
~j's ~.
So
At
are among the zeros {~j}
satisfies
[] integral
f0 B(~,a)d~
is the first Betti number of the region Since the convergence
a, we may assume that the set points.
Let
and that
distinct
Next we want to see when Widom's where
R.
X n + AI({)xn-I + --- + An(~) belongs
~-i({,),
we have
of the bounded analytic the Blaschke
in
on
We may also assume,
conR(e,a)
does not depend on the
~-l(@(a))
consists
by applying a conformal
of
n
transfor-
=
210
mation
of the
~-i(0)
disk
contains
if n e c e s s a r y , n
distinct
h(z) Then
we h a v e
h(z)
= -log
function
(see
harmonic
everywhere
h(z)
closed
u(z) and
region
follows
that
u(z)
For e a c h first such we
Betti that
find
on
e > 0
number
let
of
{z E R:
S
S .
I~(z)I
a constant
l~(z)I find
~ r.
R.
Lemma.
Let
Proof.
< r}
is c o n n e c t e d .
such
Moreover, Aa,
Let
> 1
any
such
I~(z)I
S e = {h(z) {I~(z)I
in
S
e -e.
by
(i),
R ( ~ / A , a I) all
of
ID.
S
cannot .
By use
of
$ log p
on
see that
log I~(z)l
is a p o t e n t i a l ,
.
and
number
B ' ( ~ , a I) r,
< 0 it
the
0 < r < i,
By H a r n a c k ' s
inequality
S A g ( z , a I) a' E R
with
l%(a')l
< r < I,
that < Aa,g(z,a, )
Then
S
> ~}
< r}
and
e < h(z)
and
=C R ( ~ / A , a l )
= {[~(z) I < e-S},
which
includes
the
so is c o n n e c t e d .
I~(z)I
Conversely,
is c o n n e c t e d
< e -~,
take
any
=< A g ( z , a I)
have
any
compact
Let
0 < e < - log r.
i.e.
z E se.
z E R and
with
thus
complementary
r <
Then
B ( ~ A , a I) ~ B ' ( ~ , a I) ~ B ( ~ / A , a l ) .
So
R ( e A , a I)
l,(z)l
z E R ( ~ / A , a I).
component,
[]
Lemma.
= p.
is
since
~ r.
z E R(~A,al) ; then
is i n c l u d e d Then,
Green
that
given
0 < e < - log r.
set
Then,
u(z)
we h a v e h
~(z) n ~ ( a ' ~
with
We h a v e
of the
p ÷ i, we
> e}
fix a p o s i t i v e
R ( e A , a I) ~ S
connected
hand,
Since
: {z E R: h(z)
AaTlg(z
z E R
I~(z)l
we h a v e
We
A > i
a constant
for any
that
We set
: h(z) + log I~(z)I
Letting
other
on
form
0 < p < i.
curve
~ p}.
On the
local
u(z)
with
functions
A - I g ( z , a I) S h(z)
for
we a s s u m e
a = a I.
~ 0, as c l a i m e d .
(i)
we
R.
~ h(z)
the
that p
on the
I~(z)I
and
an
g(z,ak).
any
$ log p
Namely,
= 0.
In fact,
for h a r m o n i c
0 ~ u(z)
~(a)
al,...,
I) shows
Take
{z e R:
is n o n n e g a t i v e therefore
Ch.
R.
u(z)
principle
n [ k=l
=
19(z)l.
6A,
on
is p o s i t i v e ,
the m i n i m u m the
Theorem
that
points
< As
it i n c l u d e s
211
Proof.
We claim that
relatively have
compact
S
in
3U ~ 3R(~A,al).
therefore cycle
g(z,a I)
y
gion
in
If
has no components were
It would follow that bounds
in
U, which are
such a component,
on
then we would
g(z,a I) : ~A
on
3U
U, a contradiction.
and
So, if a
S , then it should bound in the re-
This shows the first inequality.
be shown similarly.
The other half can
[]
We thus have for any •-log r I B(~A,al)d~ which
U
would be constant
R(eA,a I)
R(~A,al).
\ R(~A,a I)
S .
0 < s < -log r i-log r
~
B'(~,
al)d~
r-logr B(~/A,al)d~,
~
implies A_iI-l°g r ~
B'(~,al)d~
~As
Hence,
converges
We now estimate
suppose that the circle the double
S
of
a meromorphic
S
say
We see that
~.
It is then clear that
makes
order to obtain a further Riemann-Hurwitz
relation:
branched,
= e}
Let
contains
B(~'al)d~"
~, of S
B'(e,a I)
does.
0 < ~ < -logr
and
~j's.
~(z)
We then form
can be extended to
onto the extended
an n-sheeted,
branched,
complex plane
full covering of
is exactly the genus of
information
about
if a compact
full covering
(2)
S
f0 B~(~'al)d~
no
so that the function
function, ~
if and only if
f0 B'(~'al)d~" {l~I
¢.
sheeted,
~ A;c/A
"s
f0 B(~'al)da
IE.
r-log r
I-l°g r B(~,al)d~
In
B'(~,al) , we need the
Riemann
of another
S •
surface
compact
F
surface
is an nF0, then
X = nx0 + V,
where and
X V
(resp.
X0) is the Euler characteristic
of
F
(resp.
is the sum of the orders of all the branch points of
Nevanlinna
F
Fo) (see
[44], p. 324).
Lena.
(3)
B'(~,a I) ~ b(e -e) + I - n,
where
I~1
<
Proof.
is the total order of branching
b(e -~ )
over the disk given by
e -~
Let
X
spectively;
so
and
X
X = -2.
¢, the Riemann-Hurwitz
be the Euler characteristic Since relation
S
of
is an n-sheeted,
(2) gives us that
S
and
~, re-
full covering of
~ = - 2 n + 2b(e-e).
212
Since
S
is a compact surface,
X + 2
is equal to the first Betti
number of ~ , i.e. 2B'(~,a I) (cf. Ahlfors and Sario The formula (3) then follows at once. [] The meaning of still holds when IF. with
B'(~,a I)
~S
contains
Suppose that
I~(z)I = e.
and
b(e -~)
[AS], p. 55).
shows that the formula
(3)
some branching points.
0 < g < - log r
and there is no branch point
z
Then we have
I~g B ' ( a , a l ) d a
= ~ B ' (~,a I ) ~ - [~ a d B ' ( a , a g ~
1)
~
f
= -eB'(g,al) Let
r'
be fixed with
r < r' < i.
Then
~dB'(~,al). g
dB'(~,a I) = db(e -~)
for
0 < ~ < - log r'. So, if n. denotes the total order of branching over 3 the point ~j, then we have, for 0 < e < - log r', I-log r' - .g ~dB,(e,al)
=
=
I-log r ' -~C
l
edb(e -~)
exp(-E) log r db(r)
Jr ~
= -
When
[j njlog l%jl
[ n log I~jl. r'
is convergent,
_f~logr' ~dB,(~,al)
therefore ~0 B'(e'al)de converges. integral converges. Since B'(e,a I)
Conversely, suppose that the last is decreasing in ~, we see that
eB'(g ,a I) ~ /0g B'(~,al)d~ ÷ 0 as E ÷ 0 verges. It follows that the series
-
~
converges and
nj log
and so
[0 ~dB'(~'al)
con-
l~jl
r'< I ].I
The integral
~{njlog l~j I: Since only if
Hence we have the following f0 B'(~'al)de
0 < l~j I < I}
i ~ nj ~ n-i
~j log I~j I
converges
if and only if the series
converges.
for all
j,
~j njlog [~jl
converges or, equivalently,
converges
if and
~j (I - l~j I) < ~.
213
IG. shown IB.
Proof
of T h e o r e m
in T h e o r e m Namely,
\ {%~},
9B,
Ch.
H~(R)
separates
exists
a function
points
of
the
Blasehke
IF and
the
the r e m a r k
Verification 2A.
quence
We b e g i n type.
[x2j_l, and
R2
be the tifies with
each
covering
2, . . . . along
IA,
these of
R
condition
of i n f i n i t e Theorem.
Proof.
Let
exist
positive
that
{z e R:
end
(c) ~
of ID.
(a)
for a n y
takes
n
that
follows
~* E
distinct {~j}
from
Sat-
Lemma
[]
a class
of e x a m p l e s
of PWS's
R the
numbers
r
< r}
(4)
Then
unit
closed
usual disk
each
of the
if and
only
< ~.
We n o t e
by
which
of M y r b e r g xj,
{xj} that
be
joining
fashion.
points if
R
~,
is a s u r f a c e
R2
segments
surface
in the
the
R
over
the
a Riemann
onto
(i - xj)
be a PWS direct
be f i x e d
l~(z)l
along
segments
R
is a PWS =i
Then
a E R
slit
of se-
Let identype
j = i,
satisfies
such
a surface
genus.
Let
4.
IB shows
Lemma
We d e f i n e
R. with ~. 3 p o i n t of o r d e r two
map
Thus
each
leaf
Blaschke
2B.
disk
projection
By T h e o r e m
is a l w a y s
R, then,
which
constructing
unit
crosswise
a branch
2, . . . . the
j = i,
natural
in
already in L e m m a
Ix.: j = i, 2,...} be a s t r i c t l y i n c r e a s i n g ] real n u m b e r s c o n v e r g i n g to i. Let R 1 and
of the o p e n
x2j] ,
points
(b) was
is c o n t a i n e d
f • H~(R)
Finally,
at the
(a) ~
(c)
(DCT) With
Let
of p o s i t i v e
two c o p i e s
RI
of
given
(b) ~
the
9-i(%,).
condition.
implication
fact
if
isfies
Myrberg
The
The
there
v a l u e s J at the
2.
IA.
V.
- log
once
of M y r b e r g
Cauchy and
type
theorem
(DCT)
for all.
and
Aa with is c o n n e c t e d ,
~ ( z ~ ~ @((a_)
over
As we
0 < r < I
holds saw
and
I@(a) l < r
~
with for
R.
in IC,
there
Aa > i
such
and
~ Aag(Z,a )
1-~-I~7~(z) for any
z e R
with
meration
of all
critical
I@(z)l
~ r.
so large
take
an i n t e g e r
N > 0
j ~ N.
From
(4)
that
g(z,a),
9(zj) - ~ ( a ) . . . . . . . . log i - ~ - - ~ (zj) for
j ~ N.
Since
R
{z.:
of
We t h e n
follows
Let
points
is a PWS,
j : i, counting
that
2,...}
be an enu-
multiplicities.
19(zj)l
~ r
for e v e r y
< Aag(Zj,a) =
~j g(zj,a) _
< ~
and therefore
214
@(zj) -¢(a) : j : i,
] 2,...~
i - @(a)~(z.) ] We further infer that
satisfies the Blaschke condition. I, 2,...}
l,(zj)l Bn( 6 ) : for
n = i, 2, . . . .
j:n+l ~
{¢(zj):
j :
Put
also satisfies the Blaschke condition• ¢(zj) - ~ 1-~-~3
~
Then ~(zj) -~(z)
[Bn(,(z)) I : j:n+l
j:n+l
g(z,z.)) 3
(a) : gn (z). Since we have I
I1-
B (eit)12d°(t)
: I
n
= 2- 2Re[I
: 2(1-
~
f
77 j=n+l
l~(zj)[)
be a meromorphic
has a harmonic majorant, meromorphic on R and
say
n
B (eit)da(t)] n
as n + ~, a suitable subsequence l a.e. on T. We also note that Now let
(2 - 2Re(B (eit)))do(t)
= 2 - 2Re(B (0)) n
÷ 0
{Bn(k): k = i, 2,...} converges to B ÷ 1 almost uniformly in ~. n (a) function on R such that If g
u, on
R•
If
h n = B n f, then
n
lhn(z)Iexp(-j=l [
hn
n
g(z,zj))
= IBn(z)f(z)lexp(-j=l [
If(z)Ig(a)(z) By the weak Cauchy theorem f(a)Bn(~(a))
g(z,zj))
~ u(z).
(Theorem 4B, Ch. VII) we have = I
f(b)Bn(@(b))dXa(b)" A1
Taking the limit along the subsequenoe
{Bn(k)} , we get
f(a) : lim f(a)Bn(k)(@(a))
is
215
f
:
^
f(b)[lim k÷~
AI
: I
(@(b))]dXa(b)
Bn(k)
f(b)dXa(b)" A1
This
shows
for all
§2.
each
exist
PLANE
have
3.
i.e.
(DCT)
holds
given
in
Some
plane
fails.
It w i l l
seen
3A.
denote
In w h a t axis.
£(a,b)
( b - a)/2,
so that
begin
with
Lemma.
follows
For
A(c,~)
Let
we
every the
later
the
[] we h a v e
(DCT)
is valid.
the
that
the
with
be the
subset
of
closed
disk
with
-K = A ( - b , - a ) .
respect
to the
solution
of the D i r i c h l e t
problem
for the r e g i o n
boundary
data
equal
to
Proof.
If ~\
u0(-z)
is the h a r m o n i c
to
denotes
( K U (-K)),
and
1
region
includes
on
i
on
( K U (-K)),
~\
u(0)
ZK
u
measure
-~K
Thus u(z)
= 1/2.
0
on
a e b
we
and
radius
£(a,b). ~ c}.
MoreWe
0 < a < b < ~ that
of
with
~F. ~K
u0(0)
to
= 1/2.
F a
of the
i.e.
the
(K U F )
with
the
Then
u(0)
~ 1/2.
respect
to the
with
we
to the
function i,
and has
measure
In fact,
respect
harmonic
equal
F
(KUF),
[\
= 1/2.
~ u0(z) []
[\
on
measure u0(0)
is a b o u n d e d
we have
~ Un(0)
of
region
to
identically
( K U (-K)).
of
Re(z)
be the h a r m o n i c
and
we h a v e
values
~\
let
the h a r m o n i c
then
u0(z) + u0(-z) boundary
In p a r t i c u l a r ,
may
centers
with
Suppose
in
equal
for
facts.
with
Since
problem
(a + b)/2
{z E ~:
~K
K
with
is a d i a m e t e r
"disk"
complement of
~
at
boundary
with
type
kind.
a, b
center
[a, b]
infinite
disks
numbers
connected
(-K))
that
FAILS
corona
of this
use v a r i o u s
disk
simple
K : A(a,b)
gion.
(DCT)
shown
of P a r r e a u - W i d o m
regions
of real
interval
some
closed
u0
(DCT a) h o l d s
genus,
FOR W H I C H
regions
some
shall
pair
closed
denotes
proving
an a r b i t r a r y
for
VIII,
Lemmas
by
over,
be
R.
infinite
TYPE
to c o n s t r u c t
solution
Ch.
for w h i c h
going
Simple
the real
genus
OF P A R R E A U - W I D O M
an a f f i r m a t i v e
5A,
for this
2A has
of i n f i n i t e
REGIONS
(DCT)
By T h e o r e m
surface PWS's
We are which
(DCT a) holds.
a E R,
As there
that
see that same re-
on
~\
(KU
it is i d e n t i c a l l y Since
in the
~\
domain
(KUF) of
u 0.
216
3B. A(c,~)
Lemma. are
Let
conformal
structure
the
we have
case,
Proof. which
We h a v e
symmetric
the
= 0.
disks
= L(~)
3C. with
that
Then
the
origin
disks
in t h e
A(a,b)
sense
a - 1 - b -I = c -I
to f i n d a f r a c t i o n a l and
carries
the o r i g i n • L
see t h a t
maps
and
of the
If t h i s
and
and
L(A(c,~))
are
intervals
and
-L(b)
and
A(a,b)
is
axis
symmetric
The
onto
L([c,~])
L(z)
and
b < d < c
L(A(c,~)),
L([a,b])
= L(c).
transformation
disks
the r e a l
L([a,b])
L(~(a,b))
the
linear
the
So let
disks
L(A(a,b))
-L(a)
to t h e
provided
Trivially,
if so a r e
computation.
[,
about
We a l s o
transformed
only
of
respect
the o r i g i n
(z - x) -I + d -I. L(0)
with
b- a = a2/(c -a).
only
preserves
to d i s k s
0 < a < b < c < ~.
symmetric
and
set
itself are
A(c,~) L(z)
and
diameters
respectively.
about
L([c,~]).
desired
result
This
of
So the
the origin
and
if a n d
happens
follows
=
if
by a simple
[]
Lemma.
Let
i : 0, i,...,
K 1• = ~ ( a i , b i),
0 < a n < bn < an-i
< a0 < b0 < ~
< bn_ I < -..
n,
be c l o s e d
and
set
the r e g i o n
Dn
disks
n
(5)
D
= [\(
u i=0
n We d e n o t e
by
gn(~,z)
at the p o i n t
at
points
.
x I,..
Proof. axis, on
Since
the
infinity
, x n,
~.
the r e g i o n
Dn
implies the
that,
interval
critical
the
(bi,
points
contours, theorem
for e a c h
shows
lemma.
has
(-~,
a
2,...,
with
n
of
n.
n, t h e r e
The
critical i
'
2
'''''
= 0.
critical
Ch.
V).
Dn
This
x. l xi's
has
as t h e
= 0
theorem
So t h e s e
points,
gn(~,x)
we get
the
is a s t r i c t l y
thus in are
n + i
Riemann-Roch
establishes
following decreasing
function
on t h e
interval
) . n
3D. tions,
As a t r i v i a l
we g e t
the
consequence
following
of t h e
definition
"
so t h a t
a point
since
n
to t h e r e a l
Rolle
exists
hand,
IC,
=
is r e g u l a r ,
Dn
other
n i
pole
[~gn(~,x + iy)/~y]y=0
2,...,
of Theorem
exactly ai-l'
<
with respect So
Sgn(~,xi)/~x On t h e
exactly
(see the p r o o f
point
i = I,
has x .l
<
with
[]
As a c o n s e q u e n c e , Corollary.
for
gn(~,z).
gn(~,z)
gn(~,z).
i = i,
a i _ I)
of
b I.
is s y m m e t r i c
boundary
gn(~,bi ) = gn(~,ai_l ) = 0
for
gn(~,z)
we h a v e
function
Every
function
Then
for which
so is the G r e e n
n Ki)" ~ \ (U i=0
Green
K.). 1
of the G r e e n
func-
217
Lemma.
Using
region
D
4.
the n o t a t i o n s
4A.
Theorem
We are in a p o s i t i o n
There
such that the f o r m
exists
H~(D)
to p r o v e
(ii)
a regular
possesses
in Ch.
VIII,
In v i e w of T h e o r e m
the s e c o n d m a i n r e s u l t
Let
of the
region
Dn
w i t h pole
in
[
of P a r r e a u - W i d o m
ideal w h i c h
type
is not of
VIII,
the d i r e c t
be c l o s e d
d<sks with
Cauchy Theorem
(DCT)
D.
0 < • -. < an defined
D
4G.
K i = A ( a i , b i)
the r e g i o n
region
a B-closed maximal
5A, Ch.
for such a r e g i o n
Proof.
Dn
in the
~ gn+l(~,z)
chapter.
Theorem.
fails
gn(~,z)
n+l"
Existence
present
in 3C, we have
<
b
n
<
an-i
by
(5), and
~.
Suppose
<
--.
<
a 0
gn(~,z) that
<
b 0
<
the G r e e n
an ÷ 0
and
~, function
for the
set
oo
s
= ~-\ ( u
K. u { o } ) .
i:l Finally,
let
g(~,z)
We c o n s t r u c t arbitrary
our disks
fixed closed
By C o r o l l a r y interval
be the G r e e n Ki
disk with
3C the f u n c t i o n
we c h o o s e
chosen
an+l,
disks
bn+ I
function
for
D
with pole
in the f o l l o w i n g
way.
0 < a0 < b0 < ~
and
g0(~,x)
(-~, a0) , we h a v e
that we h a v e
l
is s t r i c t l y
0 < g0(~,z) K0,... , Kn,
g s0
for
0 < an+ I < bn+ 1 < a n
with
0 < c n < 1/2,
K0
be an
s 0 = gB(~,0).
decreasing
on the
0 ~ x < a 0.
n ~ 0, w i t h
with
Let set
~.
Suppose
~i = gi (~'0)" satisfying
Then
the fol-
lowing conditions: (a)
an+ I = Cna n
(b)
bn+ I - an+ I = a n + 1 2 / ( a n - a n +
(c) where ~
n = 0, i,...}
should
This c o n s t r u c t i o n Let
u
satisfy
is a l w a y s
(resp.
the r e g i o n
tion
Kn+ I = A ( a n + l , b n + l ) , and the s e q u e n c e {Cn:
condition
by t a k i n g
on
n=0 On
sufficiently
of the D i r i c h l e t
small.
problem
for
n
Dn+ I
~Kn+ I (e) that
implies
an a d d i t i o n a l
possible
v ) be the s o l u t i o n
n
i) on
1 ) = {Cn/(l- Cn)}an+l,
i n f { g n ( ~ , z ) : z E ~Kn+ I} ~ se n w i t h is a f i x e d c o n s t a n t w i t h 0 < ~ < i
w i t h the b o u n d a r y
and to Un(Z)
that the d i s k
0
on
$ ~CnVn(Z) Kn+ I
data
equal to
~K 0 U ... U ~K n. on
Dn+ I.
gn(~,z)
It f o l l o w s
(resp.
On the o t h e r hand,
and the i n f i n i t e
disk
to
f r o m the c o n d i -
A(an,~)
LemJna 3B
are
sym-
218
metric
with respect
A(an,~) , Lemma Un(Z)
in
to the origin.
3A shows
that
Dn+l, we have gn+l(~,O)
Since
Vn(0)
K 0 U ... U K n
~ 1/2.
Since
is i n c l u d e d
gn+l(~,z)
in
= gn(=,z) -
in p a r t i c u l a r
= gn(~,O) - Un(O) < ( i - ~/2)~ =
S gn(~, O) - e a n V n ( O )
. n
Thus we h a v e by i n d u c t i o n ~n =< ( i - ~ / 2 ) n s O.
(6) By L e m m a all
n.
So
creasing Harnaek monic
theorem
function,
D.
gn(~,z)
sequence
boundary on
3D,
value
of b o u n d e d sequence
say
u, on
0
Namely,
gn(~,z) then
say
in e a c h of the
converge shows
can be m a d e a r b i t r a r i l y
small
large
that
enough.
g(~,z)
a regular
Since
tends
region.
to
~ gn(~,z) z
tends
s
is a r e g u l a r
Next t a k e any boundary total
values
l e n g t h of
(7)
for
at a l m o s t
see t h a t
in
D, w h e r e I ~K
n : i, 2,...,
n
for e v e r y
The point,
and t h e r e gn(~,z) by l e t t i n g
n, we c o n c l u d e Namely,
D
is
(i- e/2)neo < ~.
n =0
We see that
every point
f
has the n o n - t a n g e n t i a l
on the b o u n d a r y
~D.
S i n c e the
is finite,
f(z)
z
D.
that
of the o r i g i n
to the origin.
[
on
PWS.
f E H~(D).
