Structural Monitoring with Fiber Optic Technology

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Structural Monitoring with Fiber Optic Technology

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Structural Monitoring with Fiber Optic Technology

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2.3 NEW MATERIALS FOR THE CONSTRUCTION INDUSTRY " . -. " - - . KK $ GG KK- . GG " .H % " (4$.$- C -- " +)$> !D " ;'3 )- -- 1" >. -% " . " - " - .-% " ,+ .- " " . . . " -- " . / - . - - - - % " F F#$ -. - -- 0

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24

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25

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2.6 MEASUREMENT PROSPECTS FOR FIBER OPTIC TECHNOLOGY " " .- " #$ - " ". .- " - - %

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28

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et al. C(::9D

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30

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31

FIGURE 2.12. F- # # - - $ .% . 6 ,%% % ,%1% A-- +% %% (::' KK # ! 6 , GG Magazine of Concrete Research 42 9@(; " . . " . - +#-" !%

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32

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FIGURE 2.15. , F- " # " - #.@ -. % . ,%1% C(::(D KK +-. , . -. . ! GG Magazine of Concrete Research 43 9:@2; " . . " . - +#-" !%

34

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36

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38

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2.8 OTHER STRUCTURAL MONITORING APPLICATIONS #

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41

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42

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2.9 WIND POWER AND STRUCTURAL MONITORING 7" " " - #- . " . " -

. " - - - - - # . "" % 7

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44

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45

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2.10 MAGNETIC LEVITATION TRAIN MONITORING 1"$ . ""- #- " .-- . # " - - . $ F . % * - C.-D - . ""$ " .

- "- 9'' . " ( % " ! )> "" # -

-- - # " 6 - .-- - # electrodynamic suspension C)D # . " - # . C # " "-D " $ -.. - . - " C)". (::9D% " . " " " "" " "- . " - " - " "- / "- - C9' ('' . " ( D% " ) . "? # - ('' .. "" # .-- #-% " A. '3 - " # " A. . " A. - ,- ! " - .# - - . " *".

46

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2.11 AEROSPACE ENGINEERING PROBLEMS " " - " - 343 1- 1 " ". - . " ".% * " " - - " $ . # " 6-meter " -

" B" % " - 2( " :9 H% " (:55 - .- " KK GG .% " 343 " # #- (:2: -" " " # -- .-- " .- # C (::2D% . - # (:5: "

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48

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2.12 NEW MATERIALS FOR THE AEROSPACE INDUSTRY * " . -- - ,+ .- . ". -#- " % " -- "-

" % , " # # F# .> % 1 -# "/ " ". "

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FIGURE 2.28. ).#. F#

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- . # " . % 1 - # " . ..- .- - >.- . -> - " " % -- " " -- - # . % " "- ?#- .# ""- - - " - #F . ,% " -- " "-

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/ . > " -% * " . -. # . "$ . # - > "-- "% " -- " # -? # . -F . " # " " . " -$. " - . .% -- - -. - # >.-

- -- . -#- - " # % #- " > . # - - # . . - "-" % , - " - . # . . F- "" - # . " "-" F - % " . - - .- " . % " . - # " -

. " B" " % " #- " - #- . " " . " #

? - . " # -- .% " > " -- . -- -- . - . - # . . % " " -- " - " " - . - # # " -. #-% -- . -. . " " " - # - "" " C7 et al. (::&D% " %% #. " .# - " .- " - (:3' "

" KK. GG " " + H % . " . " - F " " - .- - .- C*? et al. (:55N * (:5:N 7 (::'D% (::9 . - # , " -#. #- .-- - . - -- KK* "%GG - . - " - B " - " " " - - # . # ? - C% (%4D% " ." . B" - " - " . " ." . - ."- -. " . "- . " - . %

1 +),

4

!"

3.1 BACKGROUND AND OVERVIEW ..# " - - " - - " . % )- - . M .

# " # M . " " $ . % " - S

" F ? " -- . # # . "" ".- # " % " " " . >.- .-- C(' (9 .D - " -% " - . ::O " . " .% - " - -- - C(' (' .D H " " .# - " - . " .

--- C% 4%(D% Electronics " . - - %% - " " # F- ? " . . " # . " B

- - F-% .- " . photonics " . - " " .-- -"% " . # - " " . $ ?% )- > " . # . % +" > - 0 - " -"E " . light -- . - $ . " -" C - D " " # " ". % " . - - . . . .. " -" " - -"% " #

KK-"GG " # . - .$ % " " ". -" - # " > " -

% >. - " , . .. .. - " "-

-" . C% 4%&D% " 52

4%(

53

FIGURE 3.1. CD - C#D - " . - . "

- - F-%

.. " F - " -" -- .. % .H " - - -

. " .

- C-"$ D .. " "-- " .$ - % . " " -

54

1 +), 4 !"

> - - -" " " "

F# . - " - " "

" .- " . - . "% " F laser (:2' # " *. .-- - # " - # -" . "-- B" -. #. -" " " " . C% 4%4D% -" " " - -" -

- F# ? " - (:2' C? (:2(D " - $- -$- F# C< 1 . (:22N % 4%;D " -- - " " -

F# .. % * #/ " . F#

" - . " -- " " -? -% " - . F#

" #- - " .. % #

-- - - . " " - $" #-% " "" #" - >.- .

- F# - " . .# "- "

% " " " - "- " > - " . . $# $ . -- . " $ " " " . "" #"

- F#% . # . -

- F# .# C% 4%9D% " . - - " " . -" " .% 7 -- " analog modulation% digital modulation . -" - . # " # - " /% " "

- - - .. % Spectral modulation " . " -" " -"% " -- - " " -" - " - . " " " . % " -" - . - / C-- " - "? "?D " .$ # " / " " " /% " . frequency modulation% -- " - $ C# " > "

- F#D " - " - F- " " -" # . " . polarization modulation% -" "

- F# $ .. .. " # . " .% " -- ". # " -. " .

- -% " #

"-- "

- F# KK- . GG " .. . % " - # " " F#

4%(

55

FIGURE 3.2. , . - .. " -" "- . - B -"%

" # . . . - . . " . -$ - . F- - C -" (:55 (::3N (::(D% " " " # -" " % " -- " > " -"

FIGURE 3.3. CD ". # -% C#D - ,# - % *.% . "" 6% ,% % L A%% - %% KKAtomic Light LasersGG - +#-" (:23% %

56

1 +), 4 !"

FIGURE 3.4. --. - $-

- F# - .. %

" #/ "

- F#% " - . / " # "

-"$ % 7 " " -? -" > - .% -- -

" - -" #

- F# " " .

B %

3.2 ELECTROMAGNETIC RADIATION )- . . "

$ " " . - .

" . % 7 " -- > " - - # . # " % " # # " G - . " - " . -" .$ - . % " 6. - *>-- " .$(55' # - . # / " . " .- / " # " . C-" " (::(D% " / # -- - . " . . - F- CED . F- CBD% " /

4%& )!),* A) ,

57

FIGURE 3.5. ." . . # -" -

- F#%

. % 7" - " " # . #H - F- E; " - -> "

C# " - - "D " F-% " > " - W; # " - F- . " - . s( s& C% 4%2D # s& W eEds: 4:( s(

58

1 +), 4 !"

FIGURE 3.6. )- F- # - # - " - - %

1 " " - V(& ; # s( s& # " - " F- " %% s& Eds: 4:& V(& s(

" W eV(& :

4:4

" " " - " # > . electron volts C eVD " ( L " / # - -- " " - - ( -% - " . # " - /. ." " " # # # . % " #

. " /? . - " . " /? - . C% 4%3D% $ /. ." " .-- - . frequency n hn; " h Planck's constant " " - 2:2&2 (' 4; 6 % ". " - - > -- " . CU( ; U& ; U4 ; . . .D % 4%3% - # # . - . " . / . n " F " - n DU=h;

4:;

" DU " # . " .%

4%& )!),* A) ,

59

FIGURE 3.7. ) -- " . . >. - " - %

" - - " - # # > " "" # .# - " # "

. - . C% 4%5D% " > - -- " - " ground C- D U( ; # " " .- .

" - . / n C% 4%('D # .

" -> " - # " . -% .- . -- # ;%&% " . .. -" " # " " F-. " -" #-# % " - > "" # -- . - . . " - . $ % "

" -" # " electromagnetic wave equation C-" " (::(D "" C%% .D " . H& F

( @& F ; c& @t&

4:9

" c " - -" F E B " " - " . F- # " "

60

1 +), 4 !"

FIGURE 3.8. )> # - # " # -" "

-" " #/ " . -> %

/ % -" " E B " .0 CEx ; Ey ; Ez D CBx ; By ; Bz D -

" " . $ - F C4%9D "-- E -- " " . % . " . C%% - /D - - .- " z$ " E$®eld - )/% C4%9D " . E; x; y; z; t Ex; yeikz

ot

Ex; ye

ikz ot

;

4:2

" Ex; y; " amplitude " " -

" E$F- " - " x@y - k &p=l " " free-space propagation constant o &pn; " angular frequency

4%& )!),* A) ,

61

l " free- space wavelength " % " . " " )/% C4%2D " complex conjugate Cc.cD " F .% " - " . " Ex; y zN % 4%:% " . F- B; " " . . - > " *>--G / / # - "

" E$®eld

.. C-" " (::(D% "

" E$®eld . F> "

" " linearly polarized wave C% 4%('D% 7 "-- - " -"

-

- F# > . . ->

-? %

FIGURE 3.9. - . " . - . - " z$ 0 CD " E$F- - "

C#D " " E$ B$F- " - %

62

1 +), 4 !"

FIGURE 3.10. > E$F- -- -? -"%

" - " # " -" / -$ . # # # # " - - )/% C4%2D " / % " - k& o& =c& :

4:3

" " .

- .- " - " general propagation constant b; "" " .-

% " " - " " )/% C4%2D # " "- - " E$®eld% " "

- - " . Ex; y; z; t Re : Ex; yeibz

ot

Ex; y fbz

otg;

4:5

" electromagnetic wave equation .- "" " velocity of light u " . H& F

( @& F : u& @t&

4::

# C4%5D C4%:D - b& o& =u& ;

4:('

"" " index of refraction " .- n c=u;

4:((

.# C4%3D " C4%('D " b nk:

4:(&

"-- - b . / " "

-" -

- F#% b # " " " "

% " z; " phase " . - z ' # f bz: " " &p; .- - " " E$®eld

63

4%& )!),* A) ,

- z ' C% 4%((D %% Ef &mp Ef " m '; (; &; . . . : - " - . . > . " " -" C- " '%( .D gamma rays " " " - -" C ('' m.D " % .- " -"

- F# "-- # " M F-- (%4 (%9 m. " $ -" ""

- F# " " # . " C " 9 F-- % 9%(9D% " "" / -" -- " #- - " . - " E$ F-% " " . " -"$ -- " % -"

- " / E$F- C 7 - (:39D " . intensity I C D F " -" B - "

" % " # " # # " - I e' chE Ei

7. & :

4:(4

" hE Ei . " " E$F- " . -> H . - ." - " " " # -- ." " " . > .% ". $ - - . " )/% C4%2D h & oti h& oti (& ; "- h ot oti ': " " / C4%5D - C4%(4D " . I (& e' cE&'

7. & ;

4:(;

" " E' " .$ . -$ " % . .- / -" " radiance Jw; j C #"D "" F " B - $ . - - H %% Jw; j

( d& + w dSdO

7.

&

( ;

4:(9

" P " C7D # " w " - . " .- " j " - " .- d " -. - - "" "

-

64

1 +), 4 !"

FIGURE 3.11. , . -" %

% 4%((% " " - " # " " " " -" " . p=& &p Jw; j wdO 7. & : 4:(2 I w' j'

Jw; j J; I pJ: 7 - " spectral radiance Jn

dJ dn

7.

&

(

1? ( ;

4:(3

" spectral irradiance In

dI dn

7.

&

1? ( :

4:(3#

" . # " - # " -" . / #" CHzD% " )/% C4%3D - " $ -" l; " / n; -" " " " / nl c

. ( :

4:(5

3.3 BIREFRINGENCE AND POLARIZATION 7" - . " . ". - .

$ " z$ " "

.. C

"

D # # # )/% C4%2D% " -"

" z$ "

4%4

65

,),A)) +! ,T

birefringent medium " " > > # " #/- "

- " " E$F-% " -- % 4%(& " nx 6 ny ; " - " Ex Ey . " -" % " " -" # # / " # " "

" " E$F- . % " # > " . matrix equation ibx z otdx ~ t Re Ex z; t Re Exo e ib z td ; 4:(: Ez; y Ey z; t Eyo e y " " . - " -" Eo Exo; eidx ; Eyo; eidy ; o;

4:&'

d x ; dy bx ; by Exo ; Eyo

" phases " E$field z ' t '; " propagation constants ::; bj nj k

" j x; y; " positive field amplitudes:

7 . - C4%(:D # " total phase retardation CKK "GG " fz; t bx z

ot dx ;

"" -- Exo fz; t Ex z; t ; Eyo fz; t dz Ey z; t

4:&( 4:&&

FIGURE 3.12. .. . " x$ y$ . " E$F-%

66

1 +), 4 !"

" dz by

bx z dy

dx

4:&4

" . " differential phase% " KK

GG .. by bx b

4:&;

Exo ffz; tg Ex z; t ; Ey z; t Eyo ffz; t dg

4:&9

" " differential phase " - d dy

dx

4:&2

ot dx :

4:&3

" phase fz; t bz

" polarization angle y F " " y$ x$ .

" E$F- C% 4%(4D Ey z; t ( ; 4:&5 yz; t Re Ex z; t "" # C4%&&D " . Eyo ffz; t dg ( : yz; t Exo ffz; tg

FIGURE 3.13. !- -? -" # # " -? - y%

4:&:

4%4

,),A)) +! ,T

67

)/ C4%&:D " . " state of polarization C+D %% " - # " -? - y " " f: fyz; tg g d

d ffz; tg;

4:4'

" " g Eyo =Exo :

4:4(

" . .. . -? -" . linearly polarized light C!+!D% " " d mp

m '; (; &; . . .:

4:4&

y g mp (m g;

4:44

" .

" -? - y; # z t "

- " E$F- F>% " " - -? " " . C% 4%:D% linear polarizer .

- F- " . - " . -" " E$F- --- " . > " # F- .N % 4%(;% "

- -? -- -? -" " - " . > " -? " -" .% " % 4%(9 " " - -? - . " Ex . $ " -" "- " " ? - -? #- " .$ " . % " .# polarizer . . - dichroic sheet " -- " # # " . E$F- - . > C-" " (::(D -" - -?

- F# " - E$F- . - " - . % - . " . " E$F- " # " - " E$F- # # "

% " -? . circularly polarized light C+!D " &m ( d p m '; (; &; . . . 4:4; & g (;

::;

Eyo Exo :

68

1 +), 4 !"

FIGURE 3.14. !"$#- -?%

FIGURE 3.15. , " E$F- " . - -- -? -"%

69

4%; +),+ 1),)) ),),))

" C4%4'D # . fyz; tg (:''

fz; t;

"" " . yz; t

fz; t

4:49

" +! " E$F- C F # yD "

" - fz; t: " d &m (p=& " yz; t fz; t " left$+! "" - E # # " -" C% 4%(9D% -$ - d &m (p=& " yz; t fz; t; " right$+! "" - E; # #%

3.4 SUPERPOSITION, COHERENCE, AND INTERFERENCE 7" . " . -" - "

% " principle of superposition -- . " - " - . / C4%9D " " E$F- C B$ F-D # .. " C-D % " -"

- " / " E$ F- )/% C4%(4D - " " " . # " . " . " " - % " ". " E$F- " " " - -- " .% " . interference% -- -? -" " " . -?$ - y; . . " . -

" " " - " A B % 4%(2% " E$F- . " " .

z; t # > " . E( z; t E(' E& z; t E&'

b( ds b& ds

ot d( ot d& ;

4:42 4:43

70

1 +), 4 !"

" . .. angular frequency o; " E(' ; E&' b( ; b&

" E$field amplitudes; " propagation constants .. . :

7 " " spatial phase retardation ba ds da ; fa

4:45

"

> # " " - " " C

N % 4%(2% )/% C4%45D a ( &% 7 - " temporal phase retardation ot " " . t

. " . # " -" - # " "

" % 7 - d( d& " initial phases " " - # - z ' t ': " " # . . C4%(4D %% I e' chjE( E& j& i:

4:4:

" # > " . I e' chfE(' f(

ot E&' f&

otg& i;

4:;'

"" > # . I e' chE&(' & f( ot E&&' & f& ot &E(' E&' f( ot f& oti:

FIGURE 3.16. . . "# -" - " .