~D
~ n
har-
identically
n = 0, i,..., (6) i m p l i e s
~ gn(~,Zn ) ~ ~ gn(~, 0) n:O n=O
[
By the
seen to h a v e
g(~,z)
g ( ~ , z n) ~
n=O
D.
vanishes
we have
= D
to
for de-
nonnegative
Moreover,
n:O
Hence,
an) ,
in a n e i g h b o r h o o d
as
D
has a s i n g l e c r i t i c a l
The r e l a t i o n
g(~,z) 0
(bn+l,
on
is e a s i l y
and t h e r e f o r e
g(~,z)
intervals points.
u
decreasingly
that
e x i s t no o t h e r c r i t i c a l
n
~D
functions
to a b o u n d e d
The f u n c t i o n on
on the r e g i o n
is a m o n o t o n i c a l l y
harmonie
converges
D.
everywhere
principle
~ g(~,z)
n = 0, i,...>
positive
this
argument Zn,
~ gn+l(~,z)
{gn(~,z) - g(~,z):
= f(~)
+
each path
I = the l e n g t h of we have,
for e v e r y
[ 1 ~ n=0 ~K ~K
n n z
f
~K
f({) d~ ----2-7 c n
is d i r e c t e d
clockwise.
= ~e n l a n / ( l - C n _ in the n e g a t i v e
S i n c e we
I) < 2~c ,a = n-~ n r e a l axis,
for
219
I
f(~) d% ~- z
~K
< IIfll ]~Knl/a n < 2Wen_iIifil . . . .
"
n So the r i g h t - h a n d In:0 Cn Then
side of (7) c o n v e r g e s
is e o n v e r g e n t .
f(z)
tends
to
We d e f i n e
f(0)
as
even
f(0)
z
for
z : 0, for the series
by the f o r m u l a
tends
to
0
(7) w i t h
z : 0.
a l o n g the n e g a t i v e
real
axis.
4B. Lemma.
We n o w i n t e r r u p t If
D
is as a b o v e a n d
is a B - c o n t i n u o u s Proof.
complex
(i)
¢(f)
above,
¢(f)
= f(0)
We t h e n s u r r o u n d Yn'
~
n.
and
:
: f(0) of
lim x÷-0
is an a l g e b r a i c
each disk
n = 0, i,...,
ented clockwise; each
if
homomorphism
As we h a v e r e m a r k e d
It is t h e n c l e a r that ¢.
the p r o o f and s h o w the f o l l o w i n g
Kn
T h e n it f o l l o w s
iYnl
for any
z
in
is t r u e
each
~
CI(D)
for
on
lying
z = 0.
homomorphism
exclusive;
(ii)
(= the l e n g t h of
f r o m the u s u a l
Cauchy
¢
of
in
H (D) D
each
into
such that Yn
is o r i -
yn ) ~ 3 1 ~ K n l / 2
integral
formula
for that
f(~) d -~z Yn
in the e x t e r i o r
The p r o p e r t y
then
f(x).
Yn
1 I f(6) 1 - z 6d~ : ~ i 2-~ ~K n
this
f E H~(D),
by a c i r c l e
are m u t u a l l y
(iii)
for
H=(D).
(iii)
of
Yn"
of
Yn
In p a r t i c u l a r , implies
that
for
Yn On_ 1 °a : a n - 2 ( i _ Cn_l )
I~] => a n - ( b n - an)/2
n
3en_l/2
-
It f o l l o w s
f(%) ~
d~n(C)
n
>
a
n
/2.
iYnl l~Knl < i)f)) .a---77 =< 3Jifil~ - - -a n n
d~
=
Yn For e a c h
a
n-i
that I[ i]
(8)
1l-c
n = 0, i,...
= (2wi~)-id61y n
we d e f i n e •
3On_ I.
Since
In=0 ~ Cn
finite
Borel measure =.
fD f ( z ) d ~ ( z )
for
~n
T h e n the i n e q u a l i t y
defined
at the p o i n t
a measure
is c o n v e r g e n t , on
S i n c e the f o r m u l a f E H=(D),
~ =
D, w h e r e
~
(7) w i t h
it f o l l o w s
< 6wttf)i~ C n - I
=
on
D
"
by the f o r m u l a
(8) i m p l i e s
that
n:0 ~n + ~
is a w e l l -
denotes z : 0
from Theorem
11~nll < =
the D i r a c m e a s u r e
shows that 5C, Ch.
¢(f)
IV, that
:
220
¢
is B - c o n t i n u o u s
4C. and
¢
In o r d e r
ideal
factors.
of
To
respect
(see
Ch.
single
I,
~(~Kn)
Un=0 ~
~Kn
ease,
(ii)
Take
that
of
that
7
then
in Ch.
a polar
Vlll,
÷ ~
I
7
to
D
Since
is a B - c l o s e d common
see that
~
7
be the h a r m o n i c
~D = Un= 0 ~K n u
as
= 0}.
no n o n c o n s t a n t
of h a r m o n i c set,
we c o n s i d e r
~(f)
maxinner
cannot
4G.
let
~({0})
continuous
z ÷ 0
measure,
at the p o i n t Since
= 0
and
function
u~
U n=0 ~
through
<
u~({)dw(6)
{0}
measures).
we have
any n o n n e g a t i v e
u~(z)
4A,
H~(D), has
it is easy
7,
definition
forms
= i.
such
homomorphism
D, of the b o u n d a r y
{0}
of T h e o r e m
J = {f E H~(D):
concerning
5D for the
point
~n=0
form
claim
proof
set
We c l a i m
is the
to
the
and
complex
in the
see our
with
finish
above
H~(D).
If this
be w r i t t e n
H~(D).
to
constructed
is a B - c o n t i n u o u s imal
on
~K n
the therefore on
and
~.
~D Let
u0
be the
with
the
boundary
see that to
0
u8
as
I,
z
u0(z)
5B
tends
in
sense
tion,
say
that
lh01
an o u t e r has
D. D.
of Ch.
h0,
(cf.
no n o n c o n s t a n t
that
~(D,~
-I)
We n o w factor
tains
a function,
We d e f i n e
has
h.
k E 7.
But
divisible
by
+ 0
So t h e r e ~
inner
say
as
~(D,~ hl,
at the
l.a.m,
D
= -u 0
has
through that
inner J
factor
see that z ÷
to
by this
0 l.a.m.
holomorphic
secsuch
that
6A,
Ch.
h0
is
~(D,~) VII,
we
see
factors.
has
no c o m m o n
k = h 0 h I.
of
h 0 E ~(D,~))
means
By L e m m a
that
0
sense
is q u a s i b o u n d e d ,
clearly
common
origin
tends
determined
to
tends
function
and
(i.e.
inner
shows
We thus
a bounded
lh0(z)ilhl(Z) I ~
our c o n s t r u c t i o n h, w h i c h
whose
z ÷ 0
Look
the
in the
exists
factors.
by s e t t i n g
that
problem
D
it is easy
g(=,z)
on
This
-I)
Then
in 4A,
means
bundle
log lh01 5D).
for the r e g i o n
111.36).
D.
line
on the c o n t r a r y ,
Since
This
Dirichlet
through
bundle
II,
shown
Theorem
no n o n e o n s t a n t
k E H~(D)
k(z)
As
it is a b o u n d e d
Since
Ik(z) I = so that
2C.
problem Un= 0 ~K n.
D.
82,
0
line
Ch.
D.
be the
common
suppose,
inner
p.
~
= exp(-u0).
l.a.m.
on
for the
to
II,
of the
u~
on
Clearly, Let
Dirichlet
to
through
[65],
tends
on
z ÷ 0
in the
z
0 point
Tsuji
as
exp(-u0(z)) as
of the
equal
to
boundary
(cf.
+ ~
data
is q u a s i b o u n d e d
is a r e g u l a r Ch.
solution
a noneonstant inner
is not
common
factors,
divisible
it con-
by
h.
Then,
IlhlII~'exp(-u0(z)), D. the
is a c o n t r a d i c t i o n .
This
means
inner This
in p a r t i c u l a r
factor proves
of
k
Theorem
that
is not 4A.
[]
221
4D. the
As we e a s i l y
fact
that
disks
by any
axis;
e.g.
§3.
5.
FURTHER
Banaeh and
to H o f f m a n algebras
under
[34]
and
Let
set
the
H~(R);
namely,
M(H~(R))
space
of the
Banach
know
by the
pact
Hausdorff
function, for
every
uous
and
of
{
the
fine
{~i} if
H~(R).
theory
space.
the
For e v e r y
space
+ ~(f)
defined
each
from
H~(R)
element
a
on f u n c t i o n s the
reader
of
i.e.
H~(R),
into
the
The
identity
~ • topolspace
i, we
we a s s o c i a t e
seen
f(~)
a
= ~(f)
to be c o n t i n -
(Namely,
preceding,
= I.
is a c o m -
by s e t t i n g
is e a s i l y
in the
~(i) to
ideal
M(H~(R))
H~(R)
f.
set
to an e l e m e n t
that in
of
with
f • H~(R).
is d e f i n e d f
¢
the
relative
the m a x i m a l
has
f
transform that
fixed.
forms
of B a n a c h
for e a c h
function
Gelfand
of b o u n d e d
exposition
converges
algebras
Which
R
We r e f e r
topology
is c a l l e d
Since
The
weak
M(H~(R))
M(H~(R))
is d i f f e r e n t
boundary
to the r e a l
is h e l d
on
operations
Ha(R)
the
of B a n a c h
With
~ • M(H~(R)). is c a l l e d
on
H~(D).
ideal
with
~l(f)
algebra
f, on
depend
algebra
which
functions
for a d e t a i l e d algebra
in
thus
Banaeh
z • R}.
of the a l g e b r a
M(H~(R))
say
here
[12]
of the
~
only
not
if we r e p l a c e
respect
be a PWS,
algebraic
be the m a x i m a l
general
the
R
holomorphie
is e q u i p p e d
if and
ogical
Let
pointwise
or G a r n e t t
a net
with
goes
Space
IIfll : s u p { I f ( z ) l :
especially
M(H~(R))
4A does
proof
axis.
is to i n v e s t i g a t e
norm
M(H~(R))
same
symmetric
Ideal
on a PWS.
of all h o m o m o r p h i s m s The
are
of T h e o r e m
The
on the r e a l
of all b o u n d e d
supremum
proof
OF PWS
objective
algebra
the
which
the M a x i m a l
functions
H~(R)
our
is a disk.
intervals
into
Our
set
n sets
PROPERTIES
Embedding 5A.
see,
K
closed
closed
holomorphie The
each
the m e a n i n g
where
f
meant
function.)
point
z • R
the
evaluation
functional
e : f ÷ f(z) Z is a n o n z e r o mines on into
homomorphism
an e l e m e n t
R, the m a p
the
This
means
evaluation
set
z At this
H~(R)
in t u r n
of the
M(H~(R)).
z + s
M(H~(R)).
Then
in
is seen point
separates that
functionals
algebra Since
f
into in
to be a c o n t i n u o u s we use
our hypothesis
the p o i n t s
distinct of
H~(R)
every
H~(R).
points So,
of z
by
R in
~
and
H~(R) function that
from R
by T h e o r e m R
determine
identification
so d e t e r -
is c o n t i n u o u s R
is a PWS. 9B,
Ch.
V.
distinct
of each
point
222
z
w i t h the c o r r e s p o n d i n g
M(H~(R)).
functional
In v i e w of the e x i s t i n g
to the f o l l o w i n g (i)
ez, we r e g a r d
theory
of
R
H~(~),
as a s u b s e t of we n a t u r a l l y
come
questions:
Is the e m b e d d i n g
z ÷ E
of
R
into
M(H~(R))
a homeomor-
Z
p h i s m onto an o p e n (ii)
Is
R
The first explained corona next
subset? dense
question
right
problem,
below.
in the
space
M(H=(R))?
has b e e n a n s w e r e d As for the
the a n s w e r
which
is not d e f i n i t e .
The r e s u l t
is u s u a l l y
We w i l l
called
discuss
is
the
it in the
section.
5B.
We n o w s e t t l e the q u e s t i o n
Theorem.
If
R
maximal
ideal
Proof.
Let
n o t e by
space R
0.
is a P W S ,
(i).
then e v e r y open
M(H~(R))
be a PWS.
of
Take an a r b i t r a r y
of
0
in the
TR
~
is o p e n
in
in the
R, w h i c h we de-
each n e i g h b o r h o o d M(H~(R)).
of
0
in
R
To show this,
in §i of Ch.
IX can be u s e d h e r e
map
with
•
+ R
be the g r o u p of c o v e r t r a n s f o r m a t i o n s
for
arguments
be the u n i v e r s a l
in 3F-3H of Ch.
be the g r e a t e s t
character P0(0)
R
change.
Let let
point
space
we first n o t e that all the d i s c u s s i o n s without
s u b s e t of
H~(R).
What we n e e d to see is that
is a g a i n a n e i g h b o r h o o d
Q0
affirmatively.
second,
of
~ 0
element
QO"
and
covering
IX.
common
Set
H0(R)
i n n e r f a c t o r of
We t h e n t a k e a f u n c t i o n
JIP011~ ~ 1/2.
h E H~(R)
For e a c h
%.
P0
in
f E H=(R)
= 0
We r e p e a t
= {f E H~(R): H~(R)~ o ~
%(0)
f(0) and
the
= 0}. ~0
Let
the
H=(~,~0 ) there
and
such that
exists
a unique
such that h o ~ = (p0/Q0)( f o % - f(0)).
We d e f i n e
a linear
fixed
in
~
(S%f)(0). operator
(resp.
and
operator
with
As shown
Choose fixed,
{
T
I~I < i
in Ch.
IX,
in
3G,
Since
~(~)
S~
a complex homomorphism)
an e l e m e n t
f0 E H~(R)
with
by s e t t i n g
Tf : h.
s f = (I - ~ T ) - i f (resp. in
and
For e a c h }~f =
~ ) is a b o u n d e d
linear
H~(R). (Tf0)(0)
~ 0, w h i c h
is h e l d
set
v : {~ e M(H'(R)):
of
H~(R)
we set
Tf 0 E H=(R),
M(H~(R))
f0(0)
containing
= ~(f0)/~(Tf0).
= 0
and
the p o i n t
Clearly,
I~(f0) I < I~(Tf0)I}.
~
(Tf0)(0) 0.
~ D,
Define
is c o n t i n u o u s
V
is an o p e n
~: V ÷ C
subset
by the f o r m u l a
and has m o d u l u s
less
223
than
i
on
equation
V.
(14)
Take
in Ch.
any IX,
w
in
V
3G a f t e r
and
apply
setting
it to b o t h
h = f0
and
sides
of the
~ = Y(m).
We
get (9)
~(f)
for
every
the
equation
set
f E H~(R). (9)
U : VNR.
an o p e n
Since
implies Then,
subset
of
Since
~(z)
= f0(z)/(Tf0)(z)
on
i.
U, ~oo.
function
on
U
r 0 > O.
For
0 < r < r0
{m • V:
I~(w)I
< r}.
subset
U
R, e a c h
of
in
M(H~(R)).
Ur
(reap.
r0.
@
The
M(H~(R)). borhood
6.
spect
set
in the
set
is d e n s e
Theorem. (a)
Let
a subregion
(b) of
is compact.
onto
the
on
R.
M(H=(R)). R
that
0
in
Vr
for
is o p e n ~) m a p s
each
0 < r <
Ur = Vr
as a subset space
< r0}, Vr :
on the o p e n
(reap.
< r}
with
be in-
{I~I
R
for
0 <
of the
space
is a n e i g h -
is a r b i t r a r y
is o p e n
U
and
each
~
it is
holomorphic
< r}
see that
in the As
We
of
should
function
open
0
{.
= ~(Sz ).
a disk
I~(z)l
{161
T, we
is thus
of
~
Similarly,
disk
of
V,
includes
{z • U:
implies
of
the
every
in
R, we
in
M(H~(R)).
[]
R
is c o n v e x
with
functions
and
also
functions
on
R.
that More
following
if each R',
re-
holomorphic
PWS.
is a c o n n e c t e d
every
PWS
of all h o l o m o r p h i c
be a r e g u l a r
into
regular
of b o u n d e d space
bounded then
line
R'
the
following
surface
holomorphic
which
function
on
hold: includes R
R
as
extends
= R.
hull
If(z) I ~ s u p { I f ( ~ ) I :
Then
Riemann
bundle
R, the ~ ( R , ~ ) - c o n v e x {z E R:
r0
~(z)
is a u n i v a l e n t
in
of
subset
that
H~(R)
R
and
For
open
in the
R'
analytically
is open
0 < r < r0,
space
we w r i t e
is a c o n t i n u o u s
neighborhood
here
we h a v e
If
Ur
M(H~(R)),
H~(R)
We p r o v e
precisely,
K
every
of
to the
Ha(R)
Ur,
0
that
6A.
set
of into
it is h o l o m o r p h i c
~(U) =
V
be the r e s t r i c t i o n
Sz'
9
points of
I ( T f 0 ) ( z ) I } , so t h a t
~
z E U,
is the r e s t r i c t i o n
every
Density
with
So,
@
Ur
Let
words,
definition
Thus
of
conclude
we
Since
the
is i n j e c t i v e
= 0.
V r) u n i v a l e n t l y
Since
r < r 0.
The
~
In o t h e r 4(0)
z for
Since
with
If0(z) I < 0.
By i d e n t i f y i n g
than
separates
is an i n j e c t i o n
containing
U.
jective
~
U = {z e R:
R
set
less
H~(R)
that
to the
modulus
: ~(~)f
~
over of
R
and
every
compact
subset
K, n a m e l y
~ E K}
for each
f E ~(R,~)},
224
(c) R
Ha(R)
in the
is d e n s e
topology
The
of u n i f o r m
statement
(a)
(b) a n d
(c),
proof
(b) and
(c) w i l l
6B. R'
Proof
of
is c o n n e c t e d ,
nonempty.
Let
sequence [n=l
(a). the
b
Suppose
2,...}
for
some
bundle, 2B,
is seen
say
~.
Ch.
V),
such
Then
Thus,
f
R'
f
function
cannot
by
have
In o r d e r
results
functions
may
a eluster
to p r o v e
~ R.
R'
and
choose
R'
< ~
for
VII,
2A, the
l.a.m
.,
in
R'
a
and the
z e R \ {an:
function
which
is
denotes
every
z +
determines
by W i d o m ' s -I)
Since
space
g(a,z)
we find,
[ n=l
and
a
theorem
therefore
an
vanishing
at
g(an,Z))-
in
function (a)
f
be h o l o m o r p h i c
the
zeros
point
on
R
extends at the
in its domain.
holomorphi-
point
of any n o n z e r o
the
the p r o p e r t i e s
To m a k e
notations: on
X.
the
let
b.
This,
holomorphic
The
Riemann
the
statement
(a)
functions
on
R
the
points
such
following
(BI)
and
B-convex
that of
(B2).
we use
somewhat
subset
B F
two
gen-
simpler,
we
a set of c o m p l e x of
X
we d e n o t e
set:
surface
separates
(c),
be a set and
If(×) I ~ s u p { I f ( { ) I :
be c a l l e d
(b) and
description
X
For an a r b i t r a r y
following
{x • X:
hyperbolic
R'
an ÷ b
h E ~(R,~
holomorphic
should
because
of Bishop.
following
~(X,B)
which
The
[]
6C.
valued
is a PWS,
lh(z)lexp(-
bounded
Thus
is i m p o s s i b l e
the
subsection.
in the
within
that
in Ch.
section
R.
to E. Bishop.
that
R
R, w h e r e
g(an'Z)
By the h y p o t h e s i s
however,
is proved.
R
of
that
2, . . . .
into
R
to be an i n n e r
Since
is a n o n z e r o
n = i,
~n:l
a nonzero
If(z) I =
eral
in
RI
f • H~(R)
use
such
z
by the a r g u m e n t
(Theorem
tally
R
for
of
of
in
and,
due
contrary
point
subsets
on
6D.
boundary point
functions
in the n e x t
results
in
on the
holomorphic
on c o m p a c t
general
2,...}
exp(-~ n=l ~ g(an'Z))
an,
some
be d e s c r i b e d
be a b o u n d a r y
< ~
of all
is p r o v e d
function
n : i,
line
and
topological
{a n : n = I,
g(an'Z)
Green
we use
space
convergence
is easy
To p r o v e of
in the
R.
and A
hull
let
{ • F}
for all
of
Now,
A
contains
F.
let
be an a l g e b r a the
The t h e o r e m s
constant
of B i s h o p
f e B}, R
be a c o n n e c t e d
of h o l o m o r p h i c function we n e e d
are
i
and the
225
Theorem. every
(BI)
If
function,
F
can be a p p r o x i m a t e d (B2)
Suppose
all h o l o m o r p h i c gence
R'
that the
in
by elements is c l o s e d
and an a l g e b r a
A'
of h o l o m o r p h i c
element A'
(v)
e R' × R':
A
functions
conver-
Riemann
on
R'
such
as a subregion. is e x t e n d e d
precisely
of
z ~ w,
f(z)
R' × R'
holomorphically
of these
to an ele-
extensions.
for all
f e A'}
F'
of
R'
there
points
in
exists
a compact
R' × R'
F' ~ ~(R';A').
set
subset L
(z,w)
= f(w)
w h i c h has no c l u s t e r
subset
such that
with
F'
of
R'
and all points
E T.
The
and all r e l a t i v e l y
See Bishop of
R'
in
For each compact
F'
of u n i f o r m
of
set
R
w ~ L of
in
consists
subset
of
exist
F,
hold:
is embedded
For each compact
F
H(R)
Tc
the union of a compact
union
R
then
of
A.
in the space
a connected
is a c o u n t a b l e
exists
on
in
interior
in the t o p o l o g y
T = {(z,w)
subset
F A
F : ~(R;A),
on the
Then there
The
(iv)
on
that
with
R.
and
(iii)
uniformly
subsets
Every
A'
R
and h o l o m o r p h i c
of
R
(ii) ment
of
R
moreover
following
(i)
subset
on
functions
on compact
surface
is a compact
continuous
set
L
compact
[3] for the proof
of
the
set
z E R'
~'(R';A')
for which
can be taken
components
of
(BI) and Bishop
is
there
to be the
R' \ F'
[4] for the proof
(B2).
6D.
We are going
comments.
Let
H(R)
tions
on
R, w h i c h
gence
on compact
topological H(R)
subsets
algebra;
in
H(R). H(R)
Since
separates
that
the points
by Bishop's
theorem
and an algebra properties
function
(a) then rates
(i)
A'
of
implies
the points
R
Then,
exist
that of
(B2).
extends R'
of
set
conver-
its closure,
9B, Ch.
so does
(iii)
on
V,
the a l g e b r a Riemann
R'
into A'
say
A.
surface
which
R' = A.
(B2)
So, R'
satisfy
The
A,
T c-
H~(R)
~ A, every bounded
of
in
is c o n v e r g e n t
in the t o p o l o g y
a connected
H~(R)
in
H(R)
by T h e o r e m
and t h e r e f o r e T
in
H(R),
holomorphically
= R
R, the
func-
of u n i f o r m
is then a complete
algebra
functions
Since
Tc
H(R)
and a f o r t i o r i there
some general
and the m u l t i p l i c a t i o n
sequence
topological
of h o l o m o r p h $ c
R
space
Cauchy
is a PWS.
- (v) of on
The
is a s u b a l g e b r a
(B2),
We begin with
space of all h o l o m o r p h i c
the a d d i t i o n
and every
R
(c).
the
with the t o p o l o g y
R.
is also a c o m p l e t e
We now assume
phic
of
namely,
H~(R)
(b) and
as above,
is equipped
are c o n t i n u o u s
in
to prove be,
the
holomor-
statement
Since is void.
A
sepa-
226
Proof of
(b).
(v) of (B2) the
Let
set
(iO)
F
be an a r b i t r a r y
~(R;A)
is c o m p a c t ,
~(R;~(R,~))
for e v e r y
line b u n d l e
~
set
~(R;A).
(i0).
Choose
H~(R)
is dense
in
A
see that
H~(R)
F U {z}.
Suppose
exists
a point
Since
This b e i n g
where
e
hnf • ~ ( R , ~ )
for all
is a c l o s e d inclusion
and an e l e m e n t Tc, t h e r e
s u b s e t of a
relation
f E A.
in
Since
exists a sequence
{f } tends to f uniformly n b e l o n g s to ~ ( R ; H ~ ( R ) ) , we have
z
true
f
constant.
on
l h ( z 0 ) I,
Take any
f • ~(R,~).
and
in
So we
such that
< c e I :
2,...
we
Then there
~(R;H~(R)). R
in
A, we
inclusion
is not the case.
h
in
z • 9(R;H~(R)),
lying outside
~ e r)
the l i m i t s
is a r b i t r a r y
for e v e r y
function
n : i,
By t a k i n g
As
that this
holomorphic
is a p o s i t i v e
the s t a t e m e n t
Next, we show the first
z 0 • ~(R;~(R,~))
sup{lh(~)I:
is shown,
second
~ • F}.
~ ~(R;A).
on the c o n t r a r y
can find a b o u n d e d
By
~ ~(R;A)
n = i, 2 . . . . .
~ sup{if(~)I:
~(R;H~(R))
R.
We c l a i m
such that
~ e F},
z • ~(R;A).
(i0).
the
s u b s e t of
is void.
~(R;~(R,~))
in the t o p o l o g y
in
If(z)l
find that
because
T
Once this
z • }(R;H~(R))
Ifn(Z) I ~ s u P { i f n ( ~ ) l : n, we h a v e
R.
First we prove
a point
{f : n = I, 2,...} n on the c o m p a c t set
~ ~(R;H~(R))
over
(b) will be e s t a b l i s h e d , compact
compact
for
As we h a v e
z 0 • ~(R;~(R,~)),
so we get
If(z0) I = Ih(z0)nf(z0) I ~ s u p { l h ( ~ ) n f ( ~ ) I : ~ • F} e n . s u p { i f ( % ) I : ~ • F}. As
n
is a r b i t r a r y
point
z0
dicting
should
property
(c).
subset
clearly
(BI) w i t h
F
F
f of
f
zero of e l e m e n t s
Hence,
the first
be any h o l o m o r p h i c R
a n d set
F'
in
~(R,~),
inclusion
is a r b i t r a r y ,
[]
we h a v e
s u b s e t of
Moreover
F' : ~ ' ( R ; H ~ ( R ) ) .
the r e s t r i c t i o n
uniformly
on
R
function
F' = ~ ( R ; H ~ ( R ) ) .
is compact. that
can be a p p r o x i m a t e d
on each c o m p a c t as desired.
V.
implies
A = H~(R),
can be a p p r o x i m a t e d
As
Let
(b) just proved,
convex hulls
F ~ F',
9A, Ch.
f(z 0) = 0.
The contra-
in (i0)
is
[]
P r o o f of any c o m p a c t
0 e c < i, so we s h o u l d h a v e
thus be a c o m m o n
to C o r o l l a r y
established.
orem
and
F'
on
By B i s h o p ' s
flF ,
of
f
in
H~(R).
shown that by b o u n d e d
on f
F
Take by the
the d e f i n i t i o n
by e l e m e n t s
uniformly
R.
Then,
to the
by e l e m e n t s
set
F'
Since in
ean be a p p r o x i m a t e d
holomorphie
of
the-
functions
H~(R). uniformly on
R,
227
§4.
THE
7.
CORONA
(DCT) 7A.
an o p e n zebra R if
Corona
Let
be a PWS.
R
subset
R
in
(DCT)
now
M(H=(R))?
We
be p r o v e d
7B.
Let
V
sarily
into
[7]
M(H~(V))
says
Behrens
for w h i c h Consider eluded by
that
V
that
the
the
corona
in
conjecture
conjecture
of the of
H~(V),
holds
alIs
for
R
following type
for w h i c h
This
V
complex
is the
for the o p e n
This
if,
M(H~(V))
is not n e c e s we a g a i n
L. C a r l e s o n ' s
of c o n s t r u c t i n g
plane
case
If
V
conjecture
M(H~(V)).
in 4A.
is h o m e o m o r p h i c a l l y
although
corona
holds.
extended
V.
then
is true
construction
a continuum.
subset,
By the
a method
use of o u r
includes
as an open type.
conjecture is the
Banach
problem:
holds.
points
of
of the
corona
with
unit
a variety
is e x p r e s s e d
mean
famous disk.
reLater
of r e g i o n s as follows.
a sequence
in
V
r a d ( K n)
such
space
is d e n s e
[i] d e v i s e d
{K : n = i, 2,...} of d i s j o i n t c l o s e d disks inn centers ~ w h i c h c l u s t e r o n l y on ~V. We d e n o t e n the r a d i u s of the d i s k K n. We say that the s e q u e n c e {K n} with
is h y p e r b o l i c a l l y disks
ideal
of P a r r e a u - W i d o m
statement
sult
the
is i d e n t i f i e d
of P a r r e a u - W i d o m
subregion
[\ V
the
result
in 7C by m a k i n g
separates
the m a x i m a l
embedded
conjecture
R
M(H~(R))
corona
first
region
the c o m p l e m e n t
5B,
studying the
Our
be a c o n n e c t e d
H~(V)
space
say that
corona
will
denotes
ideal
a plane
This
such that
M.
exists
Examples
by T h e o r e m
set a b o u t
M(H~(R)).
but the
for i n s t a n c e ,
the
in
Positive
Then,
of the m a x i m a l
There
fails
Theorem:
We w i l l
is d e n s e
Theorem.
FOR PWS
and the
H~(R).
dense
PROBLEM
K' n that
with
rare
in the r e g i o n
centers
~
such
n
V
that
if t h e r e K
exist
C K' C V n = n =
disjoint
for e a c h
closed
n
and
co
r a d ( K n ) / r a d ( K n)
< ~.
n=l
Theorem. U
Suppose
is o b t a i n e d
closed
disks.
from
V
Then
the
See
Behrens
7C.
Proof
in 4A does
that
the
corona
by d e l e t i n g corona
[i] for the
of T h e o r e m
the r e q u i r e d
conjecture
holds
for
a hyperbolically
conjecture
holds
V
rare
and
a region
sequence
for
U, too.
show
that
of
proof.
7A.
We are
job a f t e r
going
a slight
to
modification
the r e g i o n
in the
D
construe-
228
tion.
We r e c a l l
requirements: 0 < ~ < i
that
D = T\
first,
and
let
(Un~ 0 A ( a n , b n) U {0})
~,
a0
0 < a 0 < b 0 < ~;
n = 0, i , . . . } ,
{a
n
: n = i,
and then
2,...}
b0
the
be a r b i t r a r i l y
determine
and
with
{b
n
three
: n = I,
following
fixed
with
sequences 2,...}
{Cn:
recurrently
by the c o n d i t i o n s : 0 < c n < 1/2
(CI)
and
[ n=0 ~
(C2)
an+ I = Cna n
(C3)
bn+ I - an+ I = a n + 1 2 / ( a n -
(C4)
inf{gn(~,z):
where
gn(~,z)
for
c n < ~,
n = 0, i,..., an+ 1 ) = { C n / ( l -
z • ~A(an+l,bn+l)}
is the
Green
function
with
\ (Ui7 0 A ( a i , b i ) ) . Take a sequence {X : n = i, 2,...} -i n such that [ n=l ~ Xn < ~ We t h e n set
pole
for the
n = i, disk
a i -Cn_ 1 2, . . . .
with
By a s i m p l e
A(a~,b~)
X n r a d ( A ( a n , b n ))" n = i,
2,...
Since
the
small, Then,
are m u t u a l l y
ture
last
by the
holds
to the
holds
punctured
disk
also
the
that
ically
D.
punctured
jecture
rare
A ( a n , b n)
Since
sequence
converge
n = i,
2,...;
X
> i
for e v e r y
n,
rad(A(a~,b~))
the
disks
included
the
{A(an,bn):
domain
[\
to
A(a~,b~
0;
n = i,
=
A(a',b')n n
in the r e g i o n
D
is a r e g i o n to show
~\
theorem
same
of P a r r e a u - W i d o m
that
rad(A(a
implies
the H~
as that
n = i,
for the
2,...}
are m u t u a l l y C [\ =
nl
n
n
:
X
n:l
Ii~ n <
the
disjoint
(A(a0,b 0) U {0})
~.
corona
con-
for the
disk.
of disks
because
type,
conjec-
is e o n f o r m a l
that
,b n)
~ad(a(a~,b ,)
corona
for the a l g e b r a
and
X :
the
(A(a0,b0) U {O])
(A(a0,b0) U {0})
' b') ~ A(an' n
c 's sufficiently n all the c o n d i t i o n s .
satisfying
only
2, . . . .
by t a k i n g
D
(A(a0,b0) U {0}),
is e s s e n t i a l l y
in the
and
and are
for
the r e g i o n
Carleson's
~\
A(an'bn) for
4A,
So we h a v e
disk,
for
region
of T h e o r e m
fails.
for
see that,
see that
disjoint
can be f u l f i l l e d
get a p l a n e
proof
numbers
Dn =
if we have
condition
(DCT)
we
A ( a n , b n) to
2en(l + A n + i O n ) < 1 - Xnen_ 1
we thus
for w h i c h
with
for the r e g i o n
i + (X - l ) C n _ i / 2 n .a i -Cn_ I n
b' = n
it is easy
n = 0, i,...,
n
computation
is c o n c e n t r i c Moreover,
\ (A(a0,b0) U {0}) (C5)
and n
~
for
of p o s i t i v e
i- (Xn+l)Cn_i/2 a' = n
Cn)}an+l,
~ ~gn(~,0)
We
see
is h y p e r b o l centers with
of
229
Thus T h e o r e m
7B i m p l i e s
that the c o r o n a
D, as was to be proved.
8.
Negative 8A.
Our o b j e c t i v e
t i o n of f a m o u s
genus.
Riemann
Sn'S
of d i s j o i n t
We d e n o t e
very
for w h i c h [43],
the c o r o n a the c o n s t r u c -
in a s i m p l e w a y to
simple trick
surfaces
by
~'n
joint u n i o n
be a s e q u e n c e
%
for d e f i n i n g
considered
copies
Let
0 ~ Re(z)
w i t h an open arc in
~Sn+ I.
B n') the left surface
~n
in
h e r e are
Since
R'
can be e m b e d d e d
which
R'
is not dense,
and d e f i n e
Bn_ I
O n : {z E Xn:
We s u p p o s e be a se-
vertical
for each B~
side of
n
the side
w i t h an o p e n are
are a s s u m e d
Riemann
surface,
Riemann
to be d i s j o i n t .
say
R",
surface.
in
Although
it is p o s s i b l e
to m a k e
simple m o d i f i c a t i o n .
{~n: n = i, 2,...}
a vertical
right)
is a PWS or not,
into a PWS a f t e r a s u i t a b l e Take a s e q u e n c e
(resp.
and
in a l a r g e r
R'
~S n. 2,...}
R' : R ( { S n } , { X n } ) , out of the dis-
it is a h y p e r b o l i c
we do not yet k n o w w h e t h e r
of c o m p a c t
< i}.
and the side
an
Sn
strip
by i d e n t i f y i n g
~Sn
H e r e the arcs
n = i,
~ 2, 0 < Im(z)
(Un~ I Sn ) U (Un~ I Xn),
Bn
borders
{Xn:
of the r e c t a n g u l a r
(resp.
an'
of i n t e r i o r s
with analytic
disjoint.
We t h e n f o r m a R i e m a n n
nn < i
PWS's
shown by N a k a i
All the R i e m a n n
surfaces
are m u t u a l l y
{z:
R'
As
of B. Cole can be m o d i f i e d
{Sn: n : i, 2,...}
bordered
X n.
for the r e g i o n
to be c o n n e c t e d .
Let
quence
is to p r e s e n t
We b e g i n w i t h N a k a i ' s
PWS's of i n f i n i t e
that
here
solution.
examples
such PWS's.
supposed
holds
Examples
p r o b l e m has a n e g a t i v e
yield
conjecture
[]
slit,
Re(z)
say
of p o s i t i v e On,
in each
= i, n n ~ Im(z)
numbers Xn
with
0 <
by s e t t i n g
< i}.
We set
R({Sn};{Xn};{nn}) so
R'
m a y be d e n o t e d
Theorem. then the Proof. of
W
by
If the s e q u e n c e surface We w r i t e
= R' \ ( U o ); n:l n
R({Sn}{{Xn}~{I}). {n n}
converges
R({Sn};{Xn};{nn])
W = R({Sn};{Xn};{~n})
corresponding
to the f i n i t e
to zero
is a r e g u l a r
union
sufficiently
rapidly,
PWS.
and d e n o t e
by
Wn
that part
230
I
Si
i:l
Each
fix a sequence
creasing a E SI the
U
U Xi\ai i:l
1
U {z e X
: 0 < Re(z) =
n
W is e a s i l y s e e n to be the i n t e r i o r n a n d t h e r e f o r e has a f i n i t e f i r s t B e t t i
face We
II
to
zero
and
let
surface
R'
W
g(a,z)
g(a,z) (resp.
pole
for e v e r y
of a c o m p a c t number,
: n = i,
n
a.
bordered
sur-
we call
B n-
which 2,...}
en+l ) < ~.
g'(a,z))
with
strictly
Take
be the
Green
Since
W
a fixed
function
depoint
for
is a s u b r e g i o n
of
z E W.
~n'S,
z = x + iy
{~
Bn+l(Cn-
(resp.
to d e t e r m i n e
coordinate
numbers
[n=l
R')
< g'(a,z)
In o r d e r local
of positive such that
< i}.
in
take X
an arbitrary
which
we u s e d
n
and
consider
the
at the b e g i n n i n g ,
so
n
that
X n = {0 =< x =< 2, 0 < y < i}.
{0 < x < 2, y = 0} in it is r e g a r d e d
may
Since
be r e g a r d e d
as a r e g u l a r
the
lower
as a b o u n d a r y
boundary
point
horizontal
arc
of
of
R'
R'
side each point
In p a r t i c u l a r ,
we h a v e g ' ( a , l + iy) as
y > 0
tends
such that
to
zero.
g ' ( a , l + iy) the
So t h e r e
e en
sequence
that
First
we
{~n )
with
0 < Y < ~n"
By t h e m a x i m u m
have
g(a,z)
for a l l
g ( a , l + iy)
e ~n
exists
for all
claim
see t h a t
÷ 0 a positive
I + iy E X n
thus
obtained
~ g ' ( a , l + iy)
.
the
< cn
principle
z E W \ W
has
choose
desired
Green any
nn > 0
0 < y e ~n"
for a l l
for the
Now
number
with
property.
i + iy E X n function
~
with
in t h e that of
Then
region
the
first
Wn+l,
the
region
Wn+ I
as a r e g u l a r
Betti
number
i.e.
B(e,a)
f Our assumption
W(e,a)
en
subregion of
on t h e
W
is a PWS.
bordered
ular.
Since
every
boundary
> en" This
B(~,a)d~
sequence
As
en
R(e,a)
is i n c l u d e d
I, IA). is n o t
It f o l l o w s larger
than
that
~ B n + l ( e n - Sn+l).
{E
n
On the o t h e r
Riemann
g(a,z)
completes
(Ch.
> e}
Cn+ I }
then
~ B(~,a)d~ 0
compact
g(a,z)
Thus
I namely,
> n
= {z E W:
B(e,a)
~ Bn+ I.
we
~
n
> en+ I.
We
surface,
is c o n t i n u o u s
on
Wn+ I
boundary Wn+ I
is the
interior
of a
points
of w h i c h
is reg-
and
is less
point,
we
see t h a t
{g(a,z)
~ ~}
tend
to
zero,
surface
is t h u s
the proof.
[]
the
that
< ~;
hand,
every
implies
than
is c o m p a c t seen
an
at
whenever
to be r e g u l a r .
231
8B.
A very u s e f u l
reformulation
of the c o r o n a
problem
is g i v e n
by
the f o l l o w i n g Theorem.
A PWS
R
for e v e r y
finite
sequence
such that
is d e n s e
in the space
of e l e m e n t s
M(H~(R))
{fi:
Ifl(z) I + . . - + Ifn(Z) I ~ ~ > 0
a sequence fng n = i
{gi: on
i = i, 2,...,
in
for e v e r y
H~(R)
n}
if,
in
z e R, t h e r e
such that
H~(R) exists
flg I + --. +
R.
Hoffman
[34; p. 163] p r o v e s
The p r o o f c o n t i n u e s
8C.
n}
if and o n l y
i = i, 2,...,
to be v a l i d
this
In v i e w of the p r e c e d i n g
the f o l l o w i n g
in the case of the unit disk.
in the p r e s e n t
in o r d e r to o b t a i n
theorem
ease as well.
it is s u f f i c i e n t
a negative
example
to p r o v e
for the c o r o n a
problem. Theorem. there
There
exists
a regular
e x i s t two e l e m e n t s
PWS
R
w i t h the f o l l o w i n g
f, g E H~(R)
property:
such that
IfI + IgI $ 6 > o everywhere
on
R
but the e q u a t i o n fh + gk : I
has no s o l u t i o n s Proof.
Let
of a c o m p a c t
the f o l l o w i n g
holomorphic
H~(R).
follows
0 < 6 < i
Cole's malformed
interior having
in
The c o n s t r u c t i o n
examples. notes
h, k
in
Wm
finite
there
]gmI ~ i,
fm h + gm k = i
tained Wm"
from
We t h e n
the s e q u e n c e say
let
by a t t a c h i n g
W, is a r e g u l a r
m
de-
namely,
W is the m with analytic border
W
m two f u n c t i o n s
fm' gm'
such t h a t
h, k E H = ( W m )
on
Wm;
implies
Ikl $ m.
S
be a f i n i t e R i e m a n n m an a n n u l u s to each b o u n d a r y
surface
is f i x e d PWS.
%,
W
m
form a Riemann {qm}
exists
Ihl + SUPw
m = i, 2,... Wm
m = i, 2,...
IfmI + IgmI ~ ~
m For e a c h
surface
on
with
SUPw
same lines as that of C o l e ' s
surface:
Riemann
and c o n t i n u o u s
the
For e a c h
Riemann
bordered property:
IfmI ~ i, and such t h a t
almost
be fixed.
R({Sm};{Xm};{~m})
surface
component
let
Ym
of
as in 8A, w h e r e
in such a w a y that the r e s u l t i n g
Then
ob-
be a s i m p l e a n a l y t i c
surface, arc that
232
starts
at
joining
~Wm, passes Sm
to
are m u t u a l l y
directly
Sm+l,
disjoint
and that
F: has no r e l a t i v e l y ways p o s s i b l e and
go
compact F
Lf01 __
using
(B2)
Carleman
go = gm
lg01
and
< 1
Igl ~ 2
ous way,
R
if n e c e s s a r y , So, using
denoting
by
RAW
and
H~(R).
based
we may assume the Green
and
have
f, g
We suppose
g01
theorems W
< @/4m for the C a r l e m a n of
F
W
on
in an obvi-
has no compact
compo-
as in the p r o o f of T h e o r e m
8A and
function
for
first
R
with
Betti
z E R \ W n.
on the c o n t r a r y
sup W
in
Restricting
W \ R
(BI)
such that
pole
number
a, we see
B
and that n
fh + gk : i.
lm = fm h + gm k"
fc
=
that
Define
It follows,
as we did in 8A,
f h + gk : 1
has no s o l u t i o n
there
elements
exist
the f u n c t i o n
1
on m
ting
is al-
F.
on
neighborhood
we show that the e q u a t i o n
such that
This
~unctions
on
for instance,
that
the same
W.
on B i s h o p ' s
Ifi + Igi ~ 6/2.
gR(a,z) ~ g(a,z) < gn for all that R is a r e g u l a r PWS.
H~(R)
Ig01 => 6
functions
[36],
in
continuous
n
Finally
Ym'S
%;
If01+
the same n o t a t i o n s W
that
conditions: on
be a c o n n e c t e d
gR(a,z)
n
next
+ S U P W--m U Y m l g -
f01
(See Kaplan
Let
If[ ~ 2,
components
Define
fo : fm'
approximation.)
X m \ Om
We assume
m:l
by the f o l l o w i n g
which
that
%1
type a p p r o x i m a t i o n
m = i, 2, . . . .
nents.
m:l
seen.
S U P W--m U Y m l f -
for
~Wm+ I.
the union
in 6C, we find h o l o m o r p h i c
(ii)
the slit r e c t a n g l e
at
complementary
as is e a s i l y
on the set
through
and t e r m i n a t e s
It follows Ii - lm[
from
: SUPw
m
h, k E W
by setm
(ii) that
i h ( f - fm ) + k(g - gm) V m
= SUPw
i h ( f - f0 ) + k ( g - g0)I m
~sup w
lhi + sup w m
<
If
m ~ JJhlJ~+ JJkrJ~, then
belong
to
H~(Wm )
(ithii
oo
llml ~ 3/4
and satisfy
Iki~'4~ m
+
llkiL
on
oo
)/4m.
W m.
Thus
fm(h/l m) + gm(k/Im)
h/l m = i
on
in
and Wm.
k/l m It
233
then follows
from the p r o p e r t y
of
Ih/Xml
SUpw
fm'
gm
Ik/Xml
+ SUpw
m
that ~
m
m
and t h e r e f o r e
sup w
Ihl
+ sup w
m
As
m
of
h
can be made and
space
k.
H~(R),
arbitrarily
Hence
Ikl
3m/4.
~
m
large,
the e q u a t i o n
this
contradicts
fh + gk = i
as was to be proved.
the b o u n d e d n e s s
has no solutions
in the
[]
NOTES Theorem such a PWS
IA t o g e t h e r
satisfies
Theorem
(DCT)
to that of Rudin
Koosis tive
example
Cole's
paper
Neville
[64].
That
[27].
but a simple
argument
In a sense our example
[7].