" %

4%; +),+ 1),)) ),),))

71

7 " - . - . " " . - . - I e' chE&(' f f( ot f( otg& i

4:;(

6 " KK# - .GG " - KK# - "%GG - " " # " " . #

# # " " .% 7 " F " - " " b( ds 4:;& f(

b& ds d;

4:;4

d d(

d& ;

4:;;

f&

"

" # " - " " -"% " -" coherent " . - " - " # " % " d "

. "" f( f& . # . . " . )/% C4%;(D %% I e' cE&(' & f( h & oti E&(' & f( h& oti :

4:;9

- ". h & oti h& oti (& h ot oti ':

4:;2

"" . " . )/% C4%;9D ? " . - " " # interference equation p 4:;3 I I( I& & I( I& f;

" I( I& " " - # # C% 4%(3D " " -" - #

" %% Ia (& e' E&ao

a (; &:

4:;5

72

1 +), 4 !"

FIGURE 3.17. /- %

7 " " # " -" " H " . " - % " > - interference term "

- f; " f

b( ds

b& ds d

4:;:

" differential phase # " -"% - " " . " - . -% " " /- . - C%% E(' E&' D coherent " " - ? " f p; % 4%(3% " . " KK . -GG destructive interference% " - # #- " . " " " f ': 1 . - constructive interference % " . KK "GG

# " " d .% " " C . " " " D " " " - " " %

3.5 PARTIAL COHERENCE AND COHERENCE LENGTH " KK "GG d " - " - " . . > " "

4%9 + , ! 1),)) 1),)) !)A1

73

%% I I( I& : " >. incoherence coherence - " .-

partial coherence% # "

" - -$ / -" # # E E' fkzg % 4%(5 " k &p=l; l " $ -"% " - " - / . n; " % 4%(5# " nl c; " c # " $ - " % " " " z; " - - -" . " % -" . " " #

. " -- " ".- > - " . -- " " . -" -- - .# " . - % " ".-- -- % 4%(:% - . - " " . . -> " . - #" " # . C-" " (::(N % 4%&'D% #-" " - " # " #" -" . - " Fourier transform theory% -"

FIGURE 3.18. CD * " . -" C#D - .%

74

1 +), 4 !"

FIGURE 3.19. -- " " E$F- -" # . %

" . - . # # ft " / . ( 1 fteiot dt; 4:9' so p &p 1

# " Fourier transform ft; " " inverse Fourier transform so ft C - (:39D0 ( 1 soe iot do: 4:9( ft p &p 1

FIGURE 3.20. ". -- " E$F- - " . ->

" . - #" " -"% " . . -> " . - " " .%

75

4%9 + , ! 1),)) 1),)) !)A1

" ft # -" . .- - / oc ; F tc C% 4%&(D% " ft e

ioc t

ft '

t=& < t < t=&;

4:9&

-- " .:

" . ft - " frequency distribution0 ( so p &p

tc =&

e

io oc t

tc =&

r & o oc tc =& : dt p o oc

4:94

" . " / # " " % 4%&(#% " power spectrum So; " F # - . " / " . C - (:39D %% So jsoj&

& & o p o

oc tc =&

oc &

;

4:9;

FIGURE 3.21. CD -" F . - C#D . CD .% . - A%,% C(:39D KKIntroduction to Modern OpticsGG & % 3&%

76

1 +), 4 !"

" % 4%&(% 7 " " . " .>.. - o oc

? o oc &p=tc : *

" " # " F ..

-. " " effective width " . Do &p=tc :

4:99

-" " " " - " F >. - --

" . - . " " coherence time -" /- " #" %% tc (=Dn:

4:92

7 " . " -" Dl; " C4%(5D0 tc

l& : cDl

4:93

" coherence length " # ctc ; " " . `c

l& ; Dl

4:95

7 " - " # " . " " -- # " -"% -"$.

-" (%99 m. " -" 9' . `c ;5 m.% -$. -

(%99 m. " #" (' *1? " " -" # #-N `c 4' .%

3.6 HIGH-COHERENCE INTERFEROMETERS * . - " . - -" . $ " . - " % " . - # . -" >. - " #. - " - .# " " " > " % " -- "

#-

Michelson interferometer % 4%&&% --. #. -" . . # #- - # " " #. - C D #. " % 4%&4% #. - . *( "- " #.

" - . *&% " #$B -" " .$ # " #. - " # . B :' : " ""$ " . - . " . -" - / o: " E$F- "

4%2 1A1$1),)) ),),*)),

77

FIGURE 3.22. -

*"- .% - " -" " " " . --- -%

B . *( # " #. - # E( E(' fbL(

ot d( g;

4:9:

" E$F- " B . *& # " #. - # E& E&' fbL&

ot d& g:

4:2'

L( L& " - # " F #. . " #. - " . # -% " " . " " .. # " #. C " " #. -D " % " " - " L( L& ; d& d( " .# " " .. . -% " # >. -

" . # - # " .-- . C " " -" " -"D " % 4%&&% L& 6 L( " d& 6 d( ; " . -" . % . " -" # " " " E "" L& L( DL; " DL d& d ( t : c

78

1 +), 4 !"

FIGURE 3.23. CD L " " . - " " L% C#D -

#- " L%

" " - C D " " B . *& " . " - " " B . *( " retarded time DL=c: " -- - DL=c " " coherence time t ; " " d d& d( . $ % -- " " " . " DL # *"- . " 9'=9' #. - % 4%&;% " # # " )/ C4%;3D . F " - " %% I

I' ( u~ f; &

4:2(

" I' " intensity " #. # E$F- "- # " #. - f " phase difference # C4%;:D% " KK#-GG " " . F # " - u~

I.> I. ; I.> I.

4:2&

4%3 *!+ ,

79

" I.> I. " .>.. ... - " % " - # " " . C4%2(D # " 9'=9' " E$F- " " # " #. -% - " .. . .. b( b& b;

f bDL: *"- . " 9'=9' #. - # . " " -" ct ; -" # .$ " visibility " DL C% 4%&;#D% $ F coherence length KK" - " . " "" " #-

'%&9%GG " / . KK7" "

" -" " f p; " ""$ " u~ (; " . " . - I ' $ C4%2&DSGG " . - " " - # " "

" -" " " " B " . % -- " " - " -" -- # # " " #. - # " " % " " " " - " " destructive interference

-" - " " C " " -"D " constructive interference " -" - # " C -- " -" # " D% " F " # - " " -" # - absorbing medium - "% -" " " " - #

" " " " -" B% " " " " . "" " > %

3.7 MULTIPASS FABRY±PEROT INTERFEROMETER . . " - --. # . L - " " .- "

- -" C % 4%&;D% -- " . B F (''O " . -" -- # . " " " Fabry±Perot interferometer C+D% ". .-B #- . " -" - # " " " " . # " . % " $ . - " " . - F#$

- # % 7 . " - . " . -" - / o . - E'

. " " F

80

1 +), 4 !"

FIGURE 3.24. -- " .- - B " - . #@+ . %

. " . % " amplitude re¯ection coef®cients " . # r( r& ; -% " E$®eld >- z; . t; # > " . Ez; t E' eibz

ot

;

4:24

" " propagation constant b nk

&pn : l

4:2;

" z$> " " " .- " " F . % . - " C4%24D . -F # . " .. . - " " E$®eld " " . z L; # " > EL E' eibL :

4:29

t& " transmission coef®cient " . " " " E$F- . B t& E' eibL r& E' eibL ; -% " - -" E$F- . " " " . " . " E$F- . . " ; . . . " " " %% E E' t& eibL ( r( r& e&ibL r&( r&& e;ibL :

4:22

" F " # " - . E

E' t& eibL : ( r( r& e&ibL

4:23

81

4%3 *!+ ,

" . I ; # . )/% C4%23D C4%(4D -- -#0 I (& e' cjET j& I'

& R&

(

aR; bL:

4:25

1 " Airy function aR; bL

( ; ( f & bL

4:2:

" coef®cient of ®nesse f

;R (

R&

:

4:3'

> C4%25D I' " total intensity " + N T& jt& j& R r( r& " transmission re¯ection coef®cients $ -% " " .#- . $ . ".-- -- % 4%&9 " + .- F- -" " " % " #" #@+ -- # . - " 9 " -% " " aR; bL (:' " bL mp: " - -- F " FPI resonant frequencies mc ; 4:3( nm &nL " m % !" . " " " + . " - " " > B F # " " " % " -

FIGURE 3.25. " - $ .-? . . #@+ . b -

- l%

82

1 +), 4 !"

FIGURE 3.26. . " " - $ .-? B . #@+ . %

.#- . . C1" TH (:3;D " . % 4%&2% + / " " .-? B . # # . " .-? B . " -- - .".% . " " % 4%&2%

3.8 LOW-COHERENCE INTERFEROMETRY -" " . .

" "" " " - " . " " - " -" " light-emitting diode C!)D% .. " - !) - > " - % " . " - " .. ." # - " . - - " " - " -" " " -"N 4%9% " # . "" " . " " coherence length " -" " " ? " .% " " *"- . 4%2 . " " -" B . *( *& - -- " " " .#% " - /. "

#- " DL < `c ;

4:3&

" L( L& "

- " - B *( *& -N DL L( L& N `c " source coherence length% " " F- - KK " #-. " - GG - $ " .$ %

4%5 !7$1),)) ),),*),

83

" - " "

" --. #-

Michelson interferometer " # # C- "D C% 4%&3D% " L( L& `c ; "

# " " " . *& .-- C -" " -"D% " " " # 4%2 " " . # # "% 1

- *& " " L( L& ; " -- # " " - " " " -" " C % 4%&5D% " " -" 9' m. " ##- . " " " ." " 9 m. # # -

" *& " " % L( " . C " 9 m.D "

" L( - .% L( ( . " /- strain resolution 9 me C. D% 7 "-- - " low-coherence interferometry - # . . -> F " .# F#

#@ + *"- .% 7 $

FIGURE 3.27. ". -- " -. " -

*"- . > # - $ " -" %

84

1 +), 4 !"

FIGURE 3.28. )> - - $ " . . -

"$ %

- $ " .% - -" -? coherence wavepacket -" `c " " - - "% " " #-

*"- . - " " p; H

" -" # # " #. -% " #. " # B . " . .# # " #. - " " p( p& ; "

" C % 4%&5D% " "

- C " `c D " -- # # "

" % -- " -- - - " " - " . %% L( L& : " " . *( C%% L( D " . - *& " " - L& "" .>.. #% .. L& /

/ % #- " - $ " . " . . % " # . -" # Fizeau interferometer - " charge coupled detector CD " " " .# #.% 7 " " . # " " % 4%&:% 1 " " " " p p# ; " - " " " *"- .% 7 " " " - .

. - -- ".%

" " " " . DL; > " " -" " -" `c : " " # p( p& ; #

4%5 !7$1),)) ),),*),

85

p#( p#& ; "" DL; ." " " " " " ` ; "" - #

# " # " ? .% % 4%&:# " " " " " " " ? . " % ? . .- #@+ . > " " - " " . - " % % 4%&:# " " ? . - H " . " " DL; # *& *( " *"- .% /-

# # " " " p#& "

FIGURE 3.29. CD ! " . ? - -$. ..% C#D -- ? . " $

%

86

1 +), 4 !"

B . " " ? . #/- . #- " " " H - " p#( " - .% " " . "

- " ? . - " - " " " *"- . " # >.- - " - - " " - . / " " %

3.9 RADIATION COUPLING BETWEEN OPTICAL FIBERS "-- " 9 -" - - -

- F# " -- # . " -- # " "

- F#% " " "" > " " - .- " -" # " " # F # - B " # # " ""$ - $> C% 4%4'D% -" " " " -" F " " "

- F# . .". / " > $-- evanescent E$®eld

> # " " - % - "

F# - " E$F- - - -" . " % "

KK -GG " "

- F# # " - "

- # >" # " " -

-% " -- #

# . " 9 " >" -" #

F# - " " .# - direction couplers% 7" . " #- " " # " E$F- " -" # " " "

- F#

FIGURE 3.30. F. -" # - B " @- $ %

4%: , +!A )7)) + ! ),

87

C% 4%4(D% 7 # " - -" #

F# - / % 7 "

- . " . -" " z$ F " "

- F#% 7 " )/% C4%2D " " E$F- " -" # > " . Ez; t E'; 'eibz

ot

::

4:34

" # " . E aeibz ;

4:3;

. % 7 - ? " " / # " " " - " . - - / " # " >- " E$F- - -

- F# %% dE ibE: dz

4:39

" / " -

- F# " - " > # " E$F- z " "%

FIGURE 3.31. E$F- # " - -

- F# " " F# # " F- " -" # " " F

- F# %

88

1 +), 4 !"

# - " " "

- F# # " F- - " " >"

- % 7 " " . - -- # coupling term )/% C4%39D "

- F# "

- " E$F- " "#

- F# %% dE( ib( E( iC(& E& dz dE& iC&( E( ib& E& ; dz

4:32 4:33

" C(& C&( " coupling coef®cients% " F " " " " " E$F- .

- F# " " "

- F# C! (:52D% 7 . " > " E$F- " F

- F# # " > E( a( eib( z

4:35

E& a& eib& z ;

4:3:

" " " amplitude coef®cients a( a&

z: # )/% C4%35D C4%3:D " )/% C4%32D C4%33D - - F$ - / " amplitude coef®cients " . da( z iC(& a& zeiDbz dz da& z iC&( a( ze iDbz ; dz

4:5' 4:5(

" " " phase mismatch Db b&

b( ;

4:5&

" " " a(

- a& % . " " . - " -" " F

- F# a( ' " -" "

- F# " - a& ' '; " " )/% C4%5'D C4%5(D # - # . - " . a( z p( eig( z

4:54

89

4%: , +!A )7)) + ! ),

a& z p& eig& z :

4:5;

" - )/% C4%5'D C4%5(D - " - ig( p( eig( z iC(& p& eig& Dbz

4:59

ig& p& eig& z iC&( p( eig(

4:52

Dbz

:

p( p& # z; " g& g(

Db:

4:53

". )/% C4%59D # C4%52D # " - g& g( C(& C&( :

4:55

.# )/% C4%53D " C4%55D - / / g( ; " - s & Db Db C& ; 4:5: g( & & " C& C(& C&( :

4::'

s & Db C& ; g &

4::(

F

" " amplitude coef®cients " -" "

- F# " . a& z e

iDbz=&

fp& eigz q& e

igz

g:

4::&

" # "

- F# %% a& ' '; / " q& p& ; a& z &ip& e

iDbz=&

& gz:

4::4

" > C4%5(D - " . - F " -" " F

- F#0 &p iDb gz : 4::; a( z & eiDbz=& g gz C&( &

90

1 +), 4 !"

" # "

- F# %% a( ' a' ; " C4%:;D - " - 0 a'

&p& g ; C&(

4::9

"" - " F- > " . - F " -" " F

- F#0 iDb iDbz=& gz gz 4::2 a( z a' e & iC a 4::3 a& z &( ' e iDbz=& & gz: g "

-

- " / " F- " # & Db & & gz 4::5 P( z P( ' gz &g P& z P( '

jC(& j& & gz: g&

4:::

phase-matched b( b& b;

4:(''

Db ': )/ C4%:5D C4%::D #/- . - " . P( z P( ' & Cz

4:('(

P& z P( ' & Cz:

4:('&

- " - >" " - # "

- F# % 4%4& " exchange length z> p=&C:

4:('4

#- " / KK" -- "

- >" # " F#S 7" "

" " -" "

- F# " .SU " - " :'

" # " driving ®eld " F

- F# " driven ®eld "

- F#% " > # " i )/% C4%:3D C i eip=& D " . - F " E$F- "

- F#% " :' " . " " F- "

4%('

, AA A, A ,)!)

91

FIGURE 3.32. !" >" # -

- F#% ! " $ " # " E$F- "

- F# " >"%

F

- F# # " F- #- "

- F# -- # (5' " " " - F- C:' - :' D " - % " " "$." F- # " F

- F# - -- " F- "

- F#%

3.10 BRAGG GRATING REFLECTION " >. - . - " -" . " > % " Bragg gratings # " $ " - # " -" "

92

1 +), 4 !"

. " .- " # # " . ! "

V$ . - - -% 7 "-- " ; " - - . # - . " 2 " .

- F# . - . % " " # # B -" " " C " ."D F% " B - . $ # " "

-" " - . " -" # " % 7" " . - . " . -"

" z$ " " "" " > " - % 4%44 # # " - nz n' Dn &pz;

4:(';

" n' " . - " > Dn " . - " > . - p p=L;

4:('9

" L " " > . - % > " -" " . ". # Ez; t Ezeiot ;

4:('2

" o " - / C4%('2D " - . / " .. C4%:D " $. . " Helmholtz wave equation0 d& Ez dz&

o& Ez: u&

4:('3

FIGURE 3.33. >- " > " F# %

4%('

93

, AA A, A ,)!)