A simple
account
(Theorem
genus
6A)
8C)
finite
5B)
is taken
is a d a p t e d
described is similar
example
[47] contains
either
(Theorem
is due to Nakai
Riemann
solved
further
Hara
is new,
in his
furnished
by
[12] or in
while
See Gamelin
the nega[ii]
[14] c o n s t r u c t e d
conjecture
examples
[66].
in Garnett
[43].
surfaces.
the corona
7A)
[64] and
by C a r l e s o n
new proof was r e c e n t l y
may be found
for w h i c h
from Stanton
from Pranger
for the unit disk was
The p o s i t i v e
malformed
of infinite
by Hayashi
[30],
(Theorem
(Theorem
problem
A detailed [40].
found
by the author.
theorem
theorem
The corona
Wolff.
was
is due to Stanton
[68].
The e m b e d d i n g
very famous
its proof
4A is due to H a y a s h i
here has been devised
the density
with
for PWS's
holds.
of PWS's
satisfying
(DCT).
CHAPTER Xl.
CLASSIFICATION
OF PLANE REGIONS
This chapter deals with the c l a s s i f i c a t i o n p r o b l e m of plane regions in terms of Hardy classes or, more precisely, classes.
The result extends Heins'
surfaces given in bis book [31].
in terms of H a r d y - O r l i c z
c l a s s i f i c a t i o n table for Riemann
Using notations to be explained below,
our result can be expressed roughly as follows: 0 G = 0AB , : 0AS < N{0q: < U{0q:
0 < q < ~} < 0AB.
The first equality is long known p. 332).
0 < q < ~} < 0-P < 0p < 0 P+
(cf. Sario and Nakai
[62], p. 280 and
The second one concerns the q u a s i b o u n d e d m a j o r a t i o n and is
due to Segawa
[63].
Except these equalities,
all that happen in the
c a t e g o r y of Riemann surfaces can already be r e a l i z e d in the c a t e g o r y of plane regions.
The crux of our d i s c u s s i o n lies in c o n s t r u c t i n g a cer-
tain kind of exceptional
sets in the plane.
After having done this, we
shall see little d i f f i c u l t y in solving the problem. In §I we describe some basic p r o p e r t i e s of H a r d y - O r l i c z classes of analytic functions.
§2 is devoted to the c o n s t r u c t i o n of e x c e p t i o n a l
sets, b e l o n g i n g to a p r e a s s i g n e d class, of positive logarithmic capacity. A merit of our c o n s t r u c t i o n is that the size and p o s i t i o n of such sets can be at our disposal.
By making use of exceptional
sets we prove in
§3 our c l a s s i f i c a t i o n result, w h i c h implies the inclusion r e l a t i o n mentioned above as a special case.
§i.
I.
HARDY-ORLICZ
Definitions IA.
chapter, [0, ~) plane D
CLASSES
Let
be a convex function,
any nonconstant, with
~
~
~(0) = 0.
we denote by
such that
~(log+Ifl)
nondecreasing, For any region
H~(D)
by which we mean,
through this
convex function defined on D
in the e x t e n d e d complex
the set of h o l o m o r p h i c functions
has a h a r m o n i c m a j o r a n t on
D.
f
on
If this is the
235
case,
then
~(log+Ifl)
has the LHM,
We say that a set totally
disconnected
for any r e g i o n
V
the c o l l e c t i o n only c o n s t a n t If convex Hardy 0p
E ~ ~
compact
in
T
is a null s u b s e t of
including
of n o n v o i d
regions
E. D
in
of
defined
N~
and
0AB~)
NAB,,
We also d e n o t e on w h i c h
by
in Ch.
0G
IV.
follows
Every
sense that
0AB)
we o f t e n
is a
by
0~
contains
H~(D)
Q ~ t < ~, is a
coincides
w i t h the
We d e n o t e
(resp.
the c l a s s
with
of s u b r e g i o n s
(resp.
and
P AB*(D)
by
0¢)
N¢,
N
¢(t) D
no n o n c o n s t a n t
= t.
of bounded
use the c o n d i t i o n :
f E H~(D)
In fact,
~(t) ~ Cot
there for
i.e.
~(log+Ifl)
on
if
characteristic.
function
on
D
on
has a h a r m o n i c
numbers
f E H~(D)
D, then we h a v e
is of b o u n d e d
bounded holomorphic
So,
characteristic
log+Ifl
exist a p o s i t i v e
t ~ tO.
= ~.
is of b o u n d e d
log Ifl e SP'(D),
f
H~(D)
In this case we w r i t e
functions
lim ~(t) t t÷~
Hence,
E
= H~(V)
let us d e n o t e
= e p t - i,
class
He(D)
(resp.
(i)
function
if
functions).
In what
IB.
N~
D.
H ~ ( V \ E)
for w h i c h
0~, r e s p e c t i v e l y .
the class
t h e r e e x i s t no G r e e n
holomorphie
~
~(t)
and the c o r r e s p o n d i n g
HP(D)
in p l a c e
and if Moreover,
0 < p < ~, then the f u n c t i o n
class
set of class ~
on
functions.
function
(resp.
D.
for it is s u b h a r m o n i c
cO
and
and
u
log+Ifl
tO
on
LHM of the
~ c01u + t O
to any
in the
such that
is the
On the o t h e r hand,
belongs
D
majorant
H~(D).
on
D.
every Summing
up,
AB(D) ~ He(D) C AB*(D), where
AB(D)
is the
same as
H~(D).
Concerning
the c l a s s e s
0~, we
have
0G ~ 0AB, ~ 0¢ ~ 0AB. A precise 2.
Some 2A.
r e s u l t w i l l be g i v e n
later.
Basic P r o p e r t i e s We are g o i n g to state
classes
following
stated
for g e n e r a l
after
Parreau
Riemann
some b a s i c [51].
surfaces,
properties
Although
of H a r d y - O r l i c z
the p r o p e r t i e s
we r e s t r i c t
our a t t e n t i o n
can be to p l a n e
regions. Let
S
be a p r o p e r
such that the r e l a t i v e
subregion
boundary
of
S A ~G
~
and let (= Cn,
say)
G
be a r e g i o n is n o n v o i d
in
S
and con-
236
sists
of a n a l y t i c
side of
We
suppose,
moreover,
be a h a r m o n i c
function
on
that
G
lies
on one
such that
u = 0
Then
~(u +)
CO.
Lemma.
Let
on
and
CO
and
curves.
u
%(lul)
~(u-)
Proof.
have
A s was
has
a harmonic
harmonic
shown
majorant
majorants
in IB,
u
S ACI(G)
on
on
G.
both
G.
is o f b o u n d e d
characteristic,
so t h a t
+
and
u
u
Let such
exist {Sn:
that
(Ch.
n = i,
SI NC O
G AS I
such that
G n Sn
which
II,
5A).
2,...}
be a r e g u l a r
exhaustion
is n o n v o i d .
We c h o o s e
a component,
S I n ~G I ~ ~.
Moreover,
let
includes
G I.
We
set
COn
Gn
S n n ~G n
:
boundary
data
equal
to
0
on
COn
and
to
S
(Ch.
say
be t h e and
It is t h e n c l e a r t h a t COn is a p a r t of c O• + N o w let un be t h e s o l u t i o n o f t h e D i r i c h l e t the
of
GI,
of
component
problem
of
: ~G n \ COn"
Cln
max{u,0}
I, IA)
for on
Gn
with
Cln.
As
max{u,0}
on
+
max{u,0)
is s u b h a r m o n i c ,
we
see t h a t
u
is the
LHM of
n
G n.
If we d e n o t e
by
U
the
%(u +) ~G n.
Since
~(u~)
%(luI)
: ~(max{u,0})
n
on
L H M of
The
definition
< ~(Iul)
is s u b h a r m o n i c
of
on
G n.
Thus
Harnack
theorem
function, Since
{u~(z):
say
~(v)
the
on
Gn,
Theorem.
satisfying that G
G.
Let
We
If
G
CO
and
function
{u~} s~e
sense
vanishing
that
Proof.
In v i e w of the p r e c e d i n g
Let
U
be the
CO •
We d e f i n e
where any
~n = 0 a E GI
on and
~(u). n = i,
COn denote
and by
2,...} = i ~a(n)
so
z E G.
By the
harmonic + = u .
¢(u +) ~ U.
[]
let
~
be a c o n v e x
harmonic
function
majorant
exists
we m a y
~(u)
= 0
as b e f o r e on
and
on
function u
such
G, t h e n
a nonconstant
bounded
CO .
result,
Since
on
v = LHM(max{u,0})
a harmonic
there on
...
at e a c h
that
~ U.
2A a n d
has
~ U
to a n o n n e g a t i v e
that
a nonconstant
~(lul)
in t h e
{Gn:
converges
@(u-)
on
L H M of
is b o u n d e d
in
~(u~)
+
.-. ~ U
in f a c t
be as
carries
G
we h a v e
uI ~ u 2 ~
~ U, we c o n c l u d e
G
on
is h y p e r b o l i c ,
2,...}
show that
(i).
u = 0
harmonic
n = i,
we c a n
that
) ~ ~ ( U n + I) £
: l i m n ÷ ~ ~(u~)
Similarly,
2B.
implies
sequence
v, on
< U
+
un }(u
G, t h e n
=
+
G n.
on
Cln.
suppose on
and
Then
the h a r m o n i e
CO, set
that U
on
vn = H[~n;G n ]
vI ~ v2 ~
measure
u ~ 0.
vanishes
.--
for t h e
Take region
237
G
at the p o i n t
n
u(a)
f Cln
:
Since
%
p.
implies
63)
a.
Then
ud~ (n) a '
is c o n v e x
and
U(a)
I Cln
=
increasing,
(n) Ud~ a ,
Jensen's
I Cln
Vn(a ) :
inequality
d~ a (n)
(Rudin
[59],
that
If
/
U~a
1 f
a
C1 n
-<-
Cl n
< [
=
~ ( u ) d ~ a(n)/[ C1 n
d~(n)
;Cln Ud~(n)/f
Cln
Cln
a
d~(n) " a
Namely, (2)
Vn(a)%(u(a)/Vn(a))
for
n = i,
for,
otherwise,
in v i e w
of
harmonic
S
(i).
{Vn(a)}
of
say
which
Let
a harmonic
side
limit,
G
that
(2) w o u l d
v,
of
vanishes
on
be a r e g i o n
in
If
v
is b o u n d e d
on
be u n b o u n d e d
from
as
0;
n ÷
{v } is a n o n c o n s t a n t b o u n d e d n CO, as was to be shown. []
[
and
is a h a r m o n i c
majorant
away
S, t h e n
let
%
function
both
v
be a c o n v e x
on
and
S
such
that
LHM(~(Ivl))
quasibounded.
Proof.
By L e m m a
it is t r i v i a l l y there void
exists proper
then G.
on
satisfying has
means
left-hand
So the
Theorem.
function ~(Ivl)
This
the
(i).
function
2C.
are
2, . . . .
~ U(a)
G
namely, that
say
open
u
there
u0 = 0 S Ul,
is thus part v > 0 Pri(v)
subset the
exists on
CO
quasibounded.
If
and
on
S
is s t r i c t l y
[]
has
one
We
set G
on in
G.
We
S \ G.
v.
This
by
means
majorant
u = v-c
on
on
G
u0
to the
resulting The
that
this G,
the
the
such
function,
LHM of
for a n y
inner v
u1
quasibounded
is t r u e
function
on
is h y p e r b o l i c ;
u0
v.
Thus
is a n o n -
components,
extend The
Since
a harmonic
c}
of its
function
then
unbounded.
2B,
positive.
such
v
in 2A.
is m a j o r i z e d
by
is b o u n d e d ,
of T h e o r e m
harmonic
zero
v
assume
denotes
a harmonic
Hence,
If
{z C S: v ( z ) - >
mentioned
and
is m a j o r i z e d
~(v)
G
0 ~ u0 ~ I
identically
be zero.
we m a y
the h y p o t h e s i s
v
for w h i c h should
S.
and
of
v ~ 0.
such that
a nonconstant
is s u b h a r m o n i c bounded
of
that
so that
c > 0
condition
satisfies
by s e t t i n g
prQ(v)
assume
quasibounded,
a constant
satisfies
Since
whole
2A we m a y
part
should
be
238
2D. polar
Theorem.
set
(Ch.
tion
on
G
such
some
convex
a harmonic Let
be the
bounded monic
that
SO
data on
on
equal
SO.
Theorem
impossible, u
§2.
NULL
3.
for
( U + ~(livU
then
Since
to
F
OF CLASS
u
u
F
be a c o m p a c t
is a h a r m o n i c U
on
G
is e x t e n d e d
to
funcfor F
as
Let
as
%(t)
for
))/2
on
on
S O \ F.
~(iu01) G.
SO \ F
set.
F
and
SO
with
~S0,
v
is also
u0
is h a r -
Then
the
~ ¢((lul + 1vi)/2)
If
u0
should
Hence
be a c o n v e x
function
~
were
nonconstant,
be h y p e r b o l i c .
u0 ~ 0 function.
to
there
on
SO
This
and
is
there-
[]
such
= 0
and
~
as
large
t;
the r i g h t
t ÷ =
exists
We w r i t e t => to,
~(t)
tO > 0
E(t)
both
Let
E(t I) $ 4 for
number
with
property:
-~(t2) > 32
and
in v i e w that
E(t)
of
#(t)/t
t}
and
and
E l(t)
and
tI
be a r e a l
El(t I) ~ 2.
num-
We
set
t I ~ t ~ t2,
_~l(t2) > 3.
t 2 > t I + i, When
the p r o p e r t y :
( n + l ) l o g 2},
}'(t + 0)
way.
~ t I + 2 ( t - t I)
n => 3, w i t h
such
= min{#(t)/t,
so that
by i n d u c t i o n .
the
derivative
nondecreasingly,
a number
t I $ m a x { t 0 , log 2},
~ ( t n _ I) > m a x { ( n - 2 ) t n _ l ,
Then
that
in a n o n d e c r e a s i n g
tn_ 2 =< t =< tn_l,
(i).
l i m t + ~ ~ ( t ) / t 2 = 0.
it has
for
our
satisfying
(i);
t ~ tO. 2t}
function
for all
is c o n v e x ,
t ÷ ~
is a r e a l
m a x { t 2 , 41og 2},
on
contains
for
N~
¢
tends
Thus
construct
that
which
is b o u n d e d
as a h a r m o n i c
satisfies
= m i n { % ' ( t + 0), ~
S
problem
Lemmas
t, w h i c h (i).
of
and
that
is a p o l a r
~(t)
for
imply
limt+ ~ ~(t)/~(t)
t2
(i),
u
~S 0
(A3)
such
where
on
~(t)
to
let
majorant
u 0 = ( u - v)/2
(A2)
We n o w ber
~
a convex
is n o n d e c r e a s i n g
tend
and
a harmonic
Dirichlet
Since
~(t + log 2) ~ 27(t)
for all
= (t) -i
set
F
Lemma.
exists
u.
u0 : 0
2B w o u l d
SETS
condition
[
If
subregion
of the
(AI)
Proof.
has
in
G = S \ F.
satisfying
to
We
Preliminary
there
~
is e x t e n d e d
3A.
Set
be a r e g u l a r
S O \ F,
fore
be a r e g i o n S.
~(iui )
solution
(~(iui) + ~ ( i v l ) ) / 2 then
S
in
function
let
boundary
6C)
function.
Proof. v
Let
I,
E(tn_ I) > n
~(t)
2tn-i and
~(t 2) > is d e t e r m i n e d
=> tn_ 2 + i, _~l(tn_l)
> n,
239
we d e f i n e $(t) where
= $ ( t n _ I) + n(t - tn_ I)
for
tn_ I ~ t g t n,
tn
is a r e a l n u m b e r w i t h the p r o p e r t y : 2 m a x { ( n - l ) t , ( n + 2 ) l o g 2}, E(t n) ~ ( n + i) and of the m o n o t o n i o i t y
property
seen to be p o s s i b l e , ously,
~(t)
for all [0, ~)
so that
is c o n v e x
0 g t g tI with
~(0)
of
for
Z
and
~(t) t ~ tI
t => t I .
and
~(t n)
Zl(t n) ~ n + I.
Zl, t h e s e
is d e f i n e d
operations
for all
In v i e w are e a s i l y
t ~ t I.
Obvi-
it is easy to c o n t i n u e
so as to h a v e a n o n d e c r e a s i n g
convex
~(t)
function
on
: 0.
We n o w h a v e o n l y to s h o w that ties for
t n ~ tn_ I + i,
~(t)
tn_ 1 =< t ~ t n.
Let
possesses
the d e s i r e d
t + log 2 =< t n + i
Then
propertn+ 1
and t h e r e f o r e ~(t + log 2) g ~(tn_ I) + (n+l)(t + log 2 - tn_ I) = ~ ( t n _ I) + ( n + l ) ( t
- t n _ I) + ( n + l ) l o g
2
2~(tn_ I) + 2n(t - t n _ I) =
The c o n d i t i o n
(AI)
2~(t).
is thus
satisfied.
n ( t - t I) + t I ~ ~(t)
For the
~(t)/#(t)
÷ 0
shows t h a t
3B.
E(t) ~ n 2, we h a v e and
t/~(t)
The
~(t)/t 2 + O ÷ 0
as
following
as
t ÷ ~.
result
t
we h a v e
= ~(tn_ I) + n(t - tn_ I)
(n-2)tn_ I + n(t-tn_ As we k n o w that
same
~(t)
I) > (n-2)t.
=> n2t
t + ~.
and
t 2 => n2t.
The a b o v e
Thus
inequality
also
[]
shows the
importance
of the c o n d i t i o n
(AI) or, m o r e g e n e r a l l y , ~(t + log 2) = 0(i), ~Ct)
(3) which (of.
is e q u i v a l e n t Krasnosel'skii
Lemma.
Let
let
be a t o t a l l y
E
and o n l y if Proof.
~
to the A 2 - c o n d i t i o n and Rutickii
be a c o n v e x
in the t h e o r y
of 0 r l i c z
spaces
[41]).
function
diseonneeted
t ÷ ~,
which
compact
satisfies set in
¢.
(i) and Then
(3) and E E N~
~ \ E e 0~.
S i n c e the n e c e s s i t y
is t r i v i a l ,
we o n l y
show that
[ \ E 6 0~
if
240
implies V 2 E not
E E N}. and any
vanish
and
u
~(u)
~ U
LHM of
on
now divided
both
u = lim
into
and n~
Let
and
parts. that
are
uA n
and
U
E
U : lim
are b o u n d e d ,
means
of T h e o r e m
2D o r o t h e r w i s e .
monic
on
V
and
that
quently,
f
is b o u n d e d
even
(ii) In t h i s We
part,
set
Since
we
Hence,
suppose
assumption
We may
assume
case
analytic V \ En,
curves
and
now
loss
that
where
2C, Ch. II,
uA n
and
functions
and
by
U are harConse-
therefore
is h o l o -
to be p r o v e d . E
is not
F = [\ V
including (i)
shows
that
E
is n o t
of generality
a polar
is a p o l a r
F
and
that
f
set. set.
f E H ~ ( S \ F).
f ~ H~(S).
is a c o n s t a n t
of
a polar
that
region
is c o n t i n u o u s
n $ i, be a n e x h a u s t i o n
boundaries,
and
that
i.e.
in
both
by c o n t i n u i t y .
E
as w a s
implies
is a J o r d a n f
seen
5C,
is
Our
function.
f E H~(V).
suppose
V
V E 0G,
by T h e o r e m
Since
u
V \ E
proof
by Theorem
that
does
see t h a t
The
as h a r m o n i c
of
follows,
is a r e g i o n
S E 0~
without
in w h i c h
V
V, as
our proof
that
Finally,
on
Then,
Thus, V \ E.
to
f C H~(V),
S
set,
set.
It f o l l o w s
in w h a t that
Then
it is t r i v i a l (iii)
~ U
}(u).
f on
We e a s i l y
L H M of
on
extended
any region
that
}(log+Ifl)
IB).
V \ E.
in a n e i g h b o r h o o d
suppose,
is a p o l a r
original
the
E.
S = [ \ E. F
Hence
on
So we
~(u)
on UA n
n~
UA n
morphic
are
is the
We take
of c o u r s e
L H M of (see
is a p o l a r
quasibounded
these
suppose
v \ E
in f a c t
three
[ \ E E 0~.
be t h e
on
suppose
U
that We m a y
U
log+ifI
V \ E
First
u
suppose
identically.
the
(i)
So w e
f E H ~ ( V \ E).
~ ~ V.
bounded
up to t h e
V k E
E =C En+ I =C En =C V,
set a n d
We b e g i n
by a f i n i t e boundary
by J o r d a n
n => i.
V ~ 0 G.
of
V.
regions
For a n y
with
number
of
Let
with
analytic
z @ V \ En
we
have
f(z)
1 SaV f(~) ~ = ~ d~
i IDE ~f({) r ~ d~.
= 2-~
- 2-~
n
The
first
and
spectively
by
respectively. that
g(z)
the
second
g(z)
members
and
F r o m the
hn(Z) , which fact
is c o n t i n u o u s
f(z)
by a c o n s t a n t
on
V \ E1
and therefore
define
on
[ \ E.
We t h u s
f(z)
lh(z)I
~ M+
positive C2
on
If(z) I
constants
M > 0.
there. CI
and
right-hand are
C2
(z) of
see a l s o
a single
o f the
on
that
on
property
denoted
and on
re-
[ \ E n,
V \ E and
all
follows n so is b o u n d e d
(z) n function,
V \ E
in s u c h a w a y t h a t
are V
on V
holomorphie
= g(z) - h(z)
By u s e
n
boundary
We
side
defined
: g(z) - h
up to the
in m o d u l u s
have
of the
h
and
(3) of
coincide h(z),
consequently ~
we f i n d
~(log+lhl)
£ CIU+
V \ E.
Let us
fix a point
z0 C V \ E1
and
denote
by
Bn
(resp.
v n)
the
241
harmonic
measure
at the
point
z0
with
(resp.
V \ E ) for n = i, 2, . . . . n a constant C > I s u c h that
find
see this,
take
a Jordan
E 1 C ~ C CI(~) a region
region
_C V \ {z0}.
D, we
for
n = i,
have
Green
and
V \ E = Un~ I V \ E n.
most
~.
in
E
So,
there
each
exists
fixed
g(a,z:D)
a polar
by a s s u m p t i o n
): n = i
boundary the
set,
for all
DE n
set,
such
Green
2,.
that
}
we can n.
To
that
function
the
g(w,z0;¢\
sequence
for
{m n}
g ( w , z 0 ; ¢ \ E) ;V\E) g(w'z0
principle
and
¢\ E
V \ E 1 C V \ E 2 =C ...
to
we
g(w
see that
z0;V\E)
al-
E n) ÷ g ( w , z 0 ; V k E )
E n) ÷ g ( w , z 0 ; ¢ \ converges
E)
uniformly
to
< oo.
i < C < ~ such = < C g ( w , z 0 ; V \ E n) for all
n, the m a x i m u m
V \ E
theorem,
tends
a constant
E n)
both
n ' "" In p a r t i c u l a r , g(w,z0;V\
max wED~
g(w,z0;¢\
analytic
by
by use of H a r n a c k ' s
Similarly,
Consequently,
i.e.
with
is not
We k n o w
V\E.
D~.