" C4%('D C4%(&D # C4%(';D n; " / d& Ez dz&

fn' Dn &pzg& k& Ez:

4:('5

" # " > .-- CHF Dn=n' (' & D > " / " " - # C4%('5D

" .

- Dn& ; & &pz e&ipz e

&ipz

4:(':

&ipz

4:(('

d& Ez dz&

b& xfe&ipz e

gEz;

" " " propagation constant b n' k

4:(((

x k& n' Dn:

4:((&

" coupling factor

7 . - - C4%(('D " . Ez a ze

ipz

a# zeipz ;

4:((4

" a z " KK GG E$F- . - a# z " KK#GG E$F- . -% " - #

C4%(('DN . " " e ipz -- - $ - / " . d& a dz&

&ip

da b& dz

p& a

xa# ':

4:((;

xa ':

4:((9

-- . " " eipz - d& a # da &ip # b& dz& dz

p& a#

* " . " . -#- C) (::3D - F$ - - /$ 0 &ip

da# b& dz

p& a#

xa '

4:((2

94

1 +), 4 !"

&ip

da dz

b&

p& a xa# '

4:((3

C4%((2D > a z . a# z z$

# " $ - / d& a # dz&

k& a# ';

4:((5

"" >-- . a# z: " . -F #- # " grating coupling coef®cient0 k&

x& ;p&

b&

p& &

;p&

:

4:((:

" $ - / - . C4%((5D # a z: # " k real - " . a# z b( ekz b& e

kz

:

4:(&'

. " -- . " z ';

" " " # - " # C% 4%4;D% " - # -- " . a# LA ' P ' P' ; " LA " -" " P' " - "

- " -" P z " " % " F # " C4%(&'D - b&

b( e&kLA :

4:(&(

# C4%(&'D - " > " # -" . - a# z &b( ekLA "fkz

LA g;

4:(&&

# " / C4%((2D > " -" . -0 a z

&b( ekLA & b x

p& "fkz

LA g &ipk "fkz

LA g: 4:(&4

4%('

95

, AA A, A ,)!)

FIGURE 3.34. # -" E$F- . - - F# %

" C4%(;D " # -. b( . "

- P' ; "

- " # " " 0 P# '

b&

P' x& "& fkLA g

p& & "& fkLA g ;p& k& "& fkLA g

:

4:(&;

" re¯ectivity " RkLA P# '=P' ;

4:(&9

# " . RkLA "

b&

x&

p& &

"& fkLA g &

" fkLA g

;p& k& x&

&

" fkLA g

#:

4:(&2

. C4%((:D " k - x& b&

p& & :

4:(&3

96

1 +), 4 !"

" - .-- -" -. . " Bragg wavelength l ; " -" " phase-matched condition F b p;

&pn' =l p=L:

4:(&5

7 " " phase-matched condition - " . > " Bragg wavelength %% l &n' L:

4:(&:

" "$."

- )/% C4%((:D " . k&

x& ; ;p&

4:(4'

" grating coupling coef®cient " . - . k

pDn : l

4:(4(

" . . C4%(&2D " B " R.> kLA "& fkLA g;

4:(4&

" kLA . " grating strength% " " B " " . % 4%49 " B . % 4%42% " B . # . . C4%(&2D% - " " B . # C4%(4&D " -"% .-- -$

FIGURE 3.35. L " B F# " " " " %

4%('

97

, AA A, A ,)!)

FIGURE 3.36. # B - " "% . ) % KK# A GG J. Lightwave Technology 15 (&33@(&53 # )))%

. . " -" > C4%(&2D " k - # " .% - -. . " -" x& b& p& & ; C4%((:D k # . .% 7 "$ s b& p& & x& ; kW ik ;p& ;p&

4:(44

" B . " -" # # " > RkWLA "

b&

x&

p& &

& fkWLA g &

fkWLA g

;p& kW& x&

&

fkWLA g

#:

4:(4;

B . C. -$ -D ($..$- . " " kLA (:2; C) (::3D % 4%43% / " - " B - " -" " -- " " B % " F -- RkWLA " kLA p:

4:(49

98

1 +), 4 !"

FIGURE 3.37. . " - > .- B % . ) % KK# A GG J. Lightwave Technology 15 (&33@(&53 # )))%

C4%('9D C4%((&D " C4%(44D ? " " $ -" " F -- b

&pn' ; l Dl

4:(42

" Dl " -" -. . " -" " -- C% 4%45D )/% C4%(49D

>. # " > s & & pLA Dl Dn p; 4:(43 L l &n' . Dl l ; " . #- HF % " - # " half-spectral width " B . s & & L Dn : 4:(45 Dl l LA &n' 7 " " " " - " .-- . - " > . >% C4%(4(D C4%(4&D - " > Dn LA : 4:(4: R.> kLA "& p L &n'

4%('

, AA A, A ,)!)

99

FIGURE 3.38. # B . " - . . " " .%

7 # " - B / " # - . " # " > . - " - # - . " . >% 7 " $ . # #- " # " -- ""$B % . . " - " B C#- et al. (::9D LA & : 4:(;' R.> l ; LA " ':5pDn l >. - "-- . "

- F# "" " -- . #-0 n' (:9; Dn (' ; ; L ':9(3 m. LA 9 ..% " l &n' L (:99 m. Dn LA 95:5% R.> "& p &n' L s & & L Dn ':(25 .: Dl l LA &n'

1 +),

;

!"

4.1 INTRODUCTION " " # " -" " -" " . #- F#

- . % - -" # " " broadband and incoherent " " narrowband and coherent% -" #-# -- " F $ "- . - # # " % 7 "- . "0 .-- / --

# "

- - .#% " # " . " $ "" - " #- # #- .-- ? "" - % " .

. > #- . - C D .%

4.2 LIGHT GENERATION AND GAIN MEDIA )- . -" " F . # " - . > . - " .% " - > # ".- -- - " " % " " -- - . " - .

" .% " " . - C- -D % " .- # "-.@ - - - # - #-" # - " % 7" F - .# " - " ? - . - . - % * 100

101

;%& !A1 A)), A *)

" - -- # " / F

? . > " # - " . "

" . "" " " " . C% ;%(D% " " -- " -" " KK . %GG 7 " 4 " -" " " -" # # # - . # " . " " . C% 4%5D% " . . # . # -# ) " /. " . " " /-#. / " > " # -" .% " " . KK.- . GG " " . #- " -% " . laser " .0 KK-" . -F # .- . %GG Stimulated emission " > . .. F- "

/ " % " induces " . " > -- # " - " " . " " - " .- " C% ;%&D% . " - . " " " .- " " " . frequency direction, phase " " % 7" . .- . . " -

. -F " -" . . > " "" " " - " C% ;%4D% "

- "

- # Np Nq - " " " > " population inversion n Np

Nq > ';

;:(

" " n " inverted population density " % . - . C%% . - --D% --

- / " . -F " F-% .. "" -" " " . KKGG KKGG .. ""- $/-#. " F % "./-#. " .- .- " " . " - C % ;%4D% ".- /-#. " "

- " "" - " # # " Boltzmann distribution Np Nq e

DU=kT

;

;:&

102

1 +), ; !"

FIGURE 4.1. CD . -" . " . - "

% C#D )- " - $ . - - "

- - F- -- " . " > ". " - / F ? ".%

;%& !A1 A)), A *)

103

FIGURE 4.2. " . 0 CD # C#D . CD .- . %

" DU Up Uq " # " "" - k (:45'3 (' &4 6< ( " Boltzmann constant T " . <- C Nq zndn Np zndn " number of atoms per unit volume " q p - " " / n%

104

1 +), ; !"

(a)

Nm /N 1

Thermal Equilibrium and Boltzmann Distribution of States

1.0 T

A

T

B

TA 0 1

(b)

3 4 5 6 2 Quantum State <m>

TB

Nm /N 1 1.0

Non-Equilibrium Population Inversion of States Population Inversion Created Between <3> and <2>

0 1

2

3

4 5 6

Quantum State <m> FIGURE 4.3. CD ".- /-#. " -?. # % C#D $ /-#. "

- %

" " # " .- . # " # " " spectral photon density Fn " F- DFndn Np Bpq Inzndn

Nq Bqp Inzndn

;:4

- " Bpq Bqp ;

;:;

Bpq Bqp b% -- " C;%4D # DFndn nbInzndn;

;:9

" " spectral photon density - # - " spectral intensity " #. # " - C-" " (::(D0 In Fnhnc:

;:2

;%& !A1 A)), A *)

105

FIGURE 4.4. CD

- # " " " - % C#D )> - -" " " .. ".- /-#. . -F C> - "D -" "

- %

" 4 hn " photon energy% . % ;%; -- " " .- " " #. / n " " " Dz " .. DIn DFnhncDz;

;:3

"" C;%3D DIn nbInhnzncDz:

;:5

" spectral gain coef®cient C -"D " .. gn nbhnznc;

;::

106

1 +), ; !"

" > C;%:D . / " . dIn=dz gnIn:

;:('

" - " / > - " " F-% In; z In; ' > gnz;

;:((

" % ;%;% gain medium # . - . -- " "" " ""

-

# % " "

- C% ;%;D% " " # - *. # -" . B" -.

- " # - % 4%4% " -- % -- # # -

" B" -. # # # - " $ 4 " # - "" . " - " # # C% ;%9D% # " High Reflectivity End Mirror

Output Mirror

Laser Beam

Ruby Crystal Laser Medium

Helical Flashlamp

Ruby Crystal Excited by Flashlamp

Rapid Lattice Relaxation

Flashlamp Light

Band of Transitions Pumped by Flashlamp

Laser State Laser Beam

Ground State

Flashlamp Photons

FIGURE 4.5. ". -- # - . F %

;%4 ,@+), L ! ),

107

" " - " # - # . " > " -

- # " " - % -- -" " " " . ". " F - " . F- # ?#- " $

- " # > "

- % * - " - " ." - " " "-

- " - " - C. (:52D% " > population inversion %% Cn > 'D " .$ " F- # F

-% " # -- -" "

/

. " - -- # . -F " - >" " . -F # #- " # "% " - gain medium - " . " --- " "

- "

" - -" #. C% ;%2D% -- " . - - " " .. Fabry±Perot cavity $ . " 4% " -" " .. "

. - - -" " % " -"

" " " .. " -- # . -F " B # " " " .. . -F % " . . " -" #-- F " -% 7 "-- " " " > % " - # " " " . . -> . . - " . - " " Fabry±Perot cavity C+D F % " " -

-- # - ;%3%

4.3 FABRY±PEROT CAVITY LASERS - # . " " " - -- "

" - . " > # " -" - " " " .. . " - " B . " - % " -B " + . " -G threshold condition " -

" #. " . - . - " . .. " + C% ;%2D% ""- B

- . " . - B F r(

" .. " z ' - B -

108

1 +), ; !"

FIGURE 4.6. #@+ - ". -- .- - B %

. " . - B F r& " " " .. z L% 7 . monochromatic plane wave " " x y

" z$ % " " " " -" - E$F-% . " . - " 4%& " I e' cE& ;

;:(&

"" . " " " E$F- > . F c . " E$®eld gain coef®cient " . )/% C;%((D C;%(&D - " cn gn=&:

;:(4

109

;%4 ,@+), L ! ),

7 " complex propagation constanta # " " " "

- > # " E$F- / n

" " " .. an bn icn:

;:(;

. " " E$F- . - " - z ' E' e iot " z L En; L E' eiaL

ot

:

;:(9

" . - e iot .. " - F - % " -" " " " .. -- B -- .% " " -" E$F- / CnD " . " " " . # r& E' eiaL ;

En; Lt( (

;:(2

. - " # " . % ;%2% "

" -" E$F- / CnD " B En; Lr( r& E' eiaL :

;:(3

" " - . " " " " .. B " " . " " " " .. " . % " " " " . # En; Lt& (

r& r( r& E' e4iaL :

;:(5

" -- - . . . -- " . E$F- . " . E$F- / n " . En; L (

r& E' eiaL r( r& E' e4iaL r( r& & E' e9iaL . . . :

;:(:

" F " # " . - . En; L (

r( r& E' e&iaL < (%

r&

(

E' eianL ; r( r& E' e&ianL

;:&'

110

1 +), ; !"

" " - -- " . " " " -- B output mirror% - . )/% C;%&'D )/% C;%(&D " . -# " . In I' T

zn f( Gng&

( ; ;Gn & fbnLg ( f( Gng&

;:&(

" In " spectral intensity C - D 7. & 1? ( I' " - -- T " . F " -- B . zn " line pro®le function " - Gn " double pass gain # Gn r( r& > &gnL;

;:&&

bn "

F # )/% C4%('D %% bn &pnn=c:

;:&4

- " line pro®le function zn > " ##-

.- . / n - " " - / n' ; % ;%3 zndn " ##- . # " / - n; dn% " " .. " " #@+ - " # .-$ . " % ;%5% " - F- " -

" .# - . # " #@+ % " " - -

"

FIGURE 4.7. ! F- " - %

111

;%4 ,@+), L ! ),

FIGURE 4.8. . -F . . A . - - H #- " - "" -% " - .

# . . . " -

" "" - - --

"% " " KK GG - C#D CD " " - -" C#D ." - " CD% . KKLasersGG % )% .

(:52 % ;;2%

> # " gain-modi®ed line pro®le " " " > C;%&(D% " zW n; Gn

zn ; f( Gng&

;:&;

" gain curve " .. " " . - - n

" " line center frequency n' ; " - Gn " - " - zW n; Gn % - " "-.@ - " # / ." - " ':( .% . " . - # > 9' .% " " C;%&(D ( On; G ; ;Gn & fbnLg ( f( Gng&

;:&9

. " gain-modi®ed Airy function

" #@+ .# - - % ;%5% 7 " 4 % 4%&3 " normalized Airy function B . # + " KK#GG ..%

112

1 +), ; !"

" # .. " frequency separation " #@ + . " % 4%&3 # " - Dn

c : &nL

;:&2

" " -"- " .. # F

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114

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134

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135

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136

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#-% # # B F# C" -" (9;9 . ;' . -"D " . + # *"@T" $ . " " +!% . " . " " B -" "" . #

. -?% " > .- . ".$ -- % 3%&&%

FIGURE 7.22. ". -- > .- . - .- -> F# #@+ . # - A% #- #@+ F- - "" F# #@+ # " " . - -- - " . . - " % . 1 +%6% , %6% 6 % % T" !% % C(::3D KK.- .$ . * 7-" *-$

-> #$#@+ " ! $ " GG (&" % % - # 7--.#%

3%2 )*+), ,) *+) , ), + ),

295

" " -" " -" B . A # (%& . C%% (9;9 .& =':& .D #- #@+ F- - " " - " F + # . . " -" A% " .#- " *"@T" . C*TD - "

# " - B . " A . + "

. # # " " % " # #

. " C7+D " 4 " . " F % 3%&4% " .#- *T 7+ S( S& % $ " " 7+ B . " F A S&

+ - " " F 7+ B . " ASW( + % - # ':( e 1? '9 " # " #- " ( 1? #" "- " . # (':2 . ( % et al. C(::5D - .#- *T )+ " F . -. A . "N % 3%&;% " ! 544%9 .

FIGURE 7.23. " > - " > .- "/ -- % 3%&&% . 1 +%6% , %6% 6 % % T" !% % C(::3D KK.- .$ . * 7-" *-$

-> #$#@+ " ! $ " GG (&" % % - # 7--.#%

296

1 +), 3 # .

FIGURE 7.24. "# A@)+ . " .#- *"@T" . " )+ ." A " A% . !% % ! # ,# % % 6% !% " % KK.- -. . "$-" - $F $- " F# GG Smart Materials and Structures @ - # 7 (::5 (5:@(:5% " . . " +" +#-" !%

" &9 . -" " *T " " " $ % " - - A " . . A " )+ # .>.? " - - # " A% " . # .- - "$ " . " # (2:& - " . # &':4 m.% " - " " " . #- . . " . -. " . % " . -. # # ':'; . 1? ':9 "- -. . # 2:( . 1? ':9 %

7.6.2 Combinations of FBGs " A .# "/ " #

" .- .. . % " . - - # "- A " - " " "- ."- C% 3%&9D% " " A " # > # " . " "- " - > " . $ " C! (::3D% >. - " - split spectrum . A " -- # - #.

3%2 )*+), ,) *+) , ), + ),

297

FIGURE 7.25. CD . $ . A "" "- " A $ - " - - . % C#D #-$ B . . " A " -- # " CD% . ! %!% 6%% C(::3D KK. - *" * . >- .- - $# $A GG SPIE Smart Sensing, Processing and Instrumentation 3042 &43@&;2%

" % 3%&9#% " " " " " ... #- > - " -" " A " (' me " & me ." # " " '%'& . A% " - " A " -"- ." # -% - " . - "/ - #- $ . A % 1 " -- # - $"- A C D . . "

" - # " " .# " " .-% 7 " 3%; "

- /- A -- " B # C7" (::2D% " et al. C(::9#D ? " " -" " #/ - "

298

1 +), 3 # .