Hence
on
¢\ E n
a polar
g ( w , z 0 ; ¢ \ E n) g(w,z0; V \ E n ) <
= wmax ED~
{g(w,z0;VkE
on
~
to the r e g i o n
is not
dun =< Cd~ n
Denoting
Since
functions.
uniformly
uniformly on
2, . . . .
sequence
E
set
mn
the
respect
Since
applied
that n
m
and
to the
< C for all n, n = all w E D~. For
region
~ \ En
shows
that (4)
g(w,z0;[\
for all
w E ~ \ E n.
E n) ~ C g ( w , z 0 ; V \ E n)
On the o t h e r
hand,
we have
dUn(W)
:
i 2--~ ~ ( w ' z 0 ; [ w
d~n(W)
:
~--~
along
DE n
\ Enlldwl
and (w,z0;V \ En)idw I, w
where
D/Dn
the o u t w a r d
arc-length desired
normal
element
the d e r i v a t i v e
relative
along
to
at
[\ E n
DE . n
w C or
Combining
DE in the d i r e c t i o n of n V \ E n, and IdwI d e n o t e s the
these
with
(4),
we h a v e
the
result.
Since of
denotes
w
Ih(z) I
~(log+ihI )
on
is
bounded
¢\ E n
Vn(Z0)
on
and
¢\
En,
we c a n
define
in fact
= I
~(l°g+ih(z)l)dUn(Z) DE
n
the
LHM,
Vn,
242
< C I
~(log+ih(z)I)d~
(z)
DE
n
n < C f =
(CIU(Z) + C2)dv
(z)
DE
n
n < C I = D(VXE
(CIU(Z) + C 2 ) d v
)
n
(z)
n
= C ( C i U ( z 0) + C2). Since
{Vn:
is b o u n d e d
n = I, 2,...} at the p o i n t
to a h a r m o n i c function on
E
function,
~(log+lhl)
implies
say
on
that
h
we c o n c l u d e
is a b o u n d e d
analytic
previously, vn
n = i, 2, . . . . I, 2,...
of
of
Vn \ E
V
V
~(log+IfI )
Fix a p o i n t
Thus
n )
\ E
As
f, w h i c h
h
the
vanishes
is equal to
such that
exhaustion
E E V
of
V
to
g,
H~(V). but
with
the a s s u m p t i o n
= E $ V I.
made
n = i, 2, . . . .
Vn \ E
z0 C VI \ E
measures
majorizes
function.
satisfies
for
n on
which
it c o n v e r g e s
and our a s s u m p t i o n
and h e n c e b e l o n g s V ~ 0G
sequence
that
Let u n Vn, r e s p e c t i v e l y ,
and
and let
~n
at the p o i n t
z0
and
vn
and for
with
with respect
n =
to
V , respectively. By an a r g u m e n t s i m i l a r to n (4), we find a p o s i t i v e c o n s t a n t C i n d e p e n d e n t of n
that u s e d for
and
dVn =< Cd~n
such that
to
f E H~(V
be the h a r m o n i c
the r e g i o n s
h ~ 0. on
be a r e g u l a r
f
we see that
be the LHM's
h e H ~ ( ~ \ E)
any r e g i o n
{Vn: n = i, 2,...}
Since the r e s t r i c t i o n
implies
~ \ E, w h i c h c l e a r l y
So
that
function
Now let us c o n s i d e r Let
v, on
~ \ E.
increasing
theorem
s h o u l d be a c o n s t a n t
at i n f i n i t y ,
V.
is a m o n o t o n i c a l l y z0, H a r n a c k ' s
U(z0)
on
DV n
~ Un(Z0)
for all
~ I
So
~(l°g+If(z)i)d~n(Z) DV
C-I I
n.
n
~(log+If(z)I)dVn(Z) DV n
= C-ivn(Z0) for all
n.
function, longs
to
3C. cumference
This v, on
H~(V),
shows that the
{ I z - z01
F(z0;r0) ,
= r0].
we a l w a y s
When
{v n}
tends
~(log+IfI )
as was to be proved.
We d e n o t e by
the f o l l o w i n g ,
sequence
V, w h i c h m a j o r i z e s
Izol
on
to a h a r m o n i c v.
Hence
f
be-
[]
< ~
and
0 < r 0 < ~, the cir-
z 0 = 0, we w r i t e
deal w i t h the e x t e n d e d
simply
complex
F(r0).
plane
~.
In So,
243
w h e n we write, in the Lemma. in
Let
{Iz[
for e x a m p l e ,
{Izl
0 < a < b < ~
~ b}
the h a r m o n i c
such that measure
and let
ds
denotes
the a r c - l e n g t h
positive,
Proof.
D I : {a < Izl < b},
Harnaek's
inequality
o n l y on the r a t i o A ' U ( z 2) U
on
D I.
i
on
there
For any arc harmonic e
e
and to
DI.
0
(5)
denotes
F(a)
U2(e;w) of
A(t),
t > 0,
c : (ab) I/2
= A'(a/b), such that
by
By
depending U(z I)
harmonic Uj(e;z), values
function 0 ~ j ~ 2,
are equal
~ U2(e;z)
inequality
the arc l e n g t h
max{U2(e;w):
and
A'
way,
we d e n o t e
~ U0(e;z)
By use of H a r n a c k ' s
lel
> a}
a constant
by
Then
t.
on
lel 4~a ~ A ' U l ( e ; w ) ' where
D 2 = {Izl
in
Denote
DO.
and
D. whose boundary ] elsewhere. Clearly,
Ul(e;z) on
F(a)
set i n c l u d e d
,
and any n o n n e g a t i v e
on
function
on
function
in a n o n d e c r e a s i n g
Zl, z 2 • F(c)
to
~ A ( a / b ) . - - ~2~a
element
exists
closed
is a region.
with respect
nondecreasing
a/b
for any
the b o u n d e d to
the p o i n t at i n f i n i t y
be a b o u n d e d
> a} \ F ~
z • F(a)}
is a finite, Let
F
D O = {Izl
at the p o i n t
m a x {d ~ (z): where
> a}, we i n c l u d e
set.
we see for
lwl = c
lel i + (a/b) I/2 ~ 2~a i - (a/b) I/2 e.
'
So
lwl = c} ~ A . m i n { U l ( e ; w ) :
lwl = c},
where A = A(a/b)
From
(5) f o l l o w s
el,
B(e I) ~ A ~ ( e 2)
if
and the f u n c t i o n problem
e2
max{
on
F(a)
lel]
w i t h the
= le21 , b e c a u s e
U0(ej;z) ,
F(e)
(z):
lwl : e} ~ A - m i n { U 0 ( e 2 ; w ) :
on
for the r e g i o n
U0(ej;z)
"
at once that
max{U0(el;w): for any arcs
= 2A'(a/b) .I + (a/b)i/2 i - (a/b) I/2
and to
z e F(a)}
same length. ~(ej)
j = i, 2, is the
{Izl
> c} \ F 0
(z):
This
shows
= U0(ej;~),
solution
w i t h the b o u n d a r y
elsewhere.
~ A.min{
lwl : c}
j = I, 2,
of the D i r i c h l e t d a t a e q u a l to
Hence z • F(a)}
that
~ A-#--(-~
.
244
3D. class
The next
l e m m a is the key to our c o n s t r u c t i o n
of null
Lemma.
Let
number
0 < a2/b
of b o u n d e d
< a0 < a < b < ~
closed
1 < i < k, is a r e g i o n i, 2,...} ~(n)/n
subsets
including
be an i n c r e a s i n g
: o(i),
n ÷ ~, and
FI,... , F k
{Izl
> b}
such that
all
F.
with
j ~ i.
sequence ~(n)
and let
of
of p o s i t i v e
> n I/2
a0exp(2~ji/n) We set polar
and
Kn, j = { I z - Wn,jl
numbers
for all large
K n : u.n]_l Kn,j.
Suppose
set and that we c o n s i d e r
in the d i s k
{Izl
Let
Pn
~
touthe
and
regions Then,
such that
for
that e a c h
only large
F.,] n's
> a 0} \ F
for any
and
s > 0, there
exists
B = B(a/b)
(6)
< E,
is a c o n s t a n t
We first
and t h e n c h o o s e
(l+s')-ip(F(a0))
where
~'
(resp.
s' > 0
< ~'(F(a'))
~") d e n o t e s
{Izl
w. ~K n
Un(Z)
with
N = N(s)
o n l y on the r a t i o
F : > 0
a/b
in a
support
the G r e e n
on
potential
Un(Z)
b = i.
Let
c >
< 2-1~(F(a0))-l~ so c l o s e
> a'} \ F
to
a0
as to have
< (l+s')~(F(a0)) ,
measure (resp.
at the p o i n t {Izl
be the G r e e n
We d e n o t e
> a"} \ F).
function
for the
by ~ the p o s i t i v e m e a s u r e n and w i t h u n i f o r m d e n s i t y on ~Kn, and
of
= I
that
with
< ~"(F(a"))
= l o g ( l l - z ~ I / I z - w I)
of m a s s by
is i n c l u d e d
i ~ j ~ n,
the h a r m o n i c
o p e n unit d i s k w i t h pole at with
s'}
< a 0 < a" < a
to the r e g i o n
g(z,w)
i
Kn
1 ~ j ~ k,
loss of g e n e r a l i t y
choose
0 < a'
(7)
Let
i =< j =< k, is not a so that
< g,
depending
m a x { ( l + s ' ) - (i+~') -3,
with respect
for
:
fashion.
We may a s s u m e w i t h o u t
be given.
w
n,j j = i,..., n.
an i n t e r g e r
~n(~Kn, j) ~ ( B n ) - l ~ ( F ( a 0 ) ) ,
Proof.
Let
n > N
I ~ ( F j ) - ~n(Fj)l
nondecreasing
n =
such that n.
(K n U F) , r e s p e c t i v e l y
[\
'j~(F(ao) ) - p n ( ~ K n ) l
where
~ \ Fi,
{~(n):
< a} and K .'s, i ~ j ~ n, are m u t u a l l y d i s j o i n t . n,] be the h a r m o n i c m e a s u r e s at the p o i n t ~ with respect
{Izl
Uj~ I Fj.
~ a0e-~(n)}
be a f i n i t e
each
Let
=
0
sets of
N~.
Vn'
i.e.
g(z,w)d~
~K n
(w) n
245
on the disk
{Izl
~ i}.
harmonic
{Izl
< i} \ Kn, and v a n i s h e s
tation
on
shows
Clearly,
Un(Z)
is e o n t i n u o u s on
F(1).
on
{Izl
~ 1},
An e x p l i c i t
compu-
that i
n
~ g(z ) j:l 'Wn'j
if
z ~ K
if
z E K
n'
Un(Z): { i
where of
Rn,i(z)
{£(n)},
(ii)
F(a')
there
seen that
K
n Let
for
i
|2~ J"
--2~
0
exists
n > N'. = (resp.
u'
(i)
U (z) n
n,
i'
By use of the p r o p e r t y converges
uniformly
on
to the value ,a0eit)d t g(a'
log
a0
N' = N'(e')
i__ a0 <
u )
i :
an i n t e g e r
(l+s')-ll°g on
+ !R .(z) n n,l
= log(ll - Z W n , i l / a 0) ~ log(2/a0).
it is easily
the circle
and
[ g(z .) + ~(n) j~i 'Wn'3 n
,
> 0
such that
i U n (z) < (l+E')log a--~
be the
solution
of the D i r i c h l e t
problem
for
n
the region equal
to
{Izl i
on
> a'} \ F F(a')
(resp.
(resp.
[ \ (K n m F ) )
aK ) and to
with the b o u n d a r y 0
elsewhere.
data
Take
N" =
n
N"(c')
so large
that,
for
n > N"
K '
Izl
a"}
<
possible
and
Un(Z)
in view of
lies
Suppose
{a' <
n
~ (i + s ' ) - l l o g ( i / a 0 )
(i).
in the annulus
on
n ~ N(s)
F(a'),
= max{N',
the latter N"}.
Then,
being by
use of (ii), Un(Z)
= i > (i + e ' ) - l ( l o g =
on
~K
Un(Z) {Izl
(z) n
and t h e r e f o r e e v e r y w h e r e on {[z I ~ i}. n ~ (I + E') -2 = (i + e')-2u'(z). Since Un(Z)
> a'} \ F
see that together (8)
i )-Iu a 0
and has the same b o u n d a r y
Un(Z) with
~n($Kn)
~ (i + E')-2u'(z)
(7), means = Un(~)
On the o t h e r hand, (9) Combining equality
everywhere
in p a r t i c u l a r
since
K
n
lies
inequalities
in the lemma.
(8),
as
on
F(a')
we have
is s u p e r h a r m o n i e u'(z)
{Izl
on
on
~F, we
> a'} \ F.
This,
that
~ (i + s ' ) - 2 ~ ' ( F ( a ' ) )
~ n ( a K n) ~ ~"(F(a")) the
values
So on
inside
~ (i + s ' ) - 3 ~ ( F ( a 0 ) ) . F(a"),
we have
~ (i + e ' ) ~ ( F ( a 0 ) ) .
(9) and using
To show the second,
(6), we get the
we take any
j
first
with
i
in-
246
Then,
j < k.
by
(6),
(7),
k __< [ i=l
I ~ ( F j ) - ~n(Fj)I
<
k [
=
i=l
(8) and
(9)
lu(Fi) - Un(Fi) I
(~(F i) - ~"(F.))
k [
+
i
(~n(Fi) - ~"(Fi))
i=l
= U " ( F ( a " ) ) - U ( F ( a 0 ) ) + ~ " ( F ( a " ) ) - Un($Kn) g ' B ( F ( a 0 ) ) + ((l+s') - (l+s')
-3 < s.
)O(r(a0))
N o w we h a v e o n l y to p r o v e the last b u n c h of i n e q u a l i t i e s . previous F(a)
observation
shows,
U (z) n
converges
uniformly
As our
on the c i r c l e
to $2~ g(a,a0elt)dt 2~
in v i e w of the fact N"
such that,
a 0 < a.
for
So t h e r e
We take any
such
n, set
Ulj , u2j) ,
1 ~ j ~ n, to be the
the r e g i o n
[ \ (K n U F )
data equal
to
1
on
m i = min{uij(z): the c o n s t a n t lemma.
of
A'
~Kn, j j
and t h e r e f o r e
monic
in
{Izl
solution
and to and
0
elsewhere•
~K n
on
Because Izl = e},
[ \ K n , we see that
On the o t h e r hand,
and is e q u a l to n (ii), we h a v e > ((i+s')log =
and thus e v e r y w h e r e
n
on
F(a),
because
)-iu
on
I
u2j(z) a
2
of s y m m e t r y , i = i, 2,
1
[Izl
n
(z)
on
i
~K . n
> ~(log =
< i} \ K n •
1 =< nM 1 =< A ' n m 1
~j:in u2j
i ]-I . U
>-- ~ ( l ° g ~ 0
< a ^u < a .
i__) -i u ( z ) a0
n
In v i e w of
I log a
> i
n (z) --> 4 log a 0 = g It
follows
that
is har-
So, by l e t t i n g
thus get
j=l
u. (resp. ] p r o b l e m for
M. < A ' ( a ) m . for i = i, 2, w h e r e i = i a p p e a r e d in the p r o o f of the p r e c e d i n g
n
on
N1
< I} \ K n) w i t h the b o u n d a r y
M i = max{uij(z):
M 1 =< A'/n.
~ u2j(z) j:l
and define
of the D i r i e h l e t
{Izl
< i} \ K
and using
integer
and we h a v e
has a l r e a d y
=< A'
c = a I/2
I X Kn,
n Ulj (z) ~ 1 ~j:l
Since
s' < 1
(resp.
Izl = c}
are i n d e p e n d e n t
a positive
1 ~ 2-11og-~-
Un(Z) F(a).
exists
n $ NI, we h a v e
(i0) on
: log l---a'
0
(I0)
we
247
n ~
A,nm 2 >nM 2 >
> i__-
u2j(z)
] ± on
F(c).
Ulj(Z) , shows
So we have
A ' m 2 ~ 1/16n ~ MI/16A'.
i ~ j ~ n, on the annulus
F(c)
{Izl
u2j(z)
S uj(z)
S
inequality
that u.(z) i
on
Since
{a < Izl < i), the above
for any
i
and
j.
< 16A'2u.(z) = ] The
same i n e q u a l i t i e s
clearly
hold on
> c} \ F, so that U n ( 3 K n , i ) : ui(~)
for any
i, j : i,...,
n.
S 16A'2uj (~) = 1 6 A ' 2 U n ( $ K n , j )
This
implies
that
Pn(~Kn,j ) ~ (16A'2n)-Ipn(~)K n) for
j = i,...,
n.
Since
for all s u f f i c i e n t l y
D(F(ao))
large
n.
~ 0, we have
Hence
pn(~K n) ~ U ( F ( a 0 ) ) / 2
we have
Pn(~Kn,j ) ~ ( B n ) - l ~ ( F ( a 0 ) ) for
j = i,...,
large.
4.
This
finishes
Existence 4A.
n, w i t h
of Null
B = B(a)
the proof.
: 16A '2, p r o v i d e d
n
is s u f f i c i e n t l y
[]
Sets
We are now in a p o s i t i o n
to prove
the m a i n
result
of this
seetion. Theorem.
Let
~
be a convex
0 < a < b < ~
and let
closed
of
subsets
taining and
all other
0 < 6 < i
Fj,
function
{Izl
> b}
Fj,
j ~ i.
there
exists
which
satisfies
i £ j £ k, be a finite
(i) and
number
(3).
Let
of b o u n d e d
such that Then
each ~ \ F. is a r e g i o n coni for any p o s i t i v e numbers e > 0
a non-polar
set
E E N$
such that
E
at the point
~
{~a ~ LzL ! a}, (il)
l ~ ( r j ) - ~E(Fj)I
< E,
i ~ j ~ k,
and
l~(r(a))-
(12) where respect
p
(resp.
~E ) d e n o t e s
to the r e g i o n
#E(E)[ < e,
the h a r m o n i c
{]z I > a} \ F
(resp.
measure
~\ (EUF))
with
F =
with
248
uj~1 ZjProof.
By a p p l y i n g
vex
function
t2
for all
find
increasing
for
functions
h(t)
The
there
t; and
number
and
determined
~(t)
exists
So the
Lemma
In o r d e r
3D.
we m a y
that
during
only
to add
that
(b/a) I/4
and
closed
disks
a finite
for all
t(s)
the
which
as to h a v e
0-th
Suppose
disks
D~,
We t h e n
Kn+ I r' n (13)
If
t
F
the
=< a} .
Each
of
we h a v e K n'
and
Up)
conditions
set,
p
{jz I £ a},
says
finished in such
This
set
we d e f i n e
that
the
We
the
n-th
a way
that
of c e n t e r
3D.
w
and
of
same
{JzJ
(resp. point
t
~0 = ~
n ~ 0.
of c o m m o n
condition
Kn+ I
is dis-
Namely,
of c l o s e d
radius
r'
Da
= {Jz-w
of t h e s e
disks.
Pn+l(Fj)-
p~(Fj)
K'n+l a
as
disjoint
fulfilled
follows.
J =< r n + l } , The v a l u e
so
n
are m u t u a l l y
is c l e a r l y
and
and
and
=< p4r~}
eonsists
of
radius
~
I £ p4r~}
p =
(K' U F ) ) . n K 0 to be e m p t y
step w i t h K'n
also
set
K n') c o n s i s t s
of the
so that disk
then
as a n e w m e m b e r
(resp.
[\
in
property,
We m a y a s s u m e
disks
(resp.
n induction,
=
{Jz-w
define
consists
(K
for
n = 0, i,...,
Kn
closed
= o(I), ~ > 0
£ ~(t)/2
in Lemma
K'n'
t ~ t I.
~(t)/t
is a p o l a r
appearing Kn,
inverse are
for
desired
F
strictly
for any
0 < ~ < (i - ~ ( F ) ) / ~ ( F ) .
one m e m b e r
1 < ~ < N(n),
F.
[\
of our
of o n l y
that
disks
from
rn+ I < r'n
the
F_I , to
disjoint,
region
step
=
joint 4 p •
satisfies with
no harm.
families
constructed
the
h(t/e)
say
constant
{Izl
that
are the
(i')
(iii')
cause
the
to the
to c o n s i s t
that
t; and
E
we c o n s t r u c t in
following:
set.
set, will
in
£
We t h e n
A(t) Then
A(t)
respectively,
functions
n ~ t I]
a set
a non-polar
=
we h a v e
{~(n):
is a n o n - p o l a r
a • The d e f i n i t i o n r0 joint f r o m the set F. '
the
large
(~ t I) such
of m u t u a l l y
t ÷ ~.
and
A(t),
get a con-
(ii)
r') in {JzJ < a} w h o s e u n i o n is d e n o t e d by K n = ' n Pn (resp. ~) we m e a n the h a r m o n i c m e a s u r e at the
By K n'). with respect As
imply
to c o n s t r u c t
included
number
(resp.
K~
now
B = B(a/b),
By i n d u c t i o n
rn
- (iii)
is so small
~(t)
and
we
t ÷ ~;
= o(i),
both
increasing
~ t I/2
our c o n s t r u c t i o n , a
that
~(t)
strictly
F
t ÷ ~(t/2),
= o(i),
t I = ma×{~(t0),A(t0)}. of
sequence
assume
we h a v e
Let
function t/A(t)
A(t)/~(t/2)
such
~(t)
a number
t ~ t(e).
(i)
(iii)
tO
as
(i)
(ii')
3A to the that
t ~ tO.
properties
t ÷ ~;
such
large
a positive
uniquely
Lemma
A(t)
by
Let
and
also
dis-
K~,
for
b/a
max{i/p,6}r~
i =< a =< N(n). rn+ I
is f i x e d
as to h a v e ~ E ~ ( F j ) / 2 n+l,
i ~ j ~ k,
The
<
family
so c l o s e
=
to
249
and ~ n + l ( ~ D ~ ) ~ ~n'($D~)/2,
(14)
In o r d e r to d e f i n e
K~+I, we take an i n t e g e r
w h i c h w i l l be f i x e d later. w
,j = w
N(n+l)
i =< e =< N(n) " N'(n+l)
~ max{n+l,tl},
We set
+ rn+lexp[2~ji/N'(n+l)] ,
= N(n)N'(n+l),
i ~ j ~ N'(n+l),
r'n+l = r n + l e x p [ - ~ ( N ( n + l ) ) ]
and n'~,j
: {Iz-w
~,j I =< r n+l },
i < j < N'(n+l)
The d i s k s
{D' .: i < ~ < N(n), i £ j < N ' ( n + l ) } t h e n f o r m the f a m i l y ~,3 = = K' We fix N'(n+l) so large as to h a v e the f o l l o w i n g : n+l" 4 , (a) the disks {Jz-w ,j J _< p rn+ I} are m u t u a l l y d i s j o i n t and
also d i s j o i n t (b)
from
F;
l~n+l(Fj)-~n+l(Fj)j
< e ~ ( F j ) / 2 n+2
for
(c)
and
This
' (~D' ) > (BN'(n+I)) -I (~D) ~n+l e,j = ~n+l e ~ = i,..., N(n); (d)
r'n+l =< 3 - 1 m i n { r n' - r n + l ' r n + l
(e)
h((n+l)(2B)n+iN(n+l))
is t r i v i a l
Lemma
3D and
for
(a) and
j : i ..
for
j = i
k;
'''''
N'(n+l)
Brn } ;
< ~(N(n+l))/2.