FIGURE 7.26. - " B . . A #H %

. " " " -" " B $ . C% 3%&2D% " . " .> / C3%9:D " #- " # Dl SWe SWa De ; 3:23 l Se Sa DT " Dl l - " - " " -" " A B . " . SWe SaW "

. " A - $ - "- Se Sa "

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SWe '; Se (:(3 ('

4

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299

# "

- F# " # .# " ,+ . - . - " H

- C F#D % 3%&3% " . .- " " " resin eye " . " -

- F# #- " . " /- % " " - # "

F# " H - " . " " - " # - -% 3%&5 - " - # . A " .#

- " - - F# " ,+ " .- C % 3%&5#D% - " "/

.H #% ).#

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300

1 +), 3 # .

FIGURE 7.28. CD )> .- # " A . # .# " " ,+ . .- " - " - - - % C#D F A " ,+ - %

. " # # " A " ""- #

- F# " " " ,+ " " # % et al. C(::5D

" A . -? .

- F# - # .-$ - . . % 1 " " " F- " -? $.

- F# # " S$.> # --$ - - % et al. C(::3D " " " " "/ . " A " + -? $.

F# C

- F# " KK-GG ".- " " -- % 9%5D% " # '%;5 . " -" " " - > C% 3%&:D% . " - % 3%4'%

3%2 )*+), ,) *+) , ), + ),

301

FIGURE 7.29. " . . A +

-? $.

- F#% . * *% 1. <% ? % 7 % ." ,% C(::3D KK.- *. . + # AGG (&" - - # 7--.# (3'@(34%

" " #- .- - . . " &' me & -% . 3%; " " . # #-. " A - . . " F " - ." % " # . # " " . . - # " " -" " A % -" " " . -> . - -? $.

- F# "/ " - "

- F# " - " # . " F# " .. -- - % " " "

" - / - " " % - / " "

# 6. et al. C(::2D C% 3%4(D " " " . $ .>.. (3 me ( ..

&9'' me (&' " " - " - . " A - #-.% " F " " "- . - ..N " " " # - " . " " - # "" N " " "

302

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FIGURE 7.30. CD L " -" " . CD C#D " #-$ B . A +

- F#% . *% *% 1. <% ? % 7 % ." ,% (::3 KK.- *. . + # AKK (&" $ - - # 7--.# (3'@(34%

" - " .# . . # " - " #H - $. - % " . > ." .- - . . " -" " $

". $

% V et al. C(::;D " . " #- )!)

59' (4'' .

3%2 )*+), ,) *+) , ), + ),

303

FIGURE 7.31. ". -- # F# " - .

- F#%

--. -- A " .- -" 5;5 (&:5 . C % 3%4&D% " #/ " B -" "

- . % 3%44% "

.> / " " .

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. $ . .

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304

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FIGURE 7.33. 7-" " CD . C#D " -- A " . -- % 3%4&% . V et al% KK. # . -$-" F# GG Electronics Letters 30C(4D ('59@('53% " . . )) +#-" !%

" .> . " . " - (' me 9 " .. 0 2'' me 9' % " "

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# A -" " -" C "

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.? (4'' .D%

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305

7.6.3 Long-period gratings "

- " - - /.

C%% - .D .# A " $-- longperiod gratings C!+AD " # " . .-$ - . . % - $ " " > "

- F# >- . - " - " # " . " - . CL et al. (::2D% "$." -" . " . . - " $

- . -" # " - lm n

n. L;

3:2:

" lm " -" " " "" -" - " ?."-- .. - . m "- n nm " " . " ?."-- .. - . m -% !- L " - " > . - % ! A - $ # # > #- -$.

- F# >- L C&;9 .D - % "

/ " % >. - "

!+A # > " .

# "- . A " ... -" - - .% " . . " " !+A B # -" AN " .$ . - .# - " " # . # - - . C " et al. (::3DN % 3%4;% 7" " !+A #H " . " " " > -" " % ! Dl( Dl& " .- " " $ # " !+A l( l& l( > l& - " . % " " - . .> / C3%9:D " # Ke;( KT;( De Dl( ; 3:3' Ke;& KT;& DT Dl& " Ke;j KT;j j ( &D " -"$ -"$. -. " K$.> " !+A% " et al. C(::3D # !+A hydrogen-loaded *$&5

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306

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FIGURE 7.34. *- - " . . - $ -$.

- F#% -- . - $ " . "%

" l( (2'3:: . l& (44&:: . " . -"$ -"$. F " !+A K$.> Ke;( (:25 . me Ke;& ':&5 . me

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KT;& ;9:& . ( : " " " # C. "D (2'3%: . C-D (44&%: . C/D " " . $ % 3%49% - !+A -$ $ >. - "" " % 3%42 X " et al. (::3Y% " " -"$ F " (2'3%: . " # / . % " - ... #- . " # 4' me ':2 - # " " % 3%43 . " " .. - . % 3%3 " et al. C(::3#D #- . -- . $

3%2 )*+), ,) *+) , ), + ),

307

FIGURE 7.35. L " -" . " C (2'3 (44&%: .D " . - $ % . " et al% C(::3D KK.-$ . ! $+ AGG SPIE 3042%

FIGURE 7.36. 7-"$ F " . " (2'3%: . . " !+A% . " et al% C(::3D KK.- . ! $+ AGG SPIE 3042%

308

1 +), 3 # .

FIGURE 7.37. CD . " . !+A% C#D .. - - - " . " " . CD% . " et al% C(::3D KK.- . ! $+ AGG SPIE 3042%

. . F . !+A # " . # 9'% + et al. C(::2#D " F # $ -" " . !+A A

" . % " "

. " .> /

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309

-" " N C!+A AD% " . -. " . " K$.> Ke;!+A ':9 . me Ke;

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# % 3%45 " . " - A -- . - " . " " !+A% " A -" l ( (&:4 . l & (4&( . - " !+A -" l!+A (4'2 .% " . " " - B . " A R( R& - . " " " -" " !+A " "- " -" ".- B " " A " . % "

.-- R( .-- R& # " " l!+A - " " l ( l & % " . - R( - R& # " " l!+A ." - " " " l ( l & % " ".-- -- % 3%45% " . -# # .- - . " " " A -" " " " normalized re¯ectance ratio p p R R FR( ; R& p( p& : R( R&

3:3&

" FR( ; R& l & " . "- 45 % 3%4: "- " .

- 9:' me % 3%4:#% " . -# "

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310

1 +), 3 # .

FIGURE 7.38. CD > .- . . $ . .. .# !+A A% - " -- " " A - . - " - " " !+A .$ .% 7" .# " -" " " . " . . % C#D . " " !+A " > $ .- . -- CD% . + 1%6% 7--. A%*% < %% +?? 6%,% L %*% KK1# F# [- F# =. . GG IEEE Phot. Tech. Lett. 8 (&&4 # (::2 )))N and C#D . < %% *% % + 1%6% ! - *%*% <

<%+% %A% +. *% % #- )%6% KK# A GG J Lightwave Technology 15 (;;&@ (;24 # (::3 )))%

3%2 )*+), ,) *+) , ), + ),

311

FIGURE 7.39. CD L " " B X > )/% C3%3&DY # " A A -" " > .- . -- % 3%45% C#D L " . B X > )/% C3%3&DY # " A A -" " > .- . -- % 3%45% . + 1%6% 7--. A%*% < %% +?? 6%,% L %*% KK1# # A=! + # A [. . GG Photon Tech Lett 8 (&&4@(&&9 # (::2 )))%

7.6.4 Use of Brillouin scattering 2%2 -"

-

- F# - .-- " " -- -- % " - .". - " " -" . phonons C/? D "

- F#% " > " # - . -F " " "$ stimulated Brillouin scattering C D% -

pump C-D radiation / n . counter

312

1 +), 3 # .

FIGURE 7.40. ". -- $- > .- -- $ "

- F#% )>

- F# -- " " "

. - " " " # -"%

propagating $ #. probe radiation / n # C% 3%;'D " --

- n .

n # n :

3:34

1 n " -- / " # )/% C2%9D n

&nV : l

V " - n " F# > l " -" " . -% F " " -- / " - " . "

- F#% < C(::2D " " -$

" # - .- -> A /$# . F- -

- F#% - " " " B . " A -" -- . " - -- " . "

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313

- F# / % "

. .> / C3%9:D " .. # Ke; KT; De Dn ; 3:3; Ke; A KT; A DT Dl A " KT; Ke; " -- / " F " . - KT; A Ke; A " A -" " F% # " K$.> / C3%3;D - " " " . # .% " -$. 0 A -

(4(: . " . # -% " A (99' . # " # #

- . -? C % 3%;(D% " A 9' .

- F# - % " " - . - (''

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FIGURE 7.41. )> .- . . $ . .. # .# A .- -- % " - > # 0 A - " . # (99' . !)% . *% % < %% C(::2#D KK.- *. . # A -- GG SPIE 2838 ((;@(&4%

314

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FIGURE 7.42. / # " 0 A - " > .- -- % 3%;( " .

- F# CD " # " 23:8 C#D " " -"

- F# " 60:5 % . *% % < %% C(::2#D KK.- *.

. # A -- GG SPIE 2838 ((;@(&4%

- " " # " " -"

- F# " # " &4:5 % " - # " . - /% 1 " -" . " 2':9 # 9'$ *1? / " # # " % " " -- / " " A -" " " . % 3%;4% " -- / " # # (4%: . . . " " " A -" " % % 3%;; " . " -- A "/ # 9%2

3%2 )*+), ,) *+) , ), + ),

315

FIGURE 7.43. L # " A -" " -- / " " . % . *% % < %% C(::2#D KK.- *.

. # A -- GG SPIE 2838 ((;@(&4%

FIGURE 7.44. L # " A -" " -- / " " % . *% % < %% C(::2#D KK.- *.

. # A -- GG SPIE 2838 ((;@(&4%

316

1 +), 3 # .

Table 7.1 . F A -- . A --

1

10:2 0:1 . 1:21 0:01 *1?

1

1:181 0:005 . me 55:1 0:4 <1? me 1

1

#% " . " "/ #- 3%( C < (::2D% " " " " . " K$.> ? " .> # "

"/ .- - - " . % 3%;9 - " . " " . " "- " .

>.- -- % -" " "

" " . " . -> ? " . - ".- "

. #- > . / # . -$ . %

7.7 TEMPERATURE-INDEPENDENT STRAIN SENSORS

- " " # .# " " " -- # " ".- > F " " .- " " F#

.#

. $ F#

" .% " - " - . $ V et al. C(::9D - " # "

-

" A " " #" " "

-- B C% 3%;2D% " . " B " #" " " C1 et al. (::;D% Differential etching " "

- F# C+. et al. (::9#D "" - " " A "

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3%3 )*+), ,)$)+)) , ),

317

FIGURE 7.45. CD . . " A " . -- % 3%;(% C#D A -" " -- / " " . CD% CD -- . . C#D% . *% % < %% C(::2#D KK.- *. . # A -- GG SPIE 2838 ((;@(&4%

318

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FIGURE 7.46. ". -- " " " B . " A " #H %

FIGURE 7.47. > .- . " . $ F#

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% 3%;5 " # # . "- - - % 3%;5#% " - # # ;:; me (O " -.. % Prechirping " # . . # .. % - " - " A -" " N /- -#- . # - - % V et al. C(::;D " . ".-- . # #

. A % " . - -- % 3%;:% " . .- "

"

# 1 C(:35D -. . . " ..% V

3%3 )*+), ,)$)+)) , ),

319

FIGURE 7.48. CD , " " - C " . " % 3%;3D . " -

- " " A % C#D L " "

- % . V et al% KK. $ $ " A - #GG Electronics Letters 31C('D 5&4@5&9 " . )) +#-" !%

et al. C(::3D

. A "

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.

320

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" # - >% . V *%$A% ".#- 6%$!% , !% 6%+% KK- # AGG Proc. SPIE 2292 ;'3@;(40 # ! V +- ,%+% C)%D%

e% . " A - > " . " . DT " " -" l e; T

l e; T Se e ST DT

Se f eg

ST DT &Se e;

--

- " " " . % " F. % 3%9' " " # # " . &5 % - - $ # - - " > - F- " # " . . $ C " et al. (::3#D% " -"@. $ -"@ F !+A " L (22 m. -" L 4:29 . . # &:9 . ( &:3 . me ( -N % 3%9(% " thermal cross-sensitivity " !+A " . &9 (&9 " % " - % 3%9& " " - " . B % -" " !+A # " -- > . -$ . CL et al. (::2D " - . % " - " ""- #- -$ " - "

3%3 )*+), ,)$)+)) , ),

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- . % . V *%$A% ".#- 6%$!% , !% 6%+% KK- # A$ GG Proc. SPIE 2292 ;'3@;(40 # ! V +- ,%+% C)%D%

"

- F# . % " -. - - " #-. "

" / % 1 " .- " . . !+A . F- -" .- -> - " % "

" -

. $ " " - # . . #- F#

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% ---- et al. C(::9D . " " - ".-

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322

1 +), 3 # .

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3%5 , @)*+), ,) ,$)L

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FIGURE 7.52. . " - . $ !+A " . " C&9 125 D " - X C' mED C9'' mED C('' mEDY% . " et al% C(::3#D KK. $ ! $+ A , > GG SPIE 3042 &9%

FIGURE 7.53. ". . $ )+ # " " ".- > F ." " " " % . ---- % - A% C(::4D KK7" !" . *. #$ GG Optics Letters 18 35@5'%

7.8 STRAIN±TEMPERATURE CROSS-SENSITIVITY . - . " " # . -- " # " " $

". $

F "

- " . % " . - - . - " #

324

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" - . - ." . F-% " - # )/% C3%;D # - -- # " - . " - - > % - - De DT " . - # #- ""$ . " > % " > . -- # " strain and temperature cross-sensitivity term # " " . cross-sensitivity coef®cient Ce;T " .- " De DT %% Dz! Se De ST DT Ce;T DeDT: z!

3:39

" et al. C(::'D L et al. C(::'D " " "

- F# " $. -#- - - . $ > % 1 " - # " " $$ F

- " -" "

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- F# -- $ F# . -#- $ " # $

- F#%

1 +),

5

-- *-

8.1 INTRODUCTION -#- - F#

- "

# --

- "" " " .# " % - " " # - " " # - " - - - % "

- F# " " " - % "

" " .H B " - - " -- " "

- F# " " " % - . # " # " - # .#

- F# " ,+ . $ " .-% " # stress concentration " .#

- F# " " " G .. . . " " G " - % 7"

- F# # " - " " - .# " - - " # % " " >. " " " " # F#

- F #

- - > - . " ..- B " " G " #-%

8.2 INSTALLATION OF FIBER OPTIC STRUCTURAL SENSORS -- F#

. -" - " " # " - " # 4 . "" 325

326

1 +), 5

-- *-

FIGURE 8.1. - F# " +B>* "$ #%

% "

- F# # . > # " " " # " +B>* C% 5%(D% 7 "-- " . ®ber optic cable . jacketed " --

- F#% *-- et al. C(::3D " -

- B F# - ## " 8$

- F#% " ®ber optic ribbon cable - F #

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/ - " . - . % "

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#-%

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327

8.2.1 Surface installation on metal structures " "/ # F#

.- " - -- " . - " " " - " % - " - " >.- . . -

- # .- " - " - " " " - . -

" .% #- " F#

" " - # . .-- .- - " # - - - C% 5%&D% " / # - A . ElectroPhotonics Corporation )+ . Roctest% 7" F#

# . - . " - - - " # -

FIGURE 8.2. 7-#- F#

% " . )- +" - %

328

1 +), 5

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" " # - . " # 1 mm " "# A A . > > . " B"$ # C% 5%4D% " F#

" - " # - " > . - " " A A " "

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F#

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329

H F> " .-- " B"$ # C% 5%4D% " " # "

- F# " sensor should never be touched - " I HJ " - # "-% -- " .

--

- " #- # . > # " H "

- F# " .-% " > - . " -- " > -- % " -- # > " - . " # " . #- ## " " # " " - ## - C% 5%4 D%

8.2.2 Installation on or within concrete structures " existing concrete structures # . .

" " -- "

- F# - " % " - >. - " . .- # ,+ " *#" , - + .- . - ,+ "#- " " C% 5%;D% " -# > . #- - . " F#

" C% 5%9D " " -#- - % " " " - # .

" " " " "- % $ .- " # # C -- % 5%4D " - " # -?% " .# " ,+ -. > . - " - F #

- " -

- # #% &; "

- --

% " -. " " F#

" # " " > -% . " . ###- " . - " > # " -.