(d).
Statements
(e) f r o m the p r o p e r t y
(iii').
(b) and Hence,
(c) f o l l o w
by i n d u c t i o n ,
from the
families
K and K', n > 0, are c o n s t r u c t e d . n n = C o m b i n i n g (13) and (b), we get for n > i
(15)
I~n(F j) - ~n+l(Fj)l J~n(Fj ) - ~ ( F j ) < s~(F.)/2 =
n+l + s~(F.)/2
]
: e ~ ( F . ) / 2 n, 3 It f o l l o w s
from
(14) and
K' such that ~n(~D~) n-1 see that for D' E K'
I + I~(Fj)
- ~n+l(Fj)J
n+l
3
i £ j £ k.
t h e r e is a D~ E D' @ K' n R e p e a t i n g this, we > ( 2 B N ' ( n ) ) - l ~ n I(~D~) = "
(c) that
for any
n
(16)
~(~D~)
~ (2B)-n(N'(n)N'(n-I).''N(1))-IB~(F(a)) : (2B)-IN(n)-I~(F(a)).
We set
250
E = and d e n o t e
by
DE
to the r e g i o n
¢\
the
Izl
harmonic
[Cl(
U Ks)] s:n
measure
at the
point
~
with
respect
(EUF).
Our c o n s t r u c t i o n K I' =C {6a <
A n=l
< a}
and
the
and
property
Kn+ I =C K'n
(d)
for
show
that
n : i,
2,...
K' C Int(K') n+l = n . It f o l l o w s
C =
that
E =C Cl[ for we
n : i, see
2,...
for
and
U s:n+2
Ks]
C= K'n+l =C Int(K')n
afortiori
E ~
{6a
<
Izl
By use
< a}.
of
(15)
n > i n
Bn(F)
: ~(F)
+
(~s(F) - Us_l(F))
s:l : B(r)
n [ s=l
+
k (Bs(F j) - ~ s _ l ( F j ) ) j=l k
<__sB(r) :
and
+
e~(F.)/2
[ [ s=l j=l
s
3
(i + e ) B ( F )
therefore Dn (~Kn)
The
last m e m b e r
the
Let
u
: ~(F(a))-
E~(F).
data
[\
equal
positive,
(resp.
n
for the r e g i o n
boundary
=> i - ~(F) - s ~ ( F )
is s t r i c t l y
(i - ~ ( F ) ) / ~ ( F ) . problem
= i - ~n(F)
v ) be the n
(F U C I ( U
to
i
because
on
of our solution
~ K )) s=n s
(resp.
~[CI(U
K )] s:n
0
on
~F.
Clearly,
the
sequence
{u
assumption of the [\
Dirichlet
(FUK)) n
(resp.
with
~K ) and
S
: n = i,
~ <
to
n
2,...}
is m o n o t o n i c a l l y
n
decreasing
and
bounded
to a n o n n e g a t i v e we have
below,
harmonic
0 < u(z)
< 1
so that
it c o n v e r g e s ,
function,
u(z),
u(z)
on
and
= 0
on
~\
~F.
by H a r n a e k ' s (E U F ) .
We k n o w
Obviously,
that
~
Vn(Z)
on the
0.
Hence
the
Diriehlet
0
on
set.
~F.
domain
u(~)
u
(z)
>
n
of
> 0.
problem
Thus
Moreover
theorem,
with
BE(E)
we h a v e
un
The
and
that
function
u
the b o u n d a r y
= u(~)
> 0
and
v n (~)
= ~ n ( Z K n) => 1 - (I+s)B(F)
is seen data
to be the
equal
consequently
to
1 E
solution on
E
is not
>
of and
to
a polar
251
(17)
~E(E)
= u(~)
: lim Un(~)
~ lim sup Vn(~)
n~
n~
= lim sup ~n(~Kn) On the other hand, and therefore with
(17),
since
~E(F)
proves
shows
is included
$ B(F).
(12).
~E(Fj) -B(Fj) which
E
Thus
~(F(a))
~ ~E(F) -~(F)
show finally
that
E E N@.
nonzero
H ~ ( [ \ E)
element
in
To show that
is included
n $ 0
f
and
v
of
K' n
D' = {Iz- w' I £ r'}
(a) says that the annulus
to the annulus
Let
~w
{r' < Iz - w' I < p2r'}
is bounded
A'/(4~r')
on
where
3C.
Iz -w' I < p2r'},
f
we have for any
the convex
function
and by
and analytic w
f
be a
}(log+Ifl)
we first note that Let us fix ' K n.
in
measure w
inequality
is the constant
is bounded
log+If(w)I
equality,
F(w';r')
A' = A'(p -2)
Since
of
n = 0, i, . . . .
at a point
then Harnack's
F(w';p2r'),
(3), we
Let
{r' ~ Iz- w' I £ p4r'}
r(w';pr'),
by
majorant
be the harmonic
on the circle
Applying
together
satisfies
be one of the members
and
K'n \ D'.
%
function,
for
the property
of Lemma
~ ~(Fj)
~ su(F),
[ \ E E 0}.
a harmonic
meet
F
Since
3B, that
is a constant
in the interior
and let E,
ZE(Fj)
~ BE(E) , which,
: D(F(a)) - ~ E ( E )
in view of Lemma
[ \ E.
{Izl ~ a},
(ii).
We will
E
in
We also have
have only to prove, on
~ ~(F(a)) - e~(F).
does not
with respect
in it. implies
A'/(4~p2r ') appearing
Then
If
w
that
is
d~w/dS
on in the proof
on the annulus
{r' <
in this annulus
£ [ l°g+If(~)Id~w (~)" ~
to both sides and using Jensen's
in-
we get ~(l°g+[f(w) l) ~ %(I l°g+If(~)Id<w(~))
I ~(l°g+If(%)I)d~w(~))
=f
F(w';r')
+f
F(w';p2r ')
= I I + 12 . We now assume sures at
~
that
w E I'(w';pr').
with respect
Let
to the regions
~, ~'
denote
G' = {Iz - w'
the harmonic > r'} \ E
mea-
and
252
G" : {Iz - w' I > p2r'} \ E, respectively.
Since
E C K' =
~D'
F(w';r')
:
we see that q'(F(w';p2r'))
By use of (16) we also have Lemma 3C to the annuli p4r'}, we see that circle on
and
n
F(w';r')
F(w';p2r'),
where
~(~D')
~ ~(~D').
~ (2B)-nN(n)-l~(F(a)). By applying and {p 2r ' < [z- w' I <
{r' < Iz- w' I < p2r'}
ds/d~ and
~ n(F(w';r'))
is bounded by
ds/d~'
2~Ar'/~(F(w';r'))
is bounded by
A = A(p -2)
on the
2~Ap2r'/n'(F(w';p2r'))
is the constant
given in Lemma
3C.
So we have d~w(~) ds(~) ~(log+If({)l) d s - - 7 ~ ~
II :
dq(6)
F(w';r') A' 2~Ar' 4w-~r ~(F(w';r'))
AA'
I
S~G'
< 2q(F(w';r'))
#(l°g+If(~)l)dq(~) F(w';r')
%(log+If(6)l)dn(~)
C(2B)nN(n)/2, where
C = AA'v(=)/z(F(a)).
using
N',
G"
Similarly,
and the corresponding ~(log+If(w)l)
for
w @ F(w';pr'). tI
can apply the inverse
h(t)
S
large
v(~)
# 0, the right-
n ~ no, say.
and get the following
So we
inequality:
~ exp[h(C(2B)nN(n))].
this along the circle
rnexp[-~(N(n))] , we have,
by
It follows that
~ C(2B)nN(n)
for all sufficiently function If(w)I
(18)
12 ~ C(2B)nN(n)/2
As we may always assume that
hand side exceeds
We integrate
we have
estimates.
F(w';pr').
Since
by use of the property
r' = r n
(e),
if(w) ids(w ) ~ 2~@rneXp[-~(N(n)) + h(C(2B)nN(n)) ]
F(w';pr') 2~Prnexp[-~(N(n))/2],
if
n ~ max{no,
corresponding included
C}.
We now look at the union
D' E K'. n in the inside of Fn,
morphic at
to all
Then, n ~ i.
, it has an expansion
Fn
of paths
F(w';pr')
as we have seen, the set
f(z)
Since the function : ~ ~ c.z -] j:0 ]
f
E
is
is holo-
Since we have
253
#(t + log 2 ) / # ( t ) belongs vanish of
to
E);
identically,
f.
(18)
: 0(i),
H#([\
If
and
n
t ÷ ~,
so w e m a y
let
Cp,
it is e a s i l y
seen that
assume
= 0.
f(~)
p ~ i, be the
is s u f f i c i e n t l y
large,
f(z) - c 0
If
first
f
does
nonzero
t h e n we c a n u s e
also
not
coefficient
the
inequality
get
if(w) llwlP_lds(w ) n PrnbP-iN(n)exp[-N(n)i/2/2].
This
is a c o n t r a d i c t i o n ,
Hence
f
must
4B. N~
In the p r e c e d i n g
in a n a n n u l u s
struction
can
the t h e o r e m dition,
for
with
Theorem.
theorem
be p e r f o r m e d
by H e i n s Every
6 = I
closed
subset
to the
dition
et/~(t)
= 0(i),
Proof.
Let
be a n y c l o s e d
F(1),
implies
F and
that
V
N~
a region
throughout
f
H~(V).
For a general is p o s s i b l e that
there
§3.
CLASSIFICATION
5.
This form.
of a c i r c l e
having
zero
will
function
~
In
linear
con-
was
measure
satisfies
the
con-
set of
in
[
V.
zero
linear
including As H e i n s
Then
F.
measure
shows,
it is e a s y
on a circle,
The hypothesis every
to v e r i f y
on
f ~ HI(v\ that
F)
such an
[]
convex
or not.
center.
following
convex
con-
a stronger
is l i n e a r .
if t h e
E
same
in the
H ~ ( V \ F) ~ H I ( v \ F).
to
set o f c l a s s the
arbitrary satisfies
n + ~. []
t + ~.
is h o l o m o r p h i c belongs
}
i.e.
a null
Trivially,
with
When
zero as
stated
is h e r e
belongs
say
class
origin.
~ < i.
to
to be p r o v e d .
we c o n s t r u c t e d
at t h e
is p o s s i b l e ,
and
tends
as w a s
for an a n n u l u s
that
[31]
last m e m b e r
function,
center
we a s s u m e d
the value
observed
the
be a c o n s t a n t
function
But we c a n
be n o p r a c t i c a l
OF P L A N E
~
we do n o t
take
~
know whether
arbitrarily
close
to
~ = i i
so
difference.
REGIONS
Lemmas 5A.
closed and
Lemma.
subset v
the r e g i o n s
of
Let
0 < a < b < c < ~
{Izl
~ c}
be the h a r m o n i c {Izl
> b} \ F
such
that
measures and
{Iz[
and {Izl
at t h e
F
be a b o u n d e d
> b} \ F
let
is a r e g i o n .
point
~
with
respect
> a} k F, r e s p e c t i v e l y .
Then
Let to
254
log(c/b) log(c/a) Proof. {Izl
Let
u
> a] \ F
elsewhere.
be the s o l u t i o n
F
lies
{Izl
in
u
on
: u(-)
~ c},
Fj,
Lemma.
sets
Let
such that
Suppose
with
~
z • F},
with respect
let
solution
a
Pa(Fj) > 0
on
D a.
strictly
quence
{U(an;Z)}
~\
i
v, so that
e a s y to see that
v
is the
w i t h the b o u n d a r y
d a t a equal
for
{an:
functions.
say
i
and,
measure
> a} \ F.
for e a c h
at the
Then there
is,
such that
is h e l d fixed. D a = {Iz - z01
n = l, 2,...}
Let
u(a;z)
> a} \ F
above, v(z),
sequence
it c o n v e r g e s
uniformly
the p o i n t on
~F.q
z0
[ \ F. and to
se-
is mo-
by H a r n a c k ' s
on any c o m p a c t
problem 0
set
is a r e m o v a b l e In fact,
of the D i r i e h l e t on
of p o s i t i v e
the c o r r e s p o n d i n g
Since this
is h a r m o n i c
solution to
[\ F
3F. a n d to 0 e l s e w h e r e , so ] is a s s u m e d to be n o n - p o l a r , we h a v e
is b o u n d e d , v
F.
point.
on
and is b o u n d e d
v
all
be the h a r m o n i c
property
to zero and c o n s i d e r
function,
Since
~
including
0 £ j £ k.
Take any s e q u e n c e
increasing
of
{Iz - z01
< E,
Pj
of h a r m o n i c
( F U {z0}).
singularity
Since
decreasing
to a h a r m o n i c
Let
of b o u n d e d
be any f i n i t e
be the h a r m o n i c
problem
to
number
is a r e g i o n
0 ~ j £ k, w h i c h
data equal
= u(a;~).
numbers
notonically
j,
i
w i t h the a b o v e
of the D i r i e h l e t
w i t h the b o u n d a r y
in
we have
~ log(]zl/e)/log(a/c)
to the r e g i o n
to the r e g i o n
s > 0, a n u m b e r
Take any i n d e x
theorem
elsewhere,
#(F(b)).
set.
Pa
p ( F j ) - #a(Fj)
u(a;z)
u(z)
F = Uj~ 0 Fj
F.± is a n o n - p o l a r at the p o i n t ~ with respect
0 < a < i n f { I z - z01:
that
0
> b} \ F
for this r e g i o n w i t h 0
k, be a f i n i t e
for each
z 0 • [\ F
that each
measure
be the
and to
{Izl
[]
j = i,...,
[ \ F.
j ~ i, and let
Proof.
for the r e g i o n
F(a)
u(z)dp(z).
log(c/b) ~ log(c/a)
5B.
for any
on
problem and to
we s e e t h a t
inequality.
point
problem
i
to the r e g i o n
F(b)
shows the d e s i r e d
closed
to
a < Izl < c, f r o m w h i c h we get
£(b) u ( z ) d p ( z )
with
u
: [ Jr(b)
f
This
of
of the D i r i c h l e t
d a t a e q u a l to
v(r(a))
Since
data e q u a l
Since the r e s t r i c t i o n
is e q u a l to the s o l u t i o n
~ v(r(a)).
of the D i r i c h l e t
w i t h the b o u n d a r y
the b o u n d a r y
for any
~(F(b))
it is for
elsewhere.
~\ F
255
Thus
v(~)
since
= ~(F.). Since U(an;~) tend increasingly 3 =< u(a;~) for a n y 0 < a < an, we have
for all
sufficiently
chosen,
the l e m m a
5C. {bn:
to
U(an;~)
Lemma.
Let
n = 0, i,...}
0 < d < i.
small
a > 0.
is proved.
~
j
and < E
was a r b i t r a r i l y
[]
be a c o n v e x
a sequence
Then t h e r e
As the i n d e x
v(~)
~(Fj) - ~a(Fj)
function
of p o s i t i v e
exist a sequence
satisfying
numbers,
(i) in IA,
0 < p < ~ < i, and
{a : n = 0, i,...}
of p o s i t i v e
n
numbers
and a s e q u e n c e
an+ 1/a n ~ p,
{E n : n = 0, i,...}
a n =< bn,
N~
En =C {6an =< Izl =< a n }
(19)
such that
for
na n < i,
n : 0, i~...,
and
d £ ~ ( - l o g ( n a n ) ) m ( E n) £ i
for
n = I, 2,...,
where
m
is the h a r m o n i c
with respect
to the r e g i o n
Proof.
{dn: n = 0, I,...},
Let
sequence measure {Jz[ an
in
with
limit
d.
at the p o i n t
i/¢(-log(na
na
n
with
E = Un= 0 E n U {0}.
by
with respect
Pn
(resp.
and
~(-log(na
n
decreasing
mn ) the h a r m o n i c
to the r e g i o n
In the f o l l o w i n g
< i
at the p o i n t
0 < d n < i, be a s t r i c t l y
We d e n o t e
~
> an+ 1 } \ (Uk~ 0 Ek)). so small that
~\ E
measure
~\
(Uk~ 0 E k)
construction )) > 0.
(resp.
we shall t a k e
We w r i t e
~
n
=
)). n
In o r d e r a0,
to c o n s t r u c t
satisfying
polar This
E 0 e N~
which
is i n c l u d e d
is p o s s i b l e
by L e m m a
chosen non-polar
E k e N}
following
E
by i n d u c t i o n ,
and
in the a n n u l u s
3A and T h e o r e m in
(C n)
0 < ak < min{bk,i/k} for
4A.
{6a 0 ~
Suppose
{6a k ~
JzJ ~ ak} ,
and
~(-log(nan))
choose
any
a n d also a n o n jzj ~ a0}.
that we h a v e
0 ~ k ~ n, w i t h the
d n ~ k ~ ~ n ( E k ) ~ ek'
T h e n we c h o o s e (21)
an+ I
(22)
so small
O ~ k £ n;
that
d n + l ~ k ~ ~ n ( E k ) ~ ~k' Vn(F(an+l)) is no p r o b l e m a b o u t
and the fact
for
I ~ k ~ n.
0 < an+ I < m i n { b n + l , ( n + l ) - l ] ,
(23)
> 0
0 ~ k ~ n - i; and
(20)
an+ 1 ÷ 0
we first
~ ( - l o g a 3) > 0,
property:
ak+I/a k ~ p
There
our set
0 < a 0 < min{b0,1}
t/~(t)
i ~ k ~ n;
> i/¢(-l°g(n+l)an+l))
= ~n+l"
(21).
is c l e a r f r o m L e m m a
= o(i),
no f a s t e r t h a n
0 < a n + l / a n £ p;
Statement
t ÷ ~, for
(-logan+l)-I
(23)
~ n ( F ( a n + l )) while
decreases
as
i/~(-log((n+l)an+l))
5A
256
decreases
much
Lemma
5B,
Fj
an+l,
and
then
in
{6an+ I ~
faster
than
= E.]
for
use
(20).
this.
For
j = 0,..., By use
IzI ~ an+ 1 }
~K
denotes
a way
to
[\
(ukn 0 E k u K ) .
of
K
such
Then
Vn(Ek)
~ ~n+l(Ek)
(Cn+ I) is s a t i s f i e d . which
4A we
to
~a
find
set,
= ~n
in
with
a set
a =
K E N~
measure
> ~n+l' at the
it is not h a r d
to
point
find
=
with
a closed
respect
subset
En+ I
that
dn+l~n+l Since
only
and
that
~ ~K (K)
the h a r m o n i c
we have
~ = ~n
of T h e o r e m
in such
Vn(F(an+l)) where
(22)
n,
satisfies
easy
to
(22)
implies
~ ~n(Ek)
for all
for each
(19),
for
By i n d u c t i o n
(C n)
see that,
~ ~ n + l ( E n + l ) ~ ~n+l"
for
can
n ~ i.
fixed
d
we
n,
construct
Set
k,
÷ d.
k = 1,...,
the
property
{En:
n = 0, i,...}
E = Un= 0 E n U {0}.
~n(Ek)
÷ m ( E k)
as
It is t h e n
n + ~.
So,
[]
n
6.
Classification 6A.
and
Let
let
For each
polar
set
that
E
The
{an:
n
included is a l s o
we call
obvious.
By
point
~
in
En
{6an
bounded,
and
with
Izl
=<
E
=< an}. and
center
to the r e g i o n s
an+i/a n ~ p
for
center
so
In the
fol-
at the
at an a r b i t r a r y the h a r m o n i c and
non-
E n U {0},
disconnected.
[\ E
numbers
disconnected, E = U n=0 ~
set w i t h
n ~ i, we d e n o t e
respect
that
set
totally
with
of p o s i t i v e
totally We
a circular
sets
mn,
Suppose
be a closed,
closed
a set
of c i r c u l a r m
be a s e q u e n c e
be c o n s t a n t s .
let
such
definition
the
n = 0, i,...}
0 < p < 6 < i
n ~ 0.
lowing
Theorem
origin.
point
is
measures
at
{Izl
> a
} \ E, ren
speetively.
We use
sification Theorem.
Then
result. Let
~
various Namely
and
~
(AI)
~(t)/~(t -s)
there
exists
E n E N~,
we h a v e
= o(i),
that
t + ~,
set
E
the
function
only
constant
Proof.
Let
0 < p < 6 < I
be fixed.
quence
{bn:
n = 0, i,...}
of p o s i t i v e
and
to o b t a i n
our
clas-
following satisfying
for any
with
H~(¢\
< i/n
in o r d e r
functions
while
b
contains
sets
the
be c o n v e x
a circular
n ~ 0, such E)
circular
fixed
center z -i
s > D.
at the o r i g i n
belongs
to
and with
H ~ ( ~ \ E),
functions. By use
of
numbers
(AI) such
we can that
find
b 0 = i,
a se-
257
0 < ~(log(6-1t)) for
n : i, 2, . . . .
of p o s i t i v e that
By L e m m a
numbers
a n =< bn
and
d ~ ~ ( - l o g ( n a n ) ) m ( E n) ~ i
same m e a n i n g
as in L e m m a
We f i r s t
En
show that
is i n c l u d e d
{an: n = 0, I,...}
{En: n : 0, i,...}
in
En C . {6a n. < Jz . I < a. n } for
n ~ i, w h e r e
m
N}
for
and
such n > 0,
d
h a v e the
5C. z -I E H ~ ( ~ \ E).
~(-log(6an)) As
t ~ i/bn,
5C we get a s e q u e n c e
and a sequence
a n + l / a n =< p,
and
£ 2-n~(log(n-lt)),
Since
a n =< b n, we h a v e
~ 2-n~(-log(nan)) ,
n ~ i.
{6a n =< Izl =< a n] , so we have
in
~(logJz-lJ)dm(z)
=
[ n=0
E
~(log[z-ll)dm(z) E n
£
[
~(-log({a ))m(Z )
n=0
n
n co
< ~ ( - l o g ( 6 a 0 ) ) m ( E 0) + =
[ ~(-log(6a n=l
£ ~ ( - l o g ( 6 a 0 ) ) m ( E 0) +
[ n:l
this shows that
z -I
belongs
to
with
n ~ i.
is i n c l u d e d measure
Since in
F(oa
(24)
).
Harnack's
d~w/dS
where
A'
= A ' ( ~ -2)
We take any [ \ E.
assume
that
f e H ~ ( ~ \ E) f
and
origin.
Namely,
£ A ' / ( 4 ~ a n) ~ A'/(4~2an
u
0 < Jz[ < ~.
)
do not v a n i s h
Since
be the h a r m o n i c at the p o i n t
W
that
F ( a 2 a n ), in the p r o o f of L e m m a
majorant
u
of
is c o n s t a n t .
expansion:
}(log+JfJ)
Since each
f(z)
En
be-
at the
= [j=0 cj z-j
is a b o u n d e d
{a n < [zJ < ~2an} , we h a v e
3C.