" % "

- F# " - # - --- " " H

- " -. " . #. " % ! /

- F# #- . . " -. ? - " # -% " F#

#- " - - # #- " . . .- % " # # -- -- .-- F .. " .-- B " H - % >. - F#

- . " . " - C* et al. (::5D " % 5%2% " -- f 1 12g

- F# $

330

1 +), 5

-- *- Electrical Cables

Concrete Column

Optoelectronic Demodulation Boxes FBG Sensor Embedded within Protective Patch

Protected Optical Fiber Cable

FRP Rehabilitation and Strengthening Wrap

FBG Sensor Embedded within FRP Wrap

FIGURE 8.4. -- ." -- F#

> % C(D " .# " ,+ " # " % C&D " .# " "#- "$ ,+ %

- " " .% " # # "

- nitrile rubber sealant butyl rubber sheets % 5%4 % " . -- --

" -- - # . " - # .> " - % . - . -- # " " F#

C% 5%3D% #- #- #- " .

# -- . " " " " " " - #% # ,+ .- -- -- - -

" % " & : .# # " - # " +, - . " $

% " .

" " - - % &%9#

5%& !! ), + ,, ! ),

331

FIGURE 8.5. . F#

" -.%

-% * "

- F# # " ,+

/ .$ .

/ " - - . - "

"

> # " " " % " - ,+ " " #

% " . # . .

" . " % 1

" - . " # F# " - " % #- #- - " F#

" -

" " # .>.. - - % " -- " # .- . " . - " ." . #- " " - "" 9%2% # - " "

# " "- - # " ".

.- " # .- " - # -- #-% " F#

#- - -. " . "

332

1 +), 5

-- *-

FIGURE 8.6. #

. " - .

" - # # -- " %

C% 5%5D% " - metal housing - #

" > -"

- F# " " " # " % 5%: :%4: :%;'% "

- F# #- " " - "- . . / " . % 7" .. . " " "

- F# # . -- metal tube with two end ¯anges # " " C% 5%('D%

" ElectroPhotonics Corporation Roctest " " % " 0 # - " .> - #/ "" " .>% " " instrumented briquettes

-- -#- " " - " - "$ .- % "-- " (' . . Smartec ?- " > " -

et al. C(::2D -

long gauge F#

.

5%& !! ), + ,, ! ),

333

FIGURE 8.7. - # . " # F#

-- " % -- " " #- ## " " "

- F# #- - " %

" . " .- . - % " . " # " " .

% " . . F#

-# " . #- ."

#- - -- - - # .

" - % . "

- - " F#

-- # -" #- " # " - #-. " " " % * - . -- -#- . $ " . "#

-0 KK-- , # GG% Prefabrication " ®ber optic structural monitoring . remote communications -- ##- # " " " - " . -- $ % " ,+ " $ . " - " : " % 5%(( #

334 1 +), 5 -- *-

FIGURE 8.8. - F#

. # " " ." - . % "

- F# #- - " ." " - " %

5%& !! ), + ,, ! ),

335

FIGURE 8.9. )>. - " - .- " " " F#

#- " % " " "

F# #- C D " % " . %

FIGURE 8.10. -- F#

.#$ " # % " . )- +" - %

# + * )*+ " F

" " .- - )% )$ -- - " " . " F#

" - # -. "#- . . $ " %

336

1 +), 5

-- *-

FIGURE 8.11. ,+ " . # # + * . -" " . - % " . %

8.2.3 Installation within FRP laminated structures -- F#

- " FRP laminated structures

#

"" ..? " . "

. " " # % " .#

- F# " # #-" " " - . " - -$ ".% " > " "

- F# - " # . . " .. /.% " ingress=egress points - # #-" . . #- " " . " - -.% "

- F# > ,+ " " " " .. # " # " % .. "

- F# " " " . # " " - " ,+ - - "

- F# F-- . . " " "

- F# -% " ,+ . " > " optical ®ber pigtail . . strain relief . # % - # "

%

5%& !! ), + ,, ! ),

337

FIGURE 8.12. CD ! .#

- F# . " " . F#= > - " - 1$ % C#D # ,+ - - "

- " " .#

- F# . % , . ! - *% * ,%*% C(::&D KK. . . . *- " ).# # GG J Composite Engineering 2 934@9:2 " . . )- %

" . F#= > - " % 2%;# >. - ,+ " . " - 2D$ .#

- F# CA-

et al. (::'D% " "

- F# .# " - - " " % 5%(& . " " " " " -- " -" " $ # . " -" " % 5%(&# C! - * (::&D% * ,+ -. . .# - . . . - F " " " " .> .- # . -/$- . . " $-% "

- F# - " # .# - "

- " . " " " " " . - - "

338

1 +), 5

-- *-

% " F# /- -

- - .> .- -- # - " .# " F# . " - " > - F# # # %

8.3 FIBER OPTIC SENSOR INTEGRATION WITHIN FRP MATERIALS " " " -- - " F#

- " .# " ,+ . .- .#

/ 0 (i)

do embedded optical ®ber sensors degrade the performance and=or life of the host structure, (ii) can the far-®eld host strain be accurately determined from a measurement of the strain within the optical ®ber, (iii) how effective is the strain transfer from host to sensor, especially when steep strain pro®les are being measured.

"-- "

"

- F# - - " .% " F " # -0

- F# " " "

- " -

F# % " F / -- --% .#

- F# 0 CD microscopic stress concentrations . "" -- -- " " - " " -- " - CD macroscopic damage " -- - " G - %

" B "

.#

- F# " "

continuum mechanics% )- " " .-- " - - - - " " .. " " - # F # ." " C% 5%(4D% " -- stress concentration - " .-% 7 % &%4' "

- F# .# " ,+ . .- --- " H F# -- - " " " .-% " .." " " # " .- stress concentration -% " " .# F#

-- . -- F -" " # . " "

- F# # " . " .% C(::9D "

5%4 ), + ), )A, 71 ,+ * ), !

339

FIGURE 8.13. ". F " " " - -$- -% . 6%% % KK - #[ . *"GG KKFiber Optic Smart StructuresGG ) 6% C)%D # (::9 7- % , # . 6 " 7- %

. obtrusivity " > " # " - #- f g " " .#

- F#% Obtrusivity - " -# " # . . " " >% " F . / # - ."- . -$ -

- F# " - $# # et al. C(:53D " # - " " -. . .- " .#

F#% ? et al. C(:5:D " # . " F MoireÂ interferometric study " F- "

- F# .# "= > -. % " " - " > lenticular resin-rich " .

- F# .# . angle " indigenous reinforcing ®bers% " resin eyes " .. " - -- % 5%(; "" -

" notation # # " " / " - " ,+ " .#

- F#% ? et al. C(:5:D - " ? " " $" ?

340

1 +), 5

-- *-

FIGURE 8.14. CD - F# .# --- - - - % C#D - F# .# ;9 - - - . % CD - F# .#

- " - - - - " . - %

5%4 ), + ), )A, 71 ,+ * ), !

341

" " / H -. # F- " % " . " - -$ . # MoireÂ interferometry

-

'& =:'& =f:'g=:'& ='& :'& ='& =f:'g='& =:'& >- $ . # " "

- F# ." - #$ f%% . g " - - F- " "

- F# 90 " F# " " - " ".% " # " .# - " F % " 902 . - 90 % ) " " * R /

" "

- F# " " - - F-% .- # -" et al. C(:5:D " $ . " - ? et al. C(:5:D . "% # -" et al. C(:5:D - " .> "" "

- " " "

- F#=" . :'; ='; =f:'g='; =:'; "$ > -.% "

.> . . " - " . -. . --

F#=-. . . .% -

F# ?$ " " strain perturbations

.#

- F# # . F . " 100 mm - 5%9% " > . F. # " " - . C(::2D%

8.3.1 Obtrusivity of embedded ®ber optic structural sensors " " obtrusivity " .# F#

-# # " basic opto-thermo-mechanical / C3%49D -? -"% " # . " . " / " .-? " " sensor optical path length # 0 DzL eF( zL

n&' F e p ( fp p(& geF& eF4 ; & ( (& & ((

5:(

" eF( " axial strain eF& ; eF4 " transverse components of strain "

- F#% " " . " . " " strain in the optical ®ber is the same as that in the hostN %% H H eF( ; eF& ; eF4 eH ( ; e& ; e4 ;

5:&

342

1 +), 5

-- *-

- " rarely " " # " "

- F# " . " - - " " / . $F- f #g -% C(::9D " #H " .# - "/ - " . . F0 KK" "

- F# / . " $ F- - " " GG% - " " " +! " " " host far-®eld strain " . ." # "

- F# " " # % " # " -

" " # " .- -- -$ . . " " "

- F# " C et al. (::'D% " " # #- . " #H C 1-" (::(N (::&N *" (::4N <. et al. (::4D% * "

- F# elastic cylindrical inclusion " " " -- -. .- .# " $F- # . # " -

- " " % *" C(::4D . " > "" obtrusivity B " calibration .# F#

# > .-- . " "

*"$T" . " " F#

" . - % " phase sensitivity " F0 Sf

Df ; Le(

5:4

" Df " " " " . -" L >- e( % " >- " F#

# " . " " " " > . generalized plane strain " 1-direction . >% " - " > . " " " " - - # 1-" C(::(D % 5%(9% " .- 1 C(:35D . - " =" . " " zero coupling of host transverse strain "

- F# " " axial strain in the ®ber matches that of the host% /- " " - % 5%(9 " Butter and Hocker model # " " ? - -% " " " - " F " " . - 1 G . - # " " optical ®ber stiffness is 10-times greater than that of the host material "

- F# - -- " " .-% - " " "

-

5%; 1) !)) ), + A

343

FIGURE 8.15. L " . " " " F# " > .- CnD 1 . - CsD 1- . - CuD%

F# .# " ,+ . .- -- " " H F#% -" " " - F F#

" " #

- /-- - intrinsic Fabry±Perot ®ber Bragg grating % 1 F#

$ . # $ " " )+ !) insensitive to transverse strain /- - # - - % " ." . " " 1 . - # # / C3%;(D%

8.4 THE INFLUENCE OF FIBER OPTIC COATINGS " " - " B optical ®ber coatings " =" " "

344

1 +), 5

-- *-

" .#

- F#% " - # # " - .. " - F# . # > . " - " -

.

surface microcracks . % " .

- - -. " -

- ." " - . "" . " " .% C" et al. (::3D # " thermoset polyimide coatings . 300 C . " 100 C -

- % + C(::&D C(::4D " " #H

.#

- F# . - ". - " F- - -

" .- C% 5%(2D% " "

- F# " - "

% % 5%(3 " " " "

- F# # " " " . - " optical ®ber coating - - " - % - " " " " " " "

- F# " " " . - " - " " " " .>% - " " " " .> " " " " C+ (::&D% " >- - " > "

- F# .>.. " " C% 5%(3#D C(::4D% C(::&D " "

- F#

- . "

"

" > ."-- KK

.-GG " .#

- F# % "

.? " # " . . ." fobtrusiveg - --

FIGURE 8.16. ". " . - >. " B . " .#

- F#% . 6%% % KK" , - ! - # . GG J. Intell. Mater. Syst. & Structures 4 &2'@&3( " . +#-" % % # (::4%

5%; 1) !)) ), + A

345

FIGURE 8.17. CD L " F# " " " " F# C - F#D - " " " . -% C#D L " F# " " " F#

- - " " .- G . -% CD . + %)% C(::&D KK! - " # GG Smart Materials and Structures J 1 93@2& " . +" +#-" !% C#D . 6%% % KK - #= . *"GG Fiber Optic Smart Structures )% C)%D " . . " . +#-" % % # (::9%

. " . " " % . - - "" - "

- F# . -

$ > B # thermal expansion mismatches " . % C(::&D "

346

1 +), 5

-- *-

" ? -- . " .#

- F# #- "

- F# .# --- " F# - >- % >. - " -- C% 5%(5D "

.- coating radius to ®ber radius = " coating design space "$ > " " - - + G '%4% Design space F # " coating Young's modulus f .-? # G . -g - coating Poisson's ratio% " .- " % 5%(5D "

.# " - -. " " " . .- >- - % . , C(::&D " optimal coating concept -- .#

- F# # #- " - . et al. C(::( (::(#D% " optimal coating parameter curves ..? " " " - % 5%(:% " - > " " coating's Young modulus Yc " host's transverse modulus YtH % " " ? - > " " coating radius rc "

FIGURE 8.18. L "

- F# G . - C .-? # " - -D " G + - " " " "

- F#% . 6%% % KK - #= . *"GG% 0 Fiber Optic Smart Structures ) 6% # (::9 7- $ % , # . 6 " 7- %

5%; 1) !)) ), + A

347

FIGURE 8.19. L "

- F# G . - .-? # " " G . - " " " "

- F# -

- F# " G . -%

" optical ®ber radius rF % )" "

- F#G * - YF " " " G . - YtH % " # . - " .

. " " - " % % 5%&' " " -- " maximum principal stress " .> .- angular position " .# ®ber=host interface " coating to matrix stiffness " " " #H transverse tensile loading% " " -

.. # " -

-- minimum .>.. - % . et al. C(::( (::(#D C(::'D C(::&D . -- C(::&D " #- .- - -- #- " . " $ - . % , # C(::(D - " # stress concentration " " weak optical ®ber coating materials weak optical ®ber=coating

coating=host interfaces - " formation of cracks -

348

1 +), 5

-- *-

FIGURE 8.20. L " .>.. - " " .> .- " - # " F#=" " " .> C G . -D% . . A% +% -- ,%% C(::&D KK -- * - * ."- L #$, . GG Proc IUMTAM Conf. &3@2( # L- A.#1%

--% " cracks - /- - - transverse cracking - ,+ . .- " % "

- micro-fractographic analysis " " .#

- F#% % 5%&( -- -

# " - -.

- F#% " .$ " " " " " .- -- " - ,+ . % 1 " ,+ -$ # " - % + et al. C(::( (::&D - " optical ®ber coatings transverse tensile longitudinal shear loading

" % " " " " thinner coating enhances strain transfer . " " " " " " " .>% " " " " " " " .> thicker coatings # shear strain transfer% " > .- F. " " - " " F- - " . " .#

F# . " # obtrusivity enhancing sensor performance C7 et al. (:55 (::&N + (::&N . et al. (::( (::(# (::4N " et al. (::( , # (::&D%

5%; 1) !)) ), + A

349

FIGURE 8.21. ". -- - # - -.

- F#% . , # %%6% ,% C(::(D *"- +

. *- ).# # Fiber Optic Smart Structures and Skins IV SPIE 1588 4&2@4;(%

-" " " "" " " #

-- " acrylate coatings

# -

" ".- #- - composite curing temperatures% " .-- -- % 5%&&# "" " .F epoxy-acrylate coated 125 mm

- F# '=:' ,+ " -.% /

" " - " .- " - " resin-pocket " . "

F#G " - " H - % % 5%&& "

- F# .# --- " - - X:'='Y ,+ " -.% -- " - $ . " "

- F# " ..- B " .-%

8.4.1 Sensor=host bond and strain transfer # C .#D ? -- . >" " # - " F# -- % 5%&4%

350

1 +), 5

-- *-

FIGURE 8.22. * " .#

- F#% CD

- F# .# --- " - - # F#% C#D -$

- F# .# " - " - - # F#% , . ,%

%1% , # %6% KK . *- * " " ).# # GG International Journal of Optoelectronics 5 4:3@;'4 # (::'% , " .$ - Q +#-" % " 0[[% -$% .

5%; 1) !)) ), + A

351

FIGURE 8.23. ". " " # .#

- F# -- .. " # " %

1" " - " " # -

. -" " .--. " " - . " " " F#% " #

. #- - shear stress ti z " axial stress sFz z "

- F# %% pr&F sFz z &prF ti Dz pr&F fsFz z DsFz zg;

5:;

352

1 +), 5

-- *-

% 5%&4#% "" 0 ti

rF dsFz z ; & dz

5:9

." " shear stress " # "

F# -

- " gradient of the axial stress " "

- F#% " creep bond degradation -. " ? -- " G " - " ? % 5%&4% #- " / # $-" " " . bond mechanics C* et al. (::3D% " bond # " sensor and its host " -. strain measurements% -

# " " " " "

- F# " -- . " - # -% et al. C(:5: (::(D " adhesion # optical ®bers and a FRP host # " --$ #

- F# .# " " " ,+ . .-% 7 C(:55D " -" " " # # - " " .- /

- F " . " " "

- F# - " -. " " " .- -

% " et al. C(::(D # " polyimide coatings # - # " "

- F# " " .- "- , # C(::(D " " # # " -

- F#

" # " - " " % # " ""- .F .--

.#

- F# % 5%&; " acrylate coating . # " " # " -- separated from the optical ®ber% " -- " - - $- . "

. " . - "

- F# - % " . " # , # C(::(D " " .. acrylate optical ®ber " 125 mm - . . 240 mm reduce the FRP composite strength # 13% f%% 57.0 MPa . 65.5 MPa 1% " # .#

- F#g% +- et al. C(::4D " " " bond strength # polyimidecoated optical ®bers graphite-epoxy host F " "" " "% . . silane coupling agent " " " # "

- F# polyimide coating # . " -- -.