So we m a y
can o n l y be s i n g u l a r
f(z)
an
F(an) ,
identically. f
following
n ~ i.
~w
then i m p l i e s
appearing
f
similar
We look at any
{a n < JZJ < @p-la n } Let
on
and a h a r m o n i c
N~, we see that
Let
on
is to s h o w that
we h a v e the
t i o n on any a n n u l u s
4A.
{a n < JzJ < O2an }
inequality
is the c o n s t a n t
Our o b j e c t i v e
longs to the class
a = (~p-l)i/4.
to the a n n u l u s
d~w/dS
(25)
for
n
))
can be shown by an a r g u m e n t
in the p r o o f of T h e o r e m We set
n
2 -n < ~.
0 < p < 6 < i, the a n n u l u s
~ \ E.
with respect
on the c i r c l e
on
used
))/}(-log(na
H ~ ( [ \ E).
The l a t t e r h a l f of the t h e o r e m to the one a l r e a d y
n
analytic
func-
258
l°g+If(w)l a I l°g+If(~)la~w(~)
(26) for any
w E F(Oan) , where
Applying
~(t)
to both
}(l°g+If(w)l)
~w
sides
is the h a r m o n i c and u s i n g
< [I = F(a
+ I
)
Assume
now that
w E F(oa
).
Jensen's
F(o2a
n
measure
)
defined
inequality,
above.
we get
] ~(l°g+If(~)l)dSw(~)-
n
Using
(24), (25), (26), Lemma 3C and the -1 ~ m(E n) ~ d } ( - l o g ( n a n ) ) , and c o m p u t i n g as in the p r o o f n
fact
mn(F(an))
of T h e o r e m
4A, we see that the r i g h t - h a n d
is m a j o r i z e d
by
C%(-logan)
, where
side of the above
inequality
C : A'(o-2)A(o-l)u(~)/d.
Thus we
have (27)
%(log+If(w) I ) / ~ ( - l o g a n ) ~ C
for any
w E F(oan).
is p o s i t i v e ~ ( t 2 ) / % ( t I) N => i
Take
a positive
and n o n d e c r e a s i n g for any
satisfying
tI > tO
for
and any
-loga N > t O .
Then
If(w)l for any
w E F(aa n)
and any
number
t _> t O .
< an
n ~ N.
tO
t 2 > 0. (27)
so large
Then we have
that
~(t)/t
t2/t I < I +
We c h o o s e
an i n t e g e r
implies
-C-I Letting
and w r i t i n g
n ~ N
r =
Oan, we have i ICkl Letting
=
f(z)zk-ldz
in
z -I
small
ek : 0
Let
p ~ i, then we w o u l d
ficiently
z, say
have
¢(log+If(z)l)dm(z)
This
contradiction
constant 6B. expressed
[ n:N'
In terms
k > C + i
k-C-i an
and t h e r e f o r e
be its h i g h e s t n o n z e r o P If(z)l => 2 -1 ICpl Izl -P ~ i
~
with
[ n=N'
N' ~ N.
f(z)
coefficient. for all
suf-
Consequently,
~(log(2 - l l c p l a n - P ) ) m ( E n )
~(log(2-11Cplan-l))/%(-log(na
shows
functions.
for
ok =
c
Izl ~ aN,
E d
< rka -C-I = n
F(r)
n ÷ ~, we see that
is a p o l y n o m i a l If
I
~
)) n
that
p = 0.
Hence
H ~ ( [ \ E)
contains
only
[] of null
as follows:
classes
0~
the p r e c e d i n g
theorem
can be
259
Theorem.
Let
O~
Then
}
and
strictly
We set
~
be c o n v e x
includes
functions
satisfying
(AI) above.
0~.
0p = U{0q : 0 < q < p}
we have the f o l l o w i n g ,
where
the
and 0 + : n{0q: p < q < ~}. Then P i n e q u a l i t y sign < m e a n s the s t r i c t
inclusion. Corollary. (b) Proof. one:
(a)
0- < 0 < 0 + for P P P 0AB , < N{0q: 0 < q < ~},
$(t)/~(t)
= o(i),
(a)
(AI)
t ÷ ~, if e i t h e r
Let ~(t)
0 < p < ~. = e pt - 1
is e q u i v a l e n t
~
or
$
Indeed,
In o r d e r
satisfies
eqt/~(t) Hence
~
satisfy
0~~ < 0p, we h a v e o n l y
0 ~ t ~ 2/p,
ePt/t,
t ~ 2/p. ~
is a c o n v e x
So, by the t h e o r e m ,
= o(i),
function
~(t)
t ÷ ~, and t h e r e f o r e
= te pt
and
(AI) and t h e r e f o r e t + ~, for any
~(t)
0q < 0~
(b)
0~ < 0 .
To s h o w t h e
~(t)/~(t)
Hence
(AI),
so that
In fact,
@
and
0~ < 05.
As
U{0q:
We r e m a r k that, their
following without
proof:
the c o n d i t i o n
and
(AI),
~
= t 2
and
0AB , < 0~
¢
by the t h e o r e m .
t ÷ ~, for any
%(t)
q > 0, so that
= exp(e 2t) - e
are seen to s a t i s f y = o(i),
if two n u l l c l a s s e s
exists
H~(D)
~(t)
=
0q <
[]
of r e g i o n s ,
e.g. 0 and P H e r e we state the
functions
a region
while
and
the c o n d i t i o n
t ÷ ~, so we h a v e
is v e r y wide.
If the c o n v e x
functions,
= t. in IA.
0 < q < ~}.
eqt/~(t)
difference
$(t)
as m e n t i o n e d
0 < q < ~} ~ 0~ < 0@ ~ 0AB.
then there
only constant
¢(t)
05 = 0AB,,
is seen by t a k i n g
0q, are d i s t i n c t ,
contains
we s e t
t ÷ ~, we have
0AB , < 0~ ~ n{0q:
Consequently, 6C.
half,
functions
~ ( t ) / e qt = o(i),
latter half
exp(e t) - e.
0~.
first
= o(i),
On the o t h e r hand,
The
we h a v e
Hence,
q
are then c o n v e x
05 < 0q.
a g a i n by
On the o t h e r hand,
q > p, so that
0 <
Then these
Op < 0¢ C 0+ . = p $
If
In o r d e r to show
= e p t - i.
0p < 0~.
and the con-
0~ < 0~ = 0p.
0p = U{0 q : 0 < q < p} C = 0~ < 0 p .
0 P < 0 p, + we set
~ ( t ) / e qt = o(i),
Since
the con-
:
is s a t i s f i e d .
q < p, t h e n
to show that
p2e2t/4,
it is easy to c h e c k that (AI)
the theorem.
and
to a s i m p l e r
and
~(t)
and
0 < q < =) < 0AB.
(3) in 3B.
to set
that
U{0q:
We first n o t e that the c o n d i t i o n
dition
dition
0 < p < ~.
~
D ~ ~
and
~
satisfy
such t h a t
is i n f i n i t e
H~(D)
dimensional
260
and
contains
lined
7.
functions
in H a s u m i
Majoration 7A.
2C.
Lemma.
Let
a convex
f
Proof. in
such
its
on
that
OAS
LHM
D
connected
D
in
let
contains
only
to
possesses
show
that
a Green
which
a non-polar
set.
Thus
it is p o s s i b l e
F
each
being
and
D.
define ux(z)
Since
contains
set
Let
analytic
is not
a point gr(z0,z)
functions
Ux,
function
the
from
let
~
be
a harmonic
the
set of a n a l y t i c by a q u a s i -
class
of r e g i o n s
D
functions.
~ 0 G.
with
thus
D £ 0AS.
clearly
Since K
set
a
two
Ch.
D'
2, . . . . D'
a
We n o w a s s u m e K
is
closed and
sets
so
I, i m p l i e s
boundary
on the r e g i o n
has
= ~ \ F'
6D,
for
n = i,
[\ D carries
D ~ 0G,
into
D'
Theorem
function
for
be a r e g i o n If
D
We
Green
D
then
is a r e g u l a r
=< n]
x E D',
let
D ~ 0 G.
to d i v i d e
set,
which
be the
g'(z0,z)
and
set.
a polar
z0
So,
i.e.
disconnected.
a non-polar
F
F n = {z @ F:
point with
of the
pole
Finally by the
z0
we
formula
: g'(x,z). D' v n = (Uz0)Fn
Let Fn
(Ch.
and
are m a j o r i z e d
n,
{Vn}
monic
I,
6E).
and
as above, {Wn}
w ~ w 0.
be the
balayaged
Clearly,
vn
there
by
g'(z0,z).
and
therefore
is i n o r e a s i n g
function,
fixed,
So
and
has
is m a j o r i z e d 0AS
is a c o n t i n u u m ,
is t o t a l l y
region
denote
constant
0AS
say)
F
AS(D)
function,
(= K,
that
region
%(log+IfI )
easily
= 0 G.
bounded
F',
be d e r i v e d
If
by
only
that
and
can
on a p l a n e
log+if(z)I
We d e n o t e
noneonstant
D = D' \ F.
which
function
[
such t h a t
component
[\ D
is out-
is q u a s i b o u n d e d .
AS(D)
We have
[, w h i c h
A proof
Functions
(i) holds.
function.
for w h i c h
Theorem.
singularities.
Harmonic
following,
be an a n a l y t i c
harmonic
[
the
For a r e g i o n
functions
in
f
then
7B.
bounded
we h a v e
function
majorant,
essential
by Q u a s i b o u n d e d
First
Theorem
having
[21].
are
function
bounded
of
harmonic
Since
{F n}
converges
Uz0
relative
functions
on
to D
is i n c r e a s i n g
with
to a q u a s i b o u n d e d
har-
set
say v, on D. Next we take any y ~ D, w h i c h is h e l d D' ~' w n = (Uy) F n for n = i, 2,... and w 0 = (Uy) Then,
{Wn:
n = i,
tends In v i e w
2,...}
is i n c r e a s i n g
to a s u p e r h a r m o n i c of T h e o r e m
6E,
Ch.
function,
and
wn S w 0
say
w, on
I, we h a v e
wn
Uy
for all
n.
D',
satisfying
on
Fn
except
261
for a polar set.
Since the union of countably many polar sets is again
a polar set, we see that set. Let
by Theorem
= g'(y,.)
Y of balayaged
The definition g~(z0,z)
w : u
on
functions
be the Green function
for
F
except for a polar
shows that
D' \ F n
w = w0
with pole
on
z 0.
D. Again
6E, Ch. I, we have Vn(Y)
= H[Uz0;D' \ Fn](Y) = g'(z 0) - g~(z0,y) = H[Uy;D' \ Fn](Z 0) = Wn(Z O) ÷ W(Zo).
D, w(z O) = Wo(Z U) : Uy(Z O) = Since z 0 is a regular boundary point of Since each v is a bounded g'(y,ZO), Hence Vn(Y) ÷ g'(y,z 0) on D. n harmonic function on D, we conclude that g'(Zo,-) is a quasibounded harmonic
function on
Finally,
D.
consider the function log+if(z)i
for a sufficiently D
is majorized
Corollary.
= (z- zo )-I
on
= log+
1
~ g, (Zo,Z) + C
large constant
C.
This means that
by a quasibounded
stant, we conclude
f(z)
that
harmonic
function.
~.
Then,
log+If(z)l f
As
D ~ 0AS, as was to be proved.
on
is not con-
[]
0 G = 0AB , = 0AS.
NOTES Heins' ili].
classification
theorem
is in his lecture note
For the case of plane regions he only showed
proposed
further investigation.
were made by Hejhal sults mentioned
Afterwards,
[32], Kobayashi
[38,
above are due to Hasumi
interesting
39] and 0brock [21].
[31; Chapter
0AB , < 01
and
contributions [49].
See Hasumi
The re-
[22] for some
related results. Lemma 3B is in Hejhal Hasumi
[21].
Theorem
[32].
The fact stated in 6C is proved
7B is adapted
from Segawa
[63].
in
APPENDICES
A.I.
The
Classical
A.I.I. Theorem. set
We b e g i n
Let
p
be a f i n i t e
= p(l A (-=,x))
(a)
F'(x)
(b) Uc
exists
if we and
set Us
For a p r o o f , [59],
Ch.
A.I.2. region 2e
we mean
E0
Let
the ~
is h a r m o n i c
S(eiS;e) Proof.
(to, that
on
~.
I
and
Then
Lebesgue
textbook
on the
and ~s
measure
on r e a l
P - Pc'
singular dx
parts
on
analysis,
I.
e.g.
unit
vertex
circle
~.
E0
angular
and
By a S t o l z measure
z~ 0) < ~},
set
Then and, to
tends
= I
F'(8)
e
0 ~ r < i. the
following
Borel measure
on
T
and
set
P(r,e -t)d~(eit).
any real
~ ( { e i8 : t O ~
=
z
a n d we h a v e
complex
Take
t O + 27)
with First
interval
summable;
-~ < a r g ( l -
We
= u ( r e i6)
t O ~ t ~ t O + 27.
interval
to the
with
kernel
be a f i n i t e
F(t)
provided
~
= {z • ~ :
Poisson
(2) for
is
on an
= ( i - r 2 ) / ( l - 2r cos e + r2),
u(z)
u
x • I. and
point
disk
0 < ~ < ~/2.
(i)
Then
measure
set
we a s s u m e
Theorem.
I
standard
be a n y
open unit
the
is c a l l e d
on
respect
see a n y
P(r,8) This
for every a.e.
with
S(~0;~) where
complex
of m e a s u r e s .
8.
Let
in the
on d i f f e r e n t i a t i o n
for A C = I and Pc(A) = fA F ' ( t ) d t a r e the a b s o l u t e l y c o n t i n u o u s a n d the
U, r e s p e c t i v e l y ,
Rudin
Theorem
with a theorem
F(x)
then of
Fatou
exists
e
tO <
and
set
t})
for almost
every
8
in t h e
for any such 8, u(z) t e n d s to 2~F'(8) ie through any fixed Stolz region
0 < e < ~/2. we
see e a s i l y
that
u(z)
is h a r m o n i c
in
D.
By t h e
263
preceding only
theorem,
to
show
If
~
then
u(z)
trivially p
if
the
is
the on
is
•
proven
notation
function
loss
any
e.
for
the
of
definition
~-9)
is
differentiable
through
F(t) So
:
the
measure
theorem
modified
it
assumed
also
F
implies
P(r,e
- t)dF(t)
=
Poisson
r COS e
integral
f
:
-
P(r,e
formula
for
the
harmonic
we
any
may to
and
= 0
T, is
given
therefore simplify e = 0.
and
so
- t)F(t)dt.
function
= -
r cos e
P(r,8 - t)sint
-'If
Thus
We
In o r d e r
= F(~)
on
theorem
for
t O = -~
F(-~)
have
-'g
P(r,e - t)cos t d~(t)
|
the
proven
= 0.
that
-g
The
be
So w e
= dt/2~
that
~ - ~(T)o.
B(T)
that
a.e. regions.
do(t)
can
measure that
is
Stolz
( t - t 0 ) / 2 ~ , so
generality
of
=
F limits
Lebesgue
and
slightly,
u(re
of
normalized
for
without
The
the
existence
~ i true
it
assume
the
states:
d~(t).
-][
have
u ( r e zS) - 2 z F ' ( 0 ) r c o s
8 = -
P(r,8 -t)(F(t)
- F'(0)sint)
dt
-7
=
(-sin t
=
+
P(r,e
+
+
= I 0 + I I + 12 + I{
with we
0 < 6 < ~•
have
only
Since
to F
Since estimate
is
(3) to
zero
increasing (3)
for
and
and
this
angular
min{~/2,~-
t ÷
function 0 < t
After i
as
I0,
~F(t) 0.
So
e(t),
say,
I I'
II
(resp.
and at
_ F'(0)
there
12
12') a r e
and
similar,
12 . 0,
'
-F (s- t~)
exists
0 £ t ! ~/2,
_ F'(0)
}
a continuous with
c(0)
monotonically
= 0, w h i c h
majorizes
~/2. =< preparation, measure
2~}
and
-
+
+I~,
differentiable max{
tends
II
- t)) is-~
belongs
2~, to
take
any
Stolz
0 < ~ < 7/2. S(I;~),
then
region If
rlsin
S(I~)
z = r e ie 91/(1
with with
-rcos
8)
vertex 101
<
~ tan
therefore
(4) where
lel ~ A(l-r), A
is
a constant
depending
only
on
e.
Since
e(~)
is
monoto-
284
nically increasing, (5)
so is
0 < 60 < i
Suppose now that
6~(6) I/4.
and
Let
60
be chosen so that
c(60) < min{(2A)-4,(260)-4,1}.
z = re i6 E ~
satisfies
(4) and
i - r £ 60~(60 )I/4
Then there exists a positive number 6 with 0 < 6 < 60 i - r = 6~(6) I/4. It follows from (4) and (5) that
such that
181 ~ A ( I - r) : A6s(6) I/4 ~ 6/2. If
Jt I £ 6, then J-sin t ~ t P(r,e - t) I =
2r(l - r 2 ) J s i n t sin(e -t) 1 2 ((i- r) + 4rsin2((e - t)/2) 2
4 ( i - r)-36(le] + 6) £
4(6a(6)i/4)-3.6.36/2
= 66-ie(6) -3/4 and thus II01 £ i6 [-sin t ~ P ( r , 8 -6 < 66-1s(6)-3/4.26~(6) If
6 ~ t
~ ~,
then
3~/2
there exists a constant
- t) I s--i-~-F(t)F'(0) dt
= 12E(6) 1/4.
~ I t - el m I t l B > 0 with
(6)
[el m I t l / 2
and therefore
sin 2 8 ~____t_t~ Bt 2.
So, for
6 £ t ~ 7/2,
l-sin
t~
P(r,8 - t)J £
4(1 - r ) t < Const. t-26a(6) I/4 sin3((t - 8)/2)
and thus IIlJ £
i712 ~6
[-sint
~
F(t) P(r,e -t) I s--i-~- F'(0) dt
£ Const.6¢(6)l/4IT/2 ;6 Finally, let 7/2 £ t £ ~. in view of (6),
]~-t
By (5),
t-2dt : Const.a(6) I/4 i - r £ 60a(60 )I/4 £ 1/2
and so,
P ( r , 8 - t)[ < 4 ( 1 - r ) [ s i n ( ( t - e)/2) I = i- r = 16sin4((t - e)/2) Isin3((t - e)/2) I < C o n s t . ( l - r) < Const.a(6) 1/4
265
This i m p l i e s
that
1~21 ~
I ~/2
+tP(r,0-t)llF(t)-F'(0)sintl
< Const.s(@)i/4(maxt
Combining
these
estimates,
IF(t)I + IF'(0)I)
z
so
u(re i8) ÷ 2wF'(0),
tends
A.I.3.
to
i
through
i14
e I £ C o n s t . s ( 6 ) I/4
S(I;~),
as desired.
Corollary.
= Const.s(~)
we get
lu(re ie) - 2 ~ F ' ( 0 ) r c o s If
dt
U n d e r the
then
6 + 0
and thus
E(6) ÷ 0;
[] same a s s u m p t i o n
as in T h e o r e m A.I.2,
let u*(e i0) which
exists
a.e.
on
T
lim r÷l-0
u(rei0),
as a s u m m a b l e
f
(7)
=
P(r,e
function.
Then
.
t)u*(elt)da(t),
-
T
for
z = re ie E ~ ,
Proof.
Since
is the q u a s i b o u n d e d
u * ( e ie)
fines a h a r m o n i c
= 2~F'(e)
function
seen to be q u a s i b o u n d e d .
on
implies
that
Pc
~,
of
we m a y a s s u m e u*(eit)da(t)
u- v that
where ~s
~s = ~ - ~c
positive monic
function,
n.
Set
F'(e)
is d e n o t e d v
is s u m m a b l e , by
v
(7) de-
is e a s i l y part of
function.
For
Since T h e o r e m A . I . I
is the a b s o l u t e l y
continuous
part
P(r,0- t)dPs(eit),
part of u- v
to show that
p.
Since
B
is n o n n e g a t i v e ,
is a n o n n e g a t i v e ( u - v) A n
v
= 0
harmonic
for any
= ( u - v) A n . Since v is a b o u n d e d h a r n n the first p a r a g r a p h of the p r o o f of T h e o r e m 2F, Ch. IV
shows that
(8)
v.
is the q u a s i b o u n d e d
is n o n n e g a t i v e .
and t h e r e f o r e
So it is s u f f i c i e n t integer
= I
is the s i n g u l a r
is a l s o n o n n e g a t i v e
function.
u(z).
is an inner h a r m o n i c p
= F'(t)dt
( u - v ) ( r e ie)
and
which
To show that
u, it is e n o u g h to see that this p u r p o s e
a.e.
~,
part of
Vn(rei0)
= I
P(r,e - t ) v ~ ( e i t ) d a ( t )
266
for
re
i8
v* denotes a bounded measurable f u n c t i o n on ~. n to t h e e x p r e s s i o n (8), we f i n d t h a t v* is the n radial boundary f u n c t i o n for vn • Since 0 =< v n =< u - v on D, 0 = < v * ( e it) < u * ( e it) - v * ( e it) = 0 a.e. a n d t h u s v E 0 by (8) as w a s n = n to be p r o v e d . []
Applying
E ~,
where
Theorem
A.I.2
A.I.4.
Let
ekeik8
on
[k~0
nomials
be
the
set
is t h u s following
Then
we
Corollary.
For
any
f E L (d~)
P(T) + P(~)
such
the
Proof.
that
We m a y
for
see
suppose
(9)
have
Ch.
re i8 E ~ . to
ascending IIhnll~ ~
By t h e
f(e i8)
a.e.
sequence IIfiJ
and
there IlfIl
IV,
that
u(rei8)
tends
the
IJfnll~ ~
definition,
of a n a l y t i c
P(T) + P - - ~
~.
(for
on
P(T) T.
Fatou as
2A),
trigonometric set
exists
and
of
f
{fn }
a.e. can
n
If
be
poly-
in
f e H~(d~)
taken
from
P(T).
Set
P(r,8 - t)f(eit)do(t)
theorem
A.2.1
and
Theorem
r + i - 0.
Let
0 < rI < r2 <
tending
to
let
h
hn + f
a.e.
P(r,e-t)
polynomials
trigonometric
a sequence
fn ÷ f
then
JIfrl > 0.
= r JT
the
i
and Using
=
A.I.I~ -.-
u ( r e ie) < i
(e ie) = u ( r eie), n n expansion
the
[
reJee l](e-t),
[ j_~
c . r i J IeiJ 8 jn
be an
so t h a t
we h a v e
h n ( e i8 ) =.
(10)
with
• = c] ST for
j = 0,
formly
on
-+i, . . . . T,
one
Since
can
find
f
sequence have
c.
the
(eiS)
{fn } : 0
conditions thus for
ilhn -
right-hand
and
N[ j:-N
fnil the
)
•.
integer
_ n-• n
fulfills
j < 0
.
the an
n
satisfies
f(elt)e-l]tdo(t
side
> 0
(i0)
converges
such
uni-
that
.. c . r l J i e l] ~ n
< 2Hfl[ /n
requirement.
therefore
of
N : N(n)
f
n
and When
E P(T).