5%; 1) !)) ), + A

353

FIGURE 8.24. )- . "

- F# .# " ,+ . -. " " " - . # " " .> " " " # . . "

- F#% . , # %% ,% C(::(D KK*"- +

. *- ).# # GG Fiber Optic Smart Structures and Skins IV SPIE 1588 4&2@4;(%

- F# -- . " . .% . H C(::9D " " ." .#

- " " - -- # - # quantify the shear strength " interface # "

- F# # " " F " .-% " -- F#

. > - % #

#- -- - . . - H

"

- F#% *? et al. C(::4D . " --$ " # # "

- F# H . >.-

% " " " et al. C(::(D " " # # . " -

- F# F-

% ) # et al. C(::&D # " -?--

- F# . . .# # " - % "

" .. " #- 5%(%

354

1 +), 5

-- *-

Table 8.1 +

- # C1#- et al. (::;D

+ -. - -

)- * - C*+D

- " C*+D

,

".#-

&;'' 3'' &

(4'%' &2%' 9%9

M

" ".- #- " " optical ®ber polymer coatings " # C1#- et al. (::; 1#- 1--. (::9D # ". alkaline solutions #/- .# ". % " -. . - # " # . " " - " B $ ". - " .#. (9 % " - ." > " # F#

" - " # # / . " - .

- F# " " # " #- .# - . " " " - C*?#" et al. (::2D " : ('%

8.5 INFLUENCE OF EMBEDDED OPTICAL FIBERS ON THE HOST STRUCTURE " & . F#

- . . . % #- #- " . # - . -. "

- F# " - -- # ". " / " % " . " -- " " " " - -- . . " . -

" . % F-- -- # -

" embedded optical ®ber sensors "0 stiffness, strength and fatigue characteristics of their host structure% - " #H " # # . H C(::9D% - # "

- F# " " . " " exception of aerodynamic surfaces -- "

F % - "

- F# .# " # -. -

5%9 !)) )* )) + ! ),

355

FIGURE 8.25. ". -- " --- .- -> - " #"

- F# " %

" " -- " -#- B% "

.- " .#

- F# " ,+ . .-% " .# .# sensor con®guration #- FRP arrangement - " " B .# F#

" -#- . - " "

$ " " % #- " # . " - " % - " .#

- F# " -. -- # .-- . % " > " - # " .#

- F# # " " . .. = "

- . $ " " -- " . --- .- -> C% 5%&9D%

8.5.1 Optical ®ber resin-pockets " interlaminar lenticular resin-rich pockets .

- F# .# " ,+ . "

" " --- " H

356

1 +), 5

-- *-

FIGURE 8.26. +" . " C D .

F# " .# " - " - - - % . % 7 % 6%% C(::&D KK+ . -

- F# .# -. . %GG Smart Materials & Structures 1 ('(@('3 "

. +" +#-" !%

F#% " H " B " resin-pockets " " -. " - " " C et al. (::' et al. (::&D . " " obtrusivity "

" -# .# % % 5%&2 - " >. - resin-pocket " "

- F# .# $ - " H F#% % 5%(; " ?

" resin-pockets " .-- " - # "

F# " F#% " - .-- " .-- " " " -.% ! $ interlaminar discontinuities potential reliability hazard # " " "

- - " - % Finite element analysis " #

- ." " stress concentration .#

- F#% " - # "- #-" - " # " optical ®ber strain " far-®eld host strain . -> .% " " resin-pocket geometry " -- - - -. / - " " # - # - " $ . C-" et al. (:5: et al. (::'D% " . " " > . #$

5%9 !)) )* )) + ! ),

357

FIGURE 8.27. , - " ,+ - "" - - " - # "

- F# " - - - D # " " . - > .% . % 7 % 6% % C(::&D KK+ . -

- F# .# -. . $ %GG Smart Materials & Structures 1 ('(@('3 " . +" +#-" !%

- . "% - . " # # # . - . - " # $ . "$ > . % 5%&3% " F " " . # . resin-pocket aspect ratios > -. /% " " > $ .- - . . " . " " $

% " . . " " C6 et al. (::& 1 -- (::4D " " .#

- F# " -- f\5%g " stiffness ,+ 0 " optical ®ber volume fraction - " . "

- F# - " 250 mm% " # 1 -- " " polyimide coated optical ®bers - 250 mm . "

.#- " " tensile compressive stiffness # " - /$

,+ -.% " . F

- F# .# " - " - " F#%

358

1 +), 5

-- *-

8.5.2 Effect on tensile strength .# " C* et al. (:5: , # (::( . et al. (::4 1 -- (::4 +- "

(::4D " " B .#

- F#0 spacing size orientation " tensile strength ,+ . .- " % " - " " " .#-

- F# .# --- " " F#% -- % 5%&5 .- " - > "

- F# " F % 7" "

- F# .# -

" F# .-- - . " - F# " # " . "

- F#% " " " - - F .--

- F# . f\&'' m.g "

#- " " tensile strength " " %

FIGURE 8.28. 1"- .F

- F# .# --- " - - F# " " ,+ .-% . , # %6% ,% C(::&D KK" . " . *- ).# # GG ('" )

. *- A- SPIE 1777 &99@&2&%

5%9 !)) )* )) + ! ),

359

8.5.3 Effect on transverse strength " transverse strength - ,+ .

- F# .# --- " . "

. "

- F# % !- " #

# static loading " . - " 100 mm C. H (::9D% - , # C(::(D - " =" =

- F# - transverse crack formation - % 5%&(% . , C(::&D --- " " coated optical ®ber .# ,+ . .- #H transverse strains% " " a coating with the appropriate compliance may avoid any premature failure " . .-% "= > -. "

.. . - - polyimide coating f%% 3.45 GPag%

8.5.4 Effect on compressive strength -" " " .#

- F#

" -#- " tensile strength ,+ . " " . # " " compressive strength%

- " C(:5:D 6 et al. C(::& (::&#D " 250 mm -$

- F# " compression strength

,+ -.% 7" "

- F# .#

--- " F# " compression strength #% / F f 70%g " compression strength . " "

- F# embedded perpendicular " H F#% " "

" - > . - " -

- F# ,+ . " "=#.-. C6 et al. (::&D / -- "" . " - .- #- % 5%&&% , # C(::(D . et al. C(::&D - " -$.

- F# " compression strength ,+ . .- .# -- " " - F#% " B .--

- F# .#. - compression strength " # -- % -- " / . - " .#

- F# . "%

360

1 +), 5

-- *-

" . C(::;D -

compression strength model # " " " lenticular region # et al. C(::'D " - . . - # 1" C(:5'D% 7" " . - " - " degradation in compression strength 0 optical ®ber size laminate stiffness properties laminate lay-up and processing parameters% " . " $ " . "

- F# .# - - " 15 degrees " " - % " - " " " " . " . " % " . - "- > - " - " " . "

compression strength%

8.5.5 Effect on shear strength " C(:5:D . 3O " interlaminar shear strength

- ,+ . -. " .# 250 mm -$

- F#% #/- , # C(::(D

. interlaminar shear test "$ # . "$ > . 100 mm -.M -$ F#% " - .- " # # +- "

C(::4D no degradation in the shear strength

" " .#

- F#%

8.5.6 Effect on fatigue " " # -- " B .#

F# " fatigue life ,+ . % , # C(::&D - ,+ . .- .#

- F# - - -- #- 80% -. - - " 20,000 - . " .# F#

- $ - - % " - .# 140 mm -.$

- F# cross-ply laminate --- " 90 . F# " X'=:'Y - ". - "

- F# . " $ - F % " *- et al. C(::&D " -.$

- F# " - .- " fatigue life ,+ -. " - F# "- > > . ! C(::'D " " - $

5%9 !)) )* )) + ! ),

361

,+ -. # .#

- F# " . - " 150 mm%

8.5.7 Effect on fracture toughness - H" et al. C(::'D " .#

- F#

" interlaminar fracture toughness <-= > -.% #- - #. " " Mode I delamination

" -.% " " "

.#

- F# " critical energy release rate # " # # 15% - -.% "

- F# stiffener " - - .> " "

%

8.5.8 End-Effects of optical ®bers terminating within host - F#

- " termination of the optical ®ber " " " % " ,+ . " " . "

- F# " .- - " .

resin-cone at the tip of the optical ®ber% " " interfacial failure " - - " " .-% " - #- F . .-

. % - " . debonding material yielding " # # # ! - C(::5D% 1 " " G . - " " "

- F# F " " "

coating with the same modulus of elasticity " " " G .> -- # eliminates this stress intensi®cation% ! - C(::5D " " #-.

- F# . " ,+ . .- 0 (% " " "

- F# " - # .# # -- - " " H F#% &% " "

.# . - . - " - # -. " - % . , C(::&D " " .# G . - " ..? " " %

362

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4% " " F . , G /. -- - " F " " # . "

- F#% " " " . " " " G .> " " " stiffness discontinuity " "

F# eliminated% " softer coating f F . - " thicker " g -- # " . " % - - - longer strain transfer length% 7" " # " " interfacial shear stress -- " stress energy " " .- % " . " .

" yielding " .- debonding -% " failure onset strain% ! - C(::5D -

. . - " -- .-

"" - -- F% " . - - # - "" " .-- "" . - F% ! - C(::5D -

- > . " . $ - . " #@+ # "

- F#% 1 " " .. " - . " - #

" A - # - # - " (&%('%4% 1 - " singleended embedded optical ®ber sensors # - - "

#- - $? . ?% Polyimide "" #- .# -

- # satisfactory for the end-zone problems% *"- " " " " " polyimide coating " - # ." thicker " - 0 60 mm . " 10 15 m.% ) > " .- " ."-

.- "

-.% " radial compression "

- F# . # " F - . ef®cient strain transfer . " " "

- F# "

# - % + -. " residual stresses " "- - " %

8.5.9 Minimization of adverse effects . # " 6 C(::9D " - " minimization adverse in¯uence .#

- F# " - " " .- / "0

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363

CD

"

- F# . f- " g # # ('' m. - - . " $ - "% CD "

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- F# " - # .# --- " - F# C%% --- " H - D% CD #- "

- F# " - - # --- " - %

8.6 PULTRUDED FIBER OPTIC STRUCTURAL SENSORS . . F# -. . .-

# .# . "/ -0 prepreg lay-upN pultrusion ®lament winding% " >-- ,+ -$ # % " - " "

- F# - " ,+ . .- . - C#- et al. (::; (::9D% " & FRP rebar and prestressing tendons F

- - ) - -. - . % " " " " " -

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. " .- " : (( C* et al. (::9 -- et al. (::3D% . " F#

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" - -. " -

F " " - . % <-. et al. C(::3D " . " polyimide-coated optical ®bers " ®ber Bragg grating sensors - survived pultrusion # -- " " .-% acrylate coated optical ®ber #- " " "" . >"# severe debonding% " 9.5 mm . # .? - ." " --- " "

150 C% " -.$

- F# " -. 155 mm "- " -$

- F# " . 250 mm% % 5%&: - )* . $ " "

364

1 +), 5

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FIGURE 8.29. - . " -

- F#0 CD -$

- F# C#D -.$

- F#% . <-. %!% * $ - %% 7" +% %% C(::3D KK+- . ,+ . GG . $ . . *- . + . *" (::3 - SPIE Proceedings 3042 ;''@;':%

-

- F#% # " -$

F# . " .- -- #- % 5%&: "- " >-- # " -.$

- F# " .- /

% 5%&:#% " .#. -

- F# --- " F# "

.- B " tensile properties "

- ,+ % -" " shear strength f 10%g

5%3 ), + ,, ! ), ),T

365

FIGURE 8.30. *F " - -$F#$ -. .#

- F#% . <-. %!% * - %% 7" +% %% C(::3D KK+- . ,+ . GG . . . *- . + . *" (::3 - SPIE Proceedings 3042 ;''@;':%

" # " glass FRP rods

carbon ®ber rods " "

- F# " -#- B

" " "% " -

- F# "

- " . F " " " " - ,+ % $ " " "

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% 5%4'% L " - "

F# . # - " 0.5 mm 10 m % " #- accurately position "

- F# # "

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%

8.7 FIBER OPTIC STRUCTURAL SENSOR CONNECTORIZATION . F#

- - " .# " tough optical ®ber cable

366

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"

- F# " # " " 5%&% . ,+ . . " resident ®ber optic structural sensing system -- # " optical ®ber pigtails% " . # " " " " ,+ " "

- F# -- . "# .- "? . " % ". " # F .-. / " .# " - " . " % " "- # " " " "

- F# / #- " . " H% -- " " " " " # . " "% -

" " #

" ®ber optic=host interface C --. ! (::9D% " " . ,+ . . - " optical interface # - " # . % 5%4(% " ,+ " . # lay-up fabrication "

- F# . " connector ferrule .# " " . -$ % "

- F# " - -" " " -% " - - " " ,+ -$ " . "- " " - . " "" - " . -

- %

# " " optical interface - #- " - " " #H - . -

" - .#% >. - "

- F# . ,+ . " ? " . C --. ! (::9D % 5%4&%

FIGURE 8.31. ".

- F#

- F# .# " ,+ . .- % . --. 7% % 6% ! 6%,% KK*"

# [) . GG 0 KKFiber Optic Smart StructuresGG )% ) 6% # (::9 7- % , # . 6 " 7- %

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367

FIGURE 8.32. - F# ,+ . .#

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" " " . " ,+ " "#- " " . - /% )>. - "

" # " : ('% pultruded FRP host structures " . continuous feedstock - .#

- F# B" " " >. - % 5%4'% * -#- #

- "

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. . smart-endcap . -" " . .% " smart-endcap - # . " "

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368

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FIGURE 8.33. -- " KK. $ GG - ,+ . "

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375

AShallow

Steep Slope High Resolution, But Small Range Shallow Slope Large Range,But Low Resolution Minimum Photodetector Ratio

λ1

λ

2 ∆λ ∆λ Shallow Steep

λ3

λ4

Wavelength, λ FIGURE 9.3. $ # .. - " -

" - F- " A - . . - .% -

"" - # .-- .. "- "-- -

-- - # - - %

4 - " > .- . % 2%&; - " " wavelength-dependent coupler " -- # " - #-$ F-% " # " "

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376

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FIGURE 9.5. +" " - --- $"- F#

. - !$4(''% " . )- +" - %

Single Mode Optical Fiber 3 dB Coupler

Broadband Source or Laser

Fiber Bragg Grating

Isolator P1

Light Dumps

Photodetectors P2

Wavelength Division Coupler

(P1 + P2 ) FilterP1Transmission

S

P1 Spectral Response FBG-Signals FBG-Signals

λΒ

Wavelength

P2 (P1 + P2 )

P2 Spectral Response FBG-Signals

λΒ

Wavelength

FIGURE 9.6. + - . . - . A -"$ - - - F-%

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FIGURE 9.12. - $-

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AOTF profile dithers about Offset from λ B

Photodetector Signal

Photodetector Signal

RF Dither

Time Small amplitude signal when λ AOTF λ B

~

Time Large amplitude signal when λ AOTF = λ B

FIGURE 9.15. $

#- F- . - . - A % - " ."- . " . # . . B - #. " " " # " #.% " " , " " . .. " -"% . A 1% V *%A% 6%+% C(::9D KK*- -> *. " ! A !" GG SPIE 2507 &9@4;%

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- % " - . " " .

" - " . ;4'' me " . . .. 9 1? " .. & me CA et al. (::9D% " frequency±strain sensitivity . " % :%(3 :2:3 1? me ( % " C(::2D

FIGURE 9.16. . A . - # " . # % :%(9% . A 1% V *%A% 6%+% C(::9D KK*- -> *. " ! A !" GG SPIE 2507 &9@4;%

386

1 +), : " A

-

FIGURE 9.17. ! / " A " > .- -- % :%(9% . A 1% V *%A% 6%+% C(::9D KK*- -> *. " ! A !" GG SPIE 2507 &9@4;%

" " -

.

. " $.- . - - . - . .. . $$ -"$.- -> A " & e 1z ':9 % Matched FBGs. " "-- . " -" A - # # " - .>. KK " " " %GG 6 et al. C(::4D " F " " A # # matching demodulation FBG% " . " reading grating B . F -" -- # . piezoelectric stretcher C% :%(5D% " . #

" " . " . % " . - .

- " ? - " " -- - " A B . " # -" -- " A .% 7" " " " .>.. " -" " " - " -

- " A " " # > # " A # .% " - . closed-loop servo - " A $ -" " " A "

? - - - " -"% " "/ - # -$.- -> A N " ((% - ; me # - # . " $#" A%

:%& ), , AA A, A ), )*!