]IfnH~ <
[Ifii .
f E H~(dg), []
The we
267
A.I.5.
For c o n t i n u o u s
Theorem.
Let
sequence
{f } n
Proof. The
f
be a r e a l in
We m a y
suppose
characteristic
on
the
Using
find that we
large lh n
-
that Unl
f < h =
uniformlY.
moreover
< i/n.
+ i/n
A.2.1.
Theorem
To a n y
u. 0 < s < i.
for
=
on C o n j u g a t e
u C Re(R(T))
u + i~ e P(T)
Let
and
f ~do
with
(a)
on
First
•
with
A.I.4,
rapidly
enough,
N = N(n) the
we
so
inequality
fn E Re(P(T)), < f + 4/n.
Hence,
=
~
the
a unique
is c a l l e d
~ E Re(R(T))
the h a r m o n i c
con-
following:
u ~ 0, -I/s IIUlll;
2 ( s + l ) / S ( c o s - ~ ) -1/s UuU1 .
< I1~11s =
Proof.
u
u e Re(P(T))
(12)
branch
(9).
Functions
= 0.
II[IIs =< ( c o s ~ ) for any
+ 3/n
by
everywhere
take
satisfies
n
we associate
T h e n we h a v e
u E Re(P(T))
(ii) (b)
1
see t h a t
+ 2/n < h n
uniformly.
[]
such that
(a)
= u n
jugate
of
f
to
is a
show that
of C o r o l l a r y
We t h e n and
we
then
= f(e i8)
tends
is r e a l
÷ f
n
there
be d e f i n e d
kernel
< I/n.
Then f
u ( r e i8)
proof
{r n}
T.
and
u ( e i8)
in t h e
= Un + 2/n,
fn
and also
Kolmogorov's
and
I f - hnl
n
uniformly.
Lemma.
as
Let
Poisson
T
When
that
Setting
< f =
A.2.
of t h e
boundary
on
f < f = n
llfll > 0.
u n = [ j = -N N c j r ] n J l e ije
n
fn ÷ f
that
same notation
hn ÷ f
can assume
function
such that
properties
up to t h e
we have
continuous
Re(P(~))
is c o n t i n u o u s T.
functions
suppose
values
u > 0.
in the (u 2
R e { ( u + i~) s } $
Then
(u + i~) s
sector
has
a single-valued
larg z I < ~s/2.
+~2)s/2cOST
$
cos
So
2
and therefore
eos~which
shows
I~lSdo < the
u $ 0, w e h a v e tend
to (b)
Re{(u
inequality only
+ illS}do
(ii)
to c o n s i d e r
for
:
Re
u > 0.
u + s
with
(u + i[)Sdo
In c a s e s > 0
= (
udo) s
u E Re(P(T)) and then
with
let
0. For e a c h
n = i,
2,...
there
exists,
by T h e o r e m
A.I.5,
a
268
function
u
E Re(P(]F))
with
u+
n
max{u(eit),o}.
Then
u
-u
< u =
< u + + l/n,
n
and
u
n
have
IIEnll s
where
+ l/n)
s
shows
the
A.2.2.
inequality
Theorem.
+i/n)S+
z : re
ie
E ~.
realized by
W(0)
a.e.
and
on
~
(12).
Let
¢(z)
also
lie n - Ell s
=< C s l l U n - ull 1
Therefore,
(IIu-lll+i/n) s)
=< 2S+icSllulll, s
[]
u E Ll(do)
=
Let
= 0.
be real
and
Proof.
Suppose
first
continuous
functions
~(z)
Then
such that
un ÷ u
in
0 < s < i, to
some
if n e c e s s a r y ,
we may
fn : e x p ( - U n fn E H~(da) and
so
fn
and
be the h a r m o n i c
l i m r + l _ 0 Y(re ie)
therefore morphie
conjugate (= v ( e i e ) ,
we have
are real,
~,
we
f(re ie)
almost
all
Since
~(rei6), that
6.
max{-u,O}.
a.e.
in
each
f(0). ~.
in
follows
: l i m r + l _ 0 ~(re ie) by a p p l y i n g
~(0)
= 0
i~)
in
LS(da),
We
Ifl ~ i, weakly*
into
= u
and
D,
on
~ + i~ As
as
set
of
in
~.
T
and
is h o l o -
f(z)
E H~(~),
r ÷ i- 0
for
÷ exp(-iu#(eiS)).
a.e.
the a b o v e
in
uniformly [fl
of
a subsequence
fn ÷ f
D.
continuously exists
that
-log
exp(-iW(rei6))
8, v a r i e s
density u n ~ 0,
converge
almost
We h a v e
Since
e,
the
extensions,
fn + f
f = exp(-¢-
such
and
By t a k i n g
: e x p ( - u ( e ie) - i u # ( e i e ) )
fixed
u E Ll(do)
A.2.1
nor-
exists
.
A.I.5
the a n a l y t i c then
¢(z)
say)
÷ u and E ÷ u # a.e. # n iu ). Then, IfnI ~ i,
F r o m this
symbols,
= ~
For
n
f= e x p ( - u -
÷ f(e ie)
v(e ie)
for any r e a l
u
of
u n E Re(P(T)),
u # C LS(da).
that
so is
find
By L e m m a
say
see t h a t
with
By T h e o r e m
we can
If we d e n o t e same
- log Ifl
in
assume and
by the
fn(0)
Ll(da).
fn ÷ f
f E H~(do).
Since
u ~ 0.
Ll(da),
element,
i[n) and
f
that in
set
P(r,8 - t ) u ( e Z t ) d o ( t )
f
llvlls =< 2 ( s + l ) / S ( c o s ~ ) - i / s l l u l l l
(13)
and
we
is a r b i t r a r y ,
which
clude
=
(ii)
1
IIEII ss 5 2Sc s (llu+lll s + ,lu-ii1)
for
So by
s + ilunll s) s
< 2ScS((llu+ll =
n
and
(e zt) "
U +
> O. =
c s = ( e o s ( w s / 2 ) ) -I/s.
II u II s =< 2S(llE_Enlls
As
-u n
__< C s l l U n l l 1 =< C s ( l l u + l l l
< Cs(llu-lll+ i/n),
where
=
E Re(P(T))
as
r ÷ i - 0, we c o n -
The
argument
same to
can
be seen
max{u,0}
269
To s h o w the i n e q u a l i t y look at the a n a l y t i c Re(P(~)) ~n ÷ $ monic and
be c h o s e n almost
extension
so that
uniformly of
un
-
u
n ~,
in
(resp.
~ n ( p j e ie) ÷ ~(pje ie)
II~(Pl ei8)
(13), we take any
functions
0 < Pl < P2 < i
¢ (pj z) + i~( pjz) ,
j = i, 2
+ u
Then
in
Ll(do).
where
%n
(resp.
~n ) to
~.
Thus
uniformly
on
T
for
~n)
%
.
Let + ¢
n denotes
and un e and the h a r -
C n ( p j e i8) ÷ ~(pje i6) j = i,
2.
So
~(P2eie)ll~
=< 3S(ll~(Pl eiS) _ ~n(Pleie)lls s + ii~n(Pleie ) - ~n(P2eie)ll s + By a p p l y i n g
(12) to the c e n t r a l
II~n(P2 eie)
-
~(P2 e±e)lls)'s
t e r m of the r i g h t - h a n d
side and l e t t i n g
n ÷ ~, we get
I1~( pl eie) We set
-
~(
~p(e ie)
p2 eiS)
II s
=< 3.2
= ~(pe ie)
(s+l)/S(cos~)-i/sll~(Pl
eie) _ } ( P 2 e i S ) U l .
and
~ (e io) = ~(pe ie) P L (da) t e n d i n g to u
0 < p < i.
Since
i
as p ÷ i, we have {~ } forms a C a u c h y net in P seen that {~ } forms a C a u c h y net in LS(dd) as p ÷ I. Since P (e i@) + v(e i@) a.e. as p + i, v E LS(dd) and ~ ÷ v in LS(dd). P P The i n e q u a l i t y (12) t h e n i m p l i e s the d e s i r e d i n e q u a l i t y (13), for ¢ ÷ P u in Ll(d~) as p ÷ i. []
A.2.3. u
n to
As a c o n s e q u e n c e
E Re(P(T)) v, w h i c h
monic
t e n d to
in
exp(-u-
of
we see that,
if
~ t e n d in LS(do), 0 < s < I, n in r e l a t i o n to u. v is c a l l e d the h a r -
u @ Ll(dd)
iF) E H ~ ( d o )
theorem,
Ll(d~),
is g i v e n by A . 2 . 2
conjusate
shows,
u
of the p r e c e d i n g
and
is d e n o t e d
provided
that
by
[.
As our d i s c u s s i o n
u ~ Ll(do)
is b o u n d e d
below.
A.3.
The F. and M. R i e s z T h e o r e m A.3.1.
We will give ~ k s e n d a l ' s
We first n o t e the f o l l o w i n g , n e rfu~la.
Let
w k E ¢,
which
k = i,...,
p r o o f of the F. and M. R i e s z can e a s i l y
n, s a t i s f y
be v e r i f i e d lWk[
< i
Then n
n
ll- It (1+%)I ~ IT (l+ lwkl)-i k=l
k=l
and
theorem.
by i n d u c t i o n . R e ( w k) < 0.
270
A.3.2. circle
~
Theorem.
Let
in the c o m p l e x
~
be a c o m p l e x
plane
such that
f
(14)
e Z.n t d ~ ( e Z t )
Borel m e a s u r e
on the unit
= 0
T for
n : i, 2, . . . .
the L e b e s g u e Proof. zero,
for
i.e.
IFI = O.
number
and
~
p - p(T)o
is a n a l y t i c
hood of the closed sequence
unit
(a)
the
{gn }
istic
function
Iz-zjl shows
of
(a).
disk
~.
j = i,...,
z E T
and
÷ i
~ 6
z E F, then
on
F.
z E Ak
Iz - ( l +
< 0
a
unit
that
n : i, 2,...;
we c l e a r l y So
and
have
Ign(Z) I < 2, w h i c h
for some
< rk
1
= Pk
n "
consider
Then,
for
k
and thus
any
]~ j=l
N.
N [ ll+
p.m.] i+
$ J z - ( i + pj)zj
pjzj z
z E ~
with
Ipjzj/(z - (I + pj)zj) I < i
j = i,...,
N[ _<- 7 7 j:l
exists
~j)zj 1
- Zkl
6 > 0.
i-
F the set
to the c h a r a c t e r -
we have
Ign(Z) I :
there
it follows
~
z C T
On the o t h e r hand,
R e { p j z j / ( z - (i + pj)zj)}
A.3.1,
cover
z-z.
j:l ~
for any fixed
n, a
in
on the c l o s e d
and
on
j = 1 .... , N.
< I z - (i + pk)Zkl gn(Z)
zN
N}, a n e i g h b o r -
theorem
polynomial,
for each
Iz
dist(z,F)
length
integer
these
uniformly
for
N
Thus
that
with
and define
pointwise
for all
I:
~
Zl,...,
such that
gn
to every
In fact, If
suppose
set in
centers
By the Runge to
converges
'gn(Z)-l
~, we may
Izl < l + m i n { p j :
< Iz- ( i + pj)zjl the c l a i m
to
N z-z. ~ $ j=l z - (i + pj)zj
Ign(Z) I <__ 2
F.
with respect
for each p o s i t i v e
with
converging
We c l a i m that
of
pj : nrj
: 1-
in
of p o l y n o m i a l s
sequence
AN
We set
disk. Since ~ is o r t h o g o n a l fT g n ( e i t ) d ~ ( e it) : 0.
(b)
continuous
be a c o m p a c t
rN, r e s p e c t i v e l y ,
[jN I rj < i/n 2.
gn
F
exists,
AI,...,
rl,...,
instead
Let
So there
of disks
gn(Z) Then,
is a b s o l u t e l y
T.
n = O, too.
and with r a d i i F
on
By c o n s i d e r i n g
(14) holds finite
Then
measure
- ( i + pj)zj
] -1
By a p p l y i n g
Lemma
271
N[
= ~
j=l
< exp
=
]
i+
-i
Iz- ( i + pj)zj [
I
~ log(l + -~--) - i j:l
exp
-1
=
exp
j :i
-1
<j =i
< eXP(n~) - i, for
[ j=l N rj < i/n 2.
So,
gn(Z)
÷ 0.
Hence,
the
statement
(b) is ver-
ified. Consequently,
the d o m i n a t e d
fF d~ = limn÷ ~ f gnd~ of length respect
zero,
: 0.
we c o n c l u d e
to the L e b e s g u e
A.3.3.
Let
p
that
f E Ll(do).
~
measure
be as above.
Thus,
on
T.
Then,
for
n = i, 2, . . . .
This means
that set
continuous
A.3.2,
: f(eit)da(t)
f(elt)elntdo(t)
"
shows
[]
by T h e o r e m
the c o n d i t i o n
IT
theorem
for any c o m p a c t
is a b s o l u t e l y
dt
d~(e it) for some
convergence
As this holds
(14)
states
that
= 0
' that
f
belongs
to
Hl(d~).
p(F)
=
in
T
F with
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INDEX OF NOTATIONS
A(a/b), A'(a/b): XI.3C B(e,a): V.IA CK(R,~): III.IA C0(R): IV.5B • : IV.IA D(a): VI.3A N(f): III.4B dx: III.2C do: IV.IA A(R) (= A): III.IB
IV.3A H~(R), H~(dx): VIII.IA h~(R): IV.5C
AI(G): I I ! . 4 B AI(R) (: AI): III.2B E0(R,a)
(= ~0(a)):
VI.IA
F0(R): 1.3A (conformal map): VI.3A (convex function): XI.IA g(a,z): 1.6A (a)( g z): VII.IA G[f;G(a)]: VI.IB ~(R,a) (= {(a)): VI.IA {'(R,a) (= {'(a)): VI.IA G(b): III.4A F, Fc, Fc0 , Fe, Fe0 , Fh: 1.8D Fh0: 1.9B; V.6D F I, Fa' I F~, F e' I Fh: i 1.8A FM(CI(G),~): V.4B F(r), F(z;r): XI.3C
h[f]: III.5A H[f]: III.3A H[f;D]: 1.5A hP(~), h~(~), hQi(~): IV.IC HP(~), H~(~): iV.IB HP(do): IV.2A H~(D): XI.IA HP(R), H~(R), hP(R), h~(R), HP(dx):
HP(~,~), HPd~,~), HP(d~,Q): ~P(R,~):V.2A ~(G,~): V.4B HP(a), HP(R): II.4A HP'(R): II.4B HI(R): 1.2A HI(R,T): II.IA I0: IX.2A I(R): II.5A k(b,z) (= kb(Z)): III.IB K'(a), K n (a): VII.7A XR (= dx): III.2C ~A: IX.2A ~C: IX.2D ~(R,a) (= L(a)): VI.IA A(R,a) (= A(a)): VI.5B m(a), m(~,a): V.8A mP(a), mP(~,a): IX.ID
IX.IA
277
M(AI):
III.2C
M(H~(R)):X.5A Mm: IX.3C {M] : VIII.IB P Np, N¢: XI.IA 0AB , 0AB,, 0~, 0G, 0p: XI.IA 0AS: XI.7B G a:
1.5D
S(~;~): A.I.2 S(%:~,p): VI.3D S(b~,p): VI.7B SP'(R): II.4D ~(c): I.gB e(a;z): VI.IA TR: III.6B w(E,E'), w(E',E): W(R): III.5A
IV.5A
~0: VI.3A P(a.a';z): VI.5B P(r,e): IV.IA; A.I.2
z(~;~): VI.IA Z(a,R): V.IC
Prl, prQ: II.5A (conformal map): VI.3A qc: QA: QC: Qg:
IX.3A IX.2A IX.2D IX.2D
QM: III.IB Q(R): II.SA R*: III.IB R%: V.3A r(a;z): VI.IA R(~,a): V.IA R 1.6E u~:
V, A (lattice operations): ^ (fine limit):
III.4B
v (radial limit):
VI.4A
(harmonic conjugation): II.II (norms): P
1.4C
A.2.1
IV.IB~ IV.IC; V.2A
INDEX
B-dual:
Behrens
IV.5B
theorem:
X.7B
II.5A
Betti
number:
V.IA
theorem:
X.6C
Blaschke
product:
Boundary
m-function:
Bounded
--
II.SD;
problem:
(: u n i t a r y bundle):
VI.SA
flat
morphic
II.IA
function: l.m.m.:
Canonical
basis: measure:
Cauchy
mero-
group:
function:
Corona
problem:
of - -
----:
direct
--
inverse
--
Covering
triple:
Critical
point:
(DCT)
( D C T )a ) :
(=
Differential:
Cauchy-Read Character:
VII.3C;
IX.4A
type):
VII.IB;
VII.4B
--
group:
-- of
-- of an --
--:
IX.4A
1.7A I.SA
--
(o(c)
singularity: problem:
):
I.gB
1.9A
I.SA;
III.3A;
VI.IB Divisor:
1.10B
VI.5A I.IA
canonical
V.4A
regular
1.3B
--:
--:
l.lC
I.IA
1.3B
function: l.m.m.:
of an m-function:
theorem:
mero-
II.2D
II.2C
IX.IA Choquet
Vll.3C~
1.8A
--:
Exhaustion:
a multiplicative
morphic
III.6A V.IC
VII.IC;
I.IIB
theorem:
III.6A
--:
-- with
End:
kernel:
III.6B
III.6B
1.7A
reproducing
III.2B
IX.IC Cauchy
II.IA
--:
map:
Dirichlet
- - --:
II.4C
VI.7E
X.5A
Covering
conjugate
1.2B
(weak
VI:7D;
XI.IA
transformation:
analytic
II.2D
II.2C
theorem
direct
theorem:
Convex
harmonic
Canonical
XI.6A
complex
II.2A
of a m u l t i p l i c a t i v e
- - of a n
Cocyle:
group
VIII.4A
XI.IB
line
value
Cover
IV.2C
characteristic:
Brelot-Choquet Bundle
set:
Cluster
Cohomology
Band:
Bishop
Circular
IV.5C
B-topology:
VIII.4A;
Fatou
theorem:
Fine
limit:
Fine
boundary
A.I.2
III.4B function:
Function balayaged
--:
boundary
m---:
1.6E VIII.4A
III.4B
279
Function convex
(continued)
Integral
--:
Invariant
XI.IA
i---:
IX.IA
m---:
VIII.4A;
IX.IA
Martin
--:
III.IB
Wiener
--:
III.5A
Fundamental
Gelfand Genus: Green
VIII.IA~
VIII.2C
simply
- - --:
VIII.IA~
VIII.2C
-- --
theorem:
transform:
X.5A
Kolmogorov
regular
1.6A
- - --:
LHM
V.TD
VIII.3B;
boundary
point:
theorem:
1.5B
A.2.2
VI.IA
Line . VI.5A;
- - --:
VI.5B
VI.IA
measure: star
VI.IA
Hardy
class:
IV.IB~
IV.3A
Hardy-Orlicz
class:
XI.IA
region:
(=
1.5D~
--
(= l o c a l l y
lus):
II.2C
--
bounded
of
--
Harmonizable:
inner
--:
II.5D --:
1.4C
Martin
compactification:
Martin
function:
--
III.2B
function:
pole
II.SA
III.2C
III.5A IX°IC~
IX.5D;
Maximal Mean
theorem: group:
III.IB
ideal
value
III.IB
space:
theorem:
Minimal
point:
Modulus
of a s e c t i o n :
X.5A IX.2D
II.4C;
III.2B II.2A
meromorphic
tion:
II.2D
1.2A
inner
factor
of
II.SD
outer
factor
of
II.5D
region:
1.5C;
rare:
V.7A
X.7B
of
bounded
characteris-
II.SD
II.5A --
factor
factor: of a n
greatest
common
--
II.5A
part:
func-
XI.3B
tic:
common
III.IB
III.IB
of a - - --:
Multiplicative
Hyperbolically
II°5D
III.2C
X.4A
Hyperbolic
modu-
characteristic:
boundary:
function:
theorem:
Homology
meromorphic
Martin
function:
quasibounded singular
modulus):
II.5D
I.SA
-- majorant:
minimal
II.2A
analytic
A.2.1
-- differential:
--measure:
majorant):
(= b u n d l e ) :
locally
quasibounded
conjugate:
X.2B;
bundle
L.a.m.
L.m.m.
VI.IA
Harmonic
Hayashi
harmonic
II.2C
Green
least
(= l e a s t
1.4C
Green
--
VIII.2C;
VIII.4C
1.2B
line:
Inner:
VIII.2A
--:
Irregular
function:
Hejhal
VIII°IA;
--
1.3A
convergent
--
subspace:
III.2B
doubly
group:
modified Green
representation:
II.5D
l.a.m.: --
Nakai II.5D
factor:
II.5D
theorem:
Normal Null
operator:
set:
XI.IA
X.8A; V.6B
X.8C
280
Origin:
II.2B
Orthogonal Outer
Riemann-Roch
decomposition:
character:
p - - - --:
II.5A
IX.IA
Riemann
theorem:
- - of M y r b e r g
IX.IA
type:
theorem:
XI.2B;
VI.4A;
XI.2C;
X.IA
- - of P a r r e a u - W i d o m regular
Parreau
1.10C
surface
VI.4B;
Riesz
theorem:
1.6F;
F. and M.
XI.2D
type:
V.IA
. V.IC III.3B
. A.3.2.
Partition identity
--:
- - of the Poisson Polar
V.6A
ideal
kernel:
set:
1.6C
Potential:
1.6B
Pranger
IV.IA;
X.6A
branch:
Principal
operator:
type):
A.I.2
II.2A
holomorphie
--:
II.2A;
meromorphie
--:
II.2A
II.2E;
theorem:
(= s u r f a c e
V.6A
Segawa
II.2D V.6D
theorem:
Standard:
of P a r r e a u - W i d o m
Stanton Stolz
II.5A;
theorem:
region:
(= q.e.):
Radial
limit:
Region
(= s u b r e g i o n ) :
canonical
--:
star
hyperbolic
Stolz Regular
I.IC --:
VI.IA
--:
1.5C;
Regularization:
= region function:
1.4A
VIII.IA
III.4A
Universal
covering
V.7A
Weak-star
maximality:
Weak
VI.7B{
point:
surface:
topology:
IV.SA
theorem:
V.2B;
Widom
V.3B
A.I.2
1.4A
III.6A
VI.3D
I.IA
VI.3D{
X.5B
VI.7B;
I.IA
--:
boundary
Support:
Thin:
Stolz
--:
--:
1.6C
VI.4A
curvilinear
regular
Subregion
X.IA;
VI.3D;
function:
Superharmonic
Quasi-everywhere
Green
IV.IC
II.5A
XI.7B
1.9A
IX.IA
Subharmonic
- - part:
--:
V.4B
Singularity:
V.IA
Quasibounded:
V.2A
meromorphic-differential
Principal
PWS
Section:
boundary:
A.I.2
1.5B
V.gA; Wiener
VII.5A
V.4C;
V.9B function:
III.5A
V.5C;