387

Single Mode Optical Fiber Broadband Source or Laser

Sensing Fiber Bragg Grating

S

Interrogating Fiber Bragg Grating 3 dB Coupler

Light Dump Photodetector

Scan Servo FIGURE 9.18. ". " ." A "/ . - A%

" " ". " - - "

B - . # < C(::9D% "

" F . " " A% " A " " . -"% " A . " # . $ "- " A . ? - " " -- # # - - # . " " $ -% " > . # < C(::9#D . . " .- -> #- "

" A C" -" (99(%5 . (993%& .D . -.. - " "" #H "$ #% " $ ." A . - . - ? - "% " A --. # # # B #.$

F# " -- - -" .- -> .# A% " " - " " .% " - . " "

- $ . -F " " " -

- " F- A% " " - $ .. " " " - # " A% " # -

-- " F- - $ -" " > # " A " " - $

388

1 +), : " A

-

- - -

- " . C% :%(:D% " " F " " - / " # " - .

- " A%

" A #- " /

- " % -" " #- - " (' e 1z ':9 " -. # " ? - "% "

" - " - " . $ $ -" > . - # - " " $

FIGURE 9.19. . - . A # - $-

" ." A% " - " " -

- ? - -. -- " A B .% . *% % < %% C(::9#D KK-- F *" - "/ A GG SPIE 2444 &:9@4(&%

:%& ), , AA A, A ), )*!

389

A% - " " ." A " # $# -. C- et al. (::9D%

9.2.3 Interferometric-based demodulation ""$ - . . - "/ #- . .-- .$$ " " B $ -" . A F . # < et al. C(::&#D% " . - #- *"@T" .

- F- -. " " . X( flY " " " . fl " -" l% :%&' ".-- -- " > .- . " - - " "/

- A % $ B -" . " " " " . " " -" " "% )/% C4%;:D

- " .#- # " .

" *"@T" . nd nd( d& - " f

&pnd d; l

::;

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FIGURE 9.20. *" T" . . . - A --

. ..% . < %% *% % + 1%6% ! - *% <

<%+% %A% +. *% % #- )%6% KK# A GG J. Lightwave Technology 15 (;;&@(;24 # (::3 )))%

390

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-

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391

" # . - ':2 e 1? ':9 " # . " # > . < et al. C(::&#D% -" " " . "/ H # . " . # " . # #- /$ ..% "/

. " -" - . " . #- # < et al. C(::4D% " > .- . % :%&( .- # # " - # " F " #- . ..- " " " " " " % " . " " " A

. ".-- % . -

- " ? - F# " " #- *"@T" . " . -$ - / o " -" # " A% " " - " # F- " . - / - -- - " . S A ot ct fl ;

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S, A, ot ct fl, ;

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FIGURE 9.21. $ . *" T" . A . - .% . < %% % % * 7%7% C(::4D KK* -> # A $. " # #$+ 7-" -GG% Optics Letters 18 (43'@(43&%

392

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. - B

- " % " "$. - - " phase analyzer " > " " 0 fl fl, "" #

. " . " A " .

- -% - ':2 e 1? ':9 - $ / # ( 1? . " " .%

9.2.4 Laser sensor demodulation -- " . - "/ # # " # A% " F " # - N " -

-$ $ -. " . .% -

" . " - " A " . - C* et al. (::&D% " #

#

" ". % :%&&% " -"

" - . # " " B " A% "" B A F- - " .. " - -" -- " " -" " % " " . " A " " - -" " $ $ - % " . . " H -" " are encoded into the laser wavelength% -- " > - " - % -" " " -

- C* et al. (::&D " " A " -" . - " F . " - A -- " -" #.$

F# - C*-- et al. (::4D% " > .- . % :%&4% - - 1st Laser Mirror

Single Mode Optical Fiber

λB

λB

Gain Medium Laser Cavity Sensing Fiber Bragg Grating Also Serves as 2nd Laser Mirror Ideally Laser Operates at the Bragg Wavelength,

λB

FIGURE 9.22. . -F " - " # F F# -%

393

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:5' . . -" #.$

- F# # . :5'=(99'$-" .- ->% "

F# . "- " " A . - #.% " B -- F " F# - % " -" " F# - . # . " - . "/ C*-- et al. (::&#D% " . " " - " B

F# . #

- . -? " . - -- % :%&;% - -- . - C\ &%& .7D -" " -" " A # " " " B .% " .

&%2 .7 " " - # .-- . -F -" " -"% "

. - - " . F# - - " -"% " - " F# - -" " . % :%&9 C" et al% (::4D% #-. " " F " " - -" - C ( .D " - + . .-- " - - -- " " A B -"% " . $-" F-% "- " - . " "

" - # # " . .. " - 9 me #" (4 1?% - et al. C(::4D . "

Erbium Doped Single Mode Optical Fiber 980 nm Pump Laser Diode

Endface Laser Mirror 980 nm

980 nm Wavelength Demodulation System

1550 nm 1550 nm Wavelength Division Coupler 1550 nm

3 dB Coupler

Photodetectors Fiber Bragg Grating and 2nd Laser Mirror

Light Dump Cantilever Beam Test Structure

Spectral Filter

FIGURE 9.23. " > .- F A F# -% " -" " #.$

F# - . # " - . "/%

394

1 +), : " A

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FIGURE 9.24. - " A F# - -- % :%&4% - - H " :5' . . - " .

B " # " " A # " .% " "" - - > " - " - # " - -%

- " F# - C A!D - # -- .- ->% " . A! F# F " - C< * (::4N -- et al. (::4D % :%&2% " - # " . " # " " . . .N " " B . - % " # ". " # " " . - ." - .

-" % " - - - ." " " A #" -- 9' 1?% 7" " H " " #- *"@T" . - "/ # - .-- .

# # % < et al. C(::3#D " . - # " 1? ':9 ." # #-%

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:%& ), , AA A, A ), )*!

395

FIGURE 9.25. ! " F# - -" " . "

- " A% . *-- % - % < % % ! <% * ,%*% KK A$ # ! .GG IEEE Photon Technology Letters 5 &24@&22 # (::4 )))%

" > . " C* (:5:D% " "" #- , - " " ." . - % , " " - .# " - " - "

"% " " .. -#- " - #- - . - " . .-$

-> A C 9%('D " .

-

/ #-% 7" " . " " G # . !# > - " #- - . - A % 7 " # #- " "

396

1 +), : " A

- Single Mode Optical Fiber

3 dB Coupler

Pump Laser

Erbium Doped Optical Fiber 1st Laser Sensor

2nd Laser Sensor

S

λ1

Light Dump

λ1

λ2

λ2

Fiber Bragg Gratings

Wavelength Measurement System FIGURE 9.26. ". -- " A - # #.$

F#%

-- # #- . - " " .

#- - . - " " . -

#- " A C* et al. (::5DM" N " - $-" N - --- .- -> N - # $ % " " " universal demodulation system - # >.- -" - - " # " " (' . # ( .% - " # F. " C* et al. (::5D% ". -- " - > .. . "

" " % :%&3% - gain-coupled distributed feedback CA$ D #- - C. -#- # - D (94& . A C et al. (::5D% " A$ - . $ #-? &( .

" . (949%9 (9;;%9 . " - # # '%9 2%&9 .7 " % " A # - #. " " # F- - " -" " % - # > " F#

..% " B - . " A -- # " % " " - " - H "" " - -" - . . . " / % " A$ - - -"

>.- &%9 . " -"

397

:%& ), , AA A, A ), )*! Single Mode Optical Fiber Gain Coupled DFB Laser

3 dB Coupler

Cantilever Beam

S

λΒ

t

Laser Current Driver

Light Dump

Fiber Bragg Grating Sensor

Photodetector Detector Output

t

Computer

Data Acquisition Board

FIGURE 9.27. . - . A # " $ - - .# " .%

" A " (' .% " " / . #- - 4%& " " -" "- .>.. C71*D " " A B (' ''' . - % "/ " -" - . " A% :%&5 - " " A . &''' me% " 2' .. % " . - " .. (' . "

#"$ .-? - ':'32 me 1? ':9 % " . - . . . # . " " - - " " #- - - - " - -

. integrated optoelectronic demodulation system C* et al. (::5D% " - "/ "-- - F " . " F . " . .? #-% " " " $ / " passive spectral ratiometric demodulation system H #% " "" . - -

" F- . "- #- -" C . D / ." - -

N % :%4% " " -.. " - . . $ - . # /.$-- - # F . # * C(::9D%

398

1 +), : " A

-

FIGURE 9.28. ! " " " #- - A . - . -- % :%&3% . % "

-- !%*% A--. %6% 1 %% * ,%*% C(::3D KK+ . - # A$ - # # #- !GG (&" - - # 7--.# &('@&(&%

" " - F-G . " # - . F # "

-

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F- ? - -- % " - " " - F- . " " $ " - . - . -- > #-% 7 " . "-- - -

- " " . .?$ - . " . . . . " . # .% "

" quantum con®ned Stark-effect tuning " # $ quantum-well electroabsorption ®ltering detector C=7)D% -" " " - % :%&: "-

# % 7 " ; " # " . $ - " . . -- .- -$-" - .- " .@--.@

A " % =7) .- > " " . " " " - " " "" -" - - B # " . " # -

- " % . -F ". " =7) # * C(::3D % :%&:%

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399

" " - " " -" # - - % :%&:#%

. " . " " # 3 L " " > -" -" (99' . Light

Anode InP InGaAs/InP Quantum-Well Structure

InGaAs Waveguide

InP Cathode

Quantum-Well Electro-Absorption Device in Mesa Configuration (a) Reverse Bias Voltage

(b) FIGURE 9.29. CD ". . " . /.$-- - $# F- C=7)D . " -" A % C#D $-

- =7) "

- # -% . % * ,%*% C(::9D KK 7-" . - A

- +" " - GG !.

- " * CD

% 4;4@4;3 " . . +-. +%

400

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-

"- "- " -" -" (9;' .% " " # - F> " " - " $ . - . .% Active wavelength demodulation C 7D " -- "

# . .% " .

. - V # . " F-

- $ % " - - . " - V % " . -- /-#. " " - V /- " . - -" -" l( " " # - " . - V( " $ C D " system state diagram C% :%4'D% " -" " -" " - -" l& - " V V C " -

" . state-point A $ % :%4'D "" .-- " VA IV J% " . # "

- # - . V( V& "" " " -

- -" - /-#. #-" C$

Ratiometric Signal, Vratio

QWEFD Response Curve for Reverse Bias Voltages:

V1

Vref

VB

V2

A

C

B

λ1 λ2 Wavelength FIGURE 9.30. ". -- - $-

" -" A " " " # - CV1 V2 D " =7) C% :%&:D " . - " . - " - C

D

C D . " " " -"% . % * ,%*% C(::5D KK. - . A # =. 7-- )- # - GG Smart Materials and Structures Journal 7 &29@&3( " . . " +" +#-" !%

:%& ), , AA A, A ), )*!

401

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- " =7) CDV V( V& D " - . "" " -" " # - " . -#% -. > .- " " . =7) ".-- -- % :%4(% " . F " -" " " " - "

- " /. --% " . - -" .

- F# " ." " " . " " " /.$-- - ." .-- " " "

- F# C% :%4&D% - " . .

" A % :%44 C * (::5D% #" .-? - 4 me 1? ':9 " A (994%9 . -. " % "

- B " =7)

" .-- #@+ . - " - ##- . " - %

FIGURE 9.31. )> .- . . " . =7) C% :%&:D A . - % . % * ,%*% KK -" . - F#

/. -- # F- GG Electronics Letters 32C(:D (5((@(5(& " . . )) +#-" !%

Optical Fiber Illuminating the The Quantum-Well Electro-Absorption Device in Waveguide Configuration

Optical Fiber Illuminating the The Quantum-Well Electro-Absorption Device in Mesa Configuration

FIGURE 9.32. ". -- " KKGG KK.GG F " =7) # % :%&:%

FIGURE 9.33. =7) . . A % . % * ,%*% C(::5D KK. - . A # =. 7-- )- # - GG Smart Materials and Structures Journal 7 &29@&3( " . . " +" +#-" !%

:%4 ), , AA A, A ), ++!

403

9.3 FIBER BRAGG GRATING SENSOR APPLICATIONS (::4 " F .H .# F#

- " # " - # . . " " G -# $ % " . .- -" " F#

" # # " " " F . " " # -- - " #% " H - " F - . F-$ # F#

. % . > " et al. C(::(D " - " # " #- .#

F# " " #-% - - " - H . " # " . -# 0 KK7 "

- " " #%GG " " " .

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F#

- . % . " " # # " B " % . > " # " (( " F- -- # .

.

"

- " "-- - " " -- - . . .- -> .H -- #- - .# % - " " -

--- .- -> " " "- - . " " ((%

9.3.1 Beddington Trail Bridge, Calgary " . " F# -- " Beddington Trail Bridge - . . " " 0 conventional steel strand Carbon Fiber Composite Cable CD carbon ®ber Leadline Rod% # ,

* % !% 6 !- . -#- # *#" ".- 6 N # " " % &%9% " "$- # . - % :%4; . &2

404

1 +), : " A

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FIGURE 9.34. - - "

" #- (::4%

2 "" " " ,+ .- - " C,?-- (::;D% ! $. . " = #" $ . " - . #-" " . . " #% " " .

0 F >. - - " " - #- " " " - % " .$ -#- # . - - " - . " F " # % - - # "- - . " # . . " - . " # % " " - # #

>.- 5 ''' me - - > # # " A "

- " " #/ -> - - " . #- . $ .".% + " # (044 - . - # #- " * # C #-". et

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405

al. (::9D% A -- - -

" " #. #H /$ - - % " A .

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# " " " " . # C% :%43D% $ - " bulb-tee precast prestressed concrete girder " - % :%45% " - "

" " A -- % " F# - - " . . .- - # > "" " " "

FIGURE 9.35. L " -" A " #. " " -

- " #. - % , . * ,% - % * ,%*% A% ,?-- %1% A"$" % C(::3D KK# A * GG Journal of Cement and Concrete Composites 19 % &2 " . . )- %

406

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- "? A ,+ + AGG SPIE 2191 ('&@(('%

. " C% :%4:D% .#-. "

F# . " " - # >

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. (5 A " . - " "

% " " " # " C % :%;'D -- " F# - " . " - # > " " H # > - "

" # #. C% :%;(DN " " " F - -- "

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407

FIGURE 9.37. +" " " " -

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" - ..

- - (::9 . (5 . " -%

408

1 +), : " A

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" $#-# " - % , . * ,% - % * ,%*% A% ,?-- %1% A"$" % C(::3D KK# A * GG Journal of Cement and Concrete CompositesGG 19 % &2 " . . )- %

FIGURE 9.39. " .- - # > " "

F# - " - %

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FIGURE 9.41. " H # > " F#

" - % " . )- +" - %

410

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" .. % :%;4 " # ".-

# " - . % " " .- - ".- > $ . . .-? " "

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% :%;;% " - > - " *< - " # . 45' *+ (:'' me C* et al.

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411

FIGURE 9.43. ".-- - " - CD ,

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% &5 " . . )- %

(::3D% " - G . - " ,+ - &9O - - " " - % # - " measurements show lower loss of strain for the CFRP tendons than for steel% " . - # . . " " - " " " .# A

FIGURE 9.44. . - " .. % :%;4% , . * ,% - % * ,%*% A% ,?-- %1% A"$" % C(::3D KK# A * GG Journal of Cement and Concrete CompositesGG 19 % &: " . . )- %

412

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- #- . " - $. - " $ N " - #- register the dynamic strain response of the bridge to live loads " F% :%;9 " " A C!!]:$;D . - . " # # "

&9$ -$>- # " " # CD

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413

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9.3.2 Taylor Bridge in Winnipeg " - 1- 7 C% &%3 :%;2D

" - # " - ,+ # " $ .% " -# " .- C,?-- et al. (::3D% " - -" " F$ # (29 . " " " 44$. $ " " % :%;3%

,+ . " #%

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414

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FIGURE 9.48. ". " F#

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415

# *#" ".- 6 % " ,+ - " . " ,+

% " #

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" # C% :%;5D% " # . " F#

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# -- " " % :%9' " F#

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" 4&$"- .- -> .

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417

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. " . " # F - % " F#

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418

TABLE 9.1.

Speci®cations for Several Types of FBG Sensors Strain

Embeddable

Bondable

Weldable

Weldable high temperature

Temperature

Bolt

Probe

Gauge length 150 mm 10 mm 25 mm 25 mm >10 mm Ð Gauge material Stainless steel Fused silica glass Stainless steel Stainless steel Bolt material Metallic=nonmetallic Cable length 1 m to 1 km 1 m to 1 km 1 m to 1 km 1 m to 1 km 1 m to 1 km 1 m to 1 km Cable diameter 3 mm 1 to 3 mm 1 to 3 mm 1 to 3 mm 3 mm 1 mm to 3 mm Connector type FC, ST, SC FC, ST, SC FC, ST, SC FC, ST, SC FC, ST, SC FC, ST, SC Strain range 0.6% 1% 1% 1% 1% Ð Temperature ÿ50 C to 80 C ÿ50 C to 80 C ÿ50 C to 80 C 0 C to 325 C ÿ50 C to 80 C ÿ70 C to 350 C range ÿ58 F to 176 F ÿ58 F to 176 F) ÿ58 F to 176 F) 32 F to 617 F) ÿ58 F to 176 F) ÿ90 F to 660 F)

CHAPTER 9 Short Gauge Sensor and Applications

Sensor type

Load

:%4 ), , AA A, A ), ++!

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- " #% " . )- +" - %

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430

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431

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437

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9.3.7 Marine catamaran model measurements " .- - . " $ " "" .% "

438

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446

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- % ((%;: "- > - "

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" " . -

- " #@+ F-% " - " - "" . " -" #$B # " F A % " F - " . " "- - - " . % " " " ? $ .. " " . " #$B - . " A " -$ % " - " " - . " - " . % " >-- - " " . "" 4O # # % ((%9'% " . " F#

. . #. - . " - -% " A " " - # "

574

1 +), (( *- -> # -

FIGURE 11.49.

" . - " F# + F-% " .- - " " - . " A "- " - " ? $ F " " -" " A % , . *% % --. % A% < % % C(::3D KK# # A , - . GG Cement and Concrete Components 19 ;9@93 " . . )- %

FIGURE 11.50. ! " A . - .

- % , . *% % --. % A% < % % C(::3D KK# # A , - . GG Cement and Concrete Components 19 ;9@93 " . . )- %

((%; ), ! *!+!)V) ), , AA A, A ++!

575

FIGURE 11.51. CD # " A - " 4$.$- #. #H # $ - % C#D + #. -% , . *% % --. % A% < % % C(::3D KK# # A , - . GG Cement and Concrete Components 19 ;9@93 " . . )- %

- - " C%% *$ &''D " >

% " - " A - " 4 . - #. " % ((%9( "- " #. $ - - % ((%9(#% A - # " " - " ,+ . .- # " " #. - "% ((%9& - " # " #. - % -- " #. - "" &( .

576

1 +), (( *- -> # -

FIGURE 11.52. CD A " . - #.% C#D A - " #.% , . *% % --. % A% < % % C(::3D KK# # A , - . GG Cement and Concrete Components 19 ;9@93 " .$ . )- %

" ;3 9'' -# " " - - " &3$. . " #- - % ((%9&% " " . # ,+ .# &9 ''' -# "% " - " - " " - " #.% #- " "" - " $# " " ,+ .-

" #. . " # "

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577

A .# " " ,+ -% " #"

# " " #. " - . .- .% " #. - " " ,+ . .- # " . # " #.% " " - - # - " # " .# #. -% " " - #- - A #- . . " - > -% -- 49 A .# " #.

-% " # - " . " - " - "- - %

11.4.4 Network of FBG sensors for test bridge damage assessment < . et al. C(::2D # --- - .- -> ;5 A " . " #$ " " /$- -# # " (&%&9 . C;' D$ % " # " . 4%49 . C(( D '%(9 . C2 D " -$ -#

# " . - 7&( 2& - #. " (&%&9 . - N " ". % ((%94% " # -- - .

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- F# " (& A # - #@+ F- -? F#

"% " . .- " " % ((%;; > " . "- " " " "% " . - # (9' 1?% )!)

(%4 m. > (& A . " ;9 . - " +

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- " # -

578

1 +), (( *- -> # -

FIGURE 11.53. ". -# . - # # . " A " . . #-% . *% % --. % A% < % % +. *% % #- )% 6% ,% !% < . *% C(::2D KK1" $ A . . !$- *

- GG SPIE 2718 4'4@4':%

- A - . - 3( 1? " (& C et al. (::2D% - $. . A C$3D C. D . #-? " " " " > .N " . A

" . % " A " # -. # " - - " " " C % ((%9;D% " " "$ . " A C D " - A C(@(&D " % " - - -- " F - " $#.

"- " " " # " - % A " - -- "

" - $#. % ((%9; "- A C$( $:D " " . . %

((%; ), ! *!+!)V) ), , AA A, A ++!

579

FIGURE 11.54. CD * A - . -# # % C#D A - % . ,% !% 7" <% ,% + 6% 7% L " % % " % % % % *% % C(::5D KK* )- 1" - # GG Fiber Optic Sensors for Construction Materials and Bridges % C)D%

%(9:@(23 " . +#-" % %

F -. - " # F " - # -- . " " . #- - " ;5 A C % ((%9;D% - - # " F#

% " +:' - - " ... .>..

580

1 +), (( *- -> # -

- " " A .% .>.. 9'' me >

" . " .- - - - % " A . . - "

" " 45 -- " . " - " # " -% . - " . . " " " - % ((%99% " -- # " &2" " " . . . " " -- " " " # # " C et al. (::5D% .. -- $- " - - # "- H% -" " . # # " B C" "D " # . B - # " " . .H # # " " B " " - "- $ " " . " % " # % ((%92% $- " . CD # 22O - - "- " .- 4'O - " . % " " -

" " . " # # .

. F#

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11.4.5 Interstate highway bridge monitoring by FBG sensor network .H " - F $ # " F#

- . . " $(' #

! *> % " # 42$.$- .

# - - - C % ((%93D% " # " - F- -" .- -> 4& A " - - " " $(' #% -- % ((%95 " A # ( & 4 ; "

(=5$ (=&$ - % " A . " - " "" -" # . "

B

# # . B " " % ((%95#% " A - .-- " F- .

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FIGURE 11.55. )> .- " . . # CD C#D CD .- % . ,% !% 7" <% ,% + 6% 7% L " % % " % % % % *% % C(::5D KK* )- 1" - # GG Fiber Optic Sensors for Construction Materials and Bridges % C)D%

%(9:@(23 " . +#-" % %

582

1 +), (( *- -> # -

FIGURE 11.56. # -- " " . . " % . ,% !% 7" <% ,% + 6% 7% L " % % " % % % % *% % C(::5D KK* )- 1" - # GG Fiber Optic Sensors for Construction Materials and Bridges % C)D%

%(9:@(23 " . +#-" % %

((%; ), ! *!+!)V) ), , AA A, A ++!

583

FIGURE 11.57. +" " $(' ! % . ,% !% 7" <% ,% + 6% 7% L " % % " % % % % *% % C(::5D KK* )- 1" - # GG Fiber Optic Sensors for Construction Materials and Bridges % C)D%

%(9:@(23 # (::5 " . +#-" % %

# -- " -- " - " A # *$ &'' "% " F A C- " (=&$ D " . -- " A . - . - " . $ . " . 4( A % " A # . F# #@+ F- # - " . - ;9 1?% " . - . ".-- -- % ((%9: - " # % " " (2$# - " + F- . - ;9 . ... #- -" " '%3 . /- - - " ( me% 1 " - ... #- # # - (' me # - " .% " ;9 . - " + . . " (2 A " -" '%& . -- #

>.- &%3 . # $ " + F-% " -" F

-- (4'' me " A % " . " A . " "" - ." " -- - "" - % "

- . F - F &' me

584

1 +), (( *- -> # -

FIGURE 11.58. CD ". " $(' - % C#D # A % . L " % % " % % % % -" % *% % ,% C(::5D KK+-. ,- " * $ 4&@"- # A .GG Fiber Optic Sensors for Construction Materials and Bridges % C)D

%(;5@(95 # (::5 " . +#-" % %

> # " A - " # . B 4% "

" -- H " . " " " . - . - . " % " " A - "- $ $4 " # "- - " % ((%2'% . A - "

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B - # ('' me " #

((%; ), ! *!+!)V) ), , AA A, A ++!

585

FIGURE 11.59. . - . " 4& A #

" $(' % . L " % % " % % % % -" % *% % ,% C(::5D KK+-. ,- " * $ 4&@"- # A .GG Fiber Optic Sensors for Construction Materials and Bridges % C)D

%(;5@(95 # (::5 " . +#-" % %

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" - # &9 me% " # . B "

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586

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FIGURE 11.60. . " A . " CD

B C#D # B CD # . B " $(' # " #H F% . L " % % " % % % % -" % *% % ,% C(::5D KK+-. ,- " * $ 4&@"- # A .GG Fiber Optic Sensors for Construction Materials and Bridges % C)D

%(;5@(95 # (::5 " . +#-" % %

" # . B " " . #" 0 . " " -- " F 9 -- # " " " . # 3%9 " . -% . " -- - . # " - -- - .$ " F - " #% - " 4& A -- $ F $ "" # -.

((%; ), ! *!+!)V) ), , AA A, A ++!

587

FIGURE 11.61. . A . " $(' # " F % . ,% !% 7" <% ,% + 6% 7% L " % % " % % % % *% % C(::5D KK* )- 1" - # GG Fiber Optic Sensors for Construction Materials and Bridges % C)D%

%(9:@(23 # (::5 " . +#-" % %

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% " . " #- #" # . #- " % -.- " . # . - . - " # # .- -- $ " - " " "" - # -#- . . %

11.4.6 Serial multiplexing by parallel spectral detection , - . A$ # . $ -- $- " "

F# . " -

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((%; ), ! *!+!)V) ), , AA A, A ++!

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FIGURE 11.65. ! A # " - " " #H - % " . " " A

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- - - " " . - $- -. " " 4$. % " "" A - " - " " $ % " . " A . #/ .# " % ((%22% " - CD " . "

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12.2 FIBER BRAGG INTRAGRATING DISTRIBUTED SENSING CONCEPT " "-- > - " Bragg intragrating C AD .. . # % 7" $ . .. within - % A # " " . " - - # -.% 7" .

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12.4 INTENSITY REFLECTION SPECTRUM FOR DISTRIBUTED STRAIN SENSING " / " . . " B -" " F- " A % " F

" -- . . - . - " % . A " > # # # % " A # " " . # -. " " B . -- " -- A . - . - # " . " . -- " #$% . . " A " " # #H "- " . -- # " . % " # > "" - " -- # " . "

- " . -% 7 . . - . - $" A # . " " F- . " A . " " -"

B - - C

605

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. D " " " -" " AN % (&%3% 7 . " " # " B Rl . " mj C D # #H " B -" lj # " . " -" . . " ... - l. C. - F-D " -" ln # B . " zN %% jn P j(

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606

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-#- . F-% -" " " . -

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- " # . - " % )/% C(&%&4D Dnz " . - " " > " >- % " CD " " C(&%&4D " C D " -

ez # "- " C D % " - " lz X"" - ez " " )/% C(&%4DY

# # / " - " - $ Cl$D " " - " "$ Cz$ " ' z LA D % " et al. C(::2D . " " > . - " -- >- % " . . -F " . #- - - " >- - z - " A "" " -" l B

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(&%; ) ,)!) +),*

607

zl # . C(&%&;D " >- e " - C" " -" B lD . )/% C(&%4D " . e

l l' ; G e l'

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Tunable DBR Laser Diode

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Wavelength FIGURE 12.8. )> .- . . " - " A # " B .% . " *%*% 1 %% ! - *% * ,% C(::2D KK# ! # AGG SPIE 2838 22@39%

# " " " % " #-. # -- . > # " " A (&%('%&% " /- - # " " - $ . - " % 7" F # #- .. . - " . . .

F- # - C % (&%('D% " . " - "/ # - # # " et al. C(::2D% " > . 9$.. - A C"" -- .D # "

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609

FIGURE 12.9. CD ,B " A -" # " . - " C10 3 %.. 12 D% C#D " " " -" . # " B . "/ " . - " % . " *%*% 1 %% ! - *% * ,% C(::2D KK# ! # AGG SPIE 2838 22@39%

" et al. C(::2D 1 et al. C(::5D # interferometric technique " # " spectral integration "/% 1 - -. . F-

" . -> " .. .# " " ." > " F- . #- .# " " "/ # " -. "" # " > %

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1 +), (&

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file on Pro egi ain ient R r t d tS Ne w Gra e to g o L Du ratin n i No fG tra sS po Bia -Chir Pre Strain Profile Low Gradient Regions

Effective Strain Profile, ε(z)

Axial Position Along Grating, z

ile rof n P onic i a r not t St Ne w Mo No

o e t ing Du rat n G i a f Str irp o as Bi e-Ch Pr Strain Profile Including a Reversal

Axial Position Along Grating, z

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611

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12.5 DISTRIBUTED STRAIN SENSING BASED ON FOURIER TRANSFORMS F

# " et al. C(::3D #- KK-GG # # F- " - F# .# " .. .# " . -%

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612

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613

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&pnz lz

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614

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12.6 EXPERIMENTAL FOURIER TRANSFORM DISTRIBUTED STRAIN SENSING " -. > . . # 1 et al. C(::5D

" . ." . " #

F- . F# " ".-- % (&%(4% #- , -

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615

(&%2 )V+),*) ! ,), , ,* Reference Photodetector

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86 mm

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Mirrored Tip Reference Optical Fiber

(a) Applied Force

Beam Clamped

86 mm Fiber Bragg Grating in Groove

Specially Shaped Aluminium Cantilever Beam Resistive Foil Str ain Gauge on Underside of Beam

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" -- " - #. " " - " #.%

616

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F- " F- . F # " " - %

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" " H " " $ - -

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FIGURE 12.16. CD " > .- . - ;$.$- A

H " - - - -% " - F- . . " . " " C " . #- - . " (&%(4D -" - # " - "

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12.7 FOURIER TRANSFORM FOR SERIAL MULTIPLEXED FIBER GRATING SENSORS -

- F# # " " > A " ? B # .# -. #- " " .

" ." - # - " # . " - A % " - ." - .- -> - A " " - " / -" .- -> " -

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620

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622

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623

12.8 LOW COHERENCE TECHNIQUES FOR DISTRIBUTED SENSING .# -

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624

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12.9 DISTRIBUTED SENSING UNDER SIMULATED BRILLOUIN SCATTERING 7 " 2 2%2%( " -- - - -" # --

- " . $ " - # " " " " /

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Time of Interaction (t/2)

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A 6% C(:5;D% Optical Communication Systems +$1-- - ! % A <% % L% * % % C(::9D Optical Fiber Sensor Technology, " . 1-- ! % A 6% % * " <% % % ,% - ,% % L % *% C(::&D% KK - # L# $* - +" , $ > AGG Smart Materials & Structures 1 &;4@&;:% A 6% % 6 *% )% % % * " <% % C(::2D% KKA$ - #$ GG SPIE 2718 (3'@(3;% A 6% % 6 *% )% +% A% < ? % !% - % % * ,% A% * " <% % C(::3D% KKA$ - # GG SPIE 3042 &2'@&22% A % % - <% C(::&D% KK . ," " 7" !# GG A , % &3@( &3@&:% A. +% C(:5&D% KK) / " " " A .- "GG J. Mech. Phys. Solids 30 44:@494% 1#- 7% ,% 1--. % C(::9D% KK,- * . . ! - # * # GG SPIE 2446 &9@42% 1#- 7% 1

*% % + - 1% C(::;D KK" B -- - - # GG 2nd Europ. Conf. on Smart Structures & Materials + % (25@(3(% 1#- 7% ,% + - 1% C(::;D% KK" B . - *- + -. ).# - # GG G(' (@:% 1#- 7% ,% 1 . % 1--. % % C(::2D% KK# . ! . . " . *-GG Engineerinig Mechanics Proceedings of the 11th Conference C% <% ! % % )%D 499@495% 1F- +% C(::9D% KK = 7 A. +- ,

GG New Scientist #% 9% 1- <% % C(::&D% KK -$# $ * .GG ( )

% . *- A- SPIE 1777 (;3@(9'% 1- <% % 1 "-- % % " - A% C(:5'D% KK"

- - # 7 " )- GG - *. % , *(,3&.D $,$5''2% 1.- A% C(::2D% KK* . GG Equinox *"= - 93@24% 1 6% C(::9D% KK . *-GG Fiber Optic Smart Structures C)% )%D &4@9:% 6% 7- Q % % 1 % 1% !" % +% A - *% +% C(:59D% KK# . -$ #GG Electron. Lett. 21 ('2(@('2&% 1-" 1% 7% 6% % C(:5:D% KK * - # GG + % # . SPIE 1170 ;9&@;2(%

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1 1% % C(:5;D% KK* .GG Waves and Fields in Optoelectronics C1 - % )%D " % 4 99@5'% +$1-- )-

- % 1 1% % ! % C(::(D% KK $ # # ,B GG J. Lightwave Tech. 9 39;@32'% 1 =% % " +% A % C(::&D% KK - +" #@+ )- 0 - GG Optics Lett. 17 22;@222% 1 % + .. (::5% 1" 6% C(::2D% KK# +G GG New Scientisit % &;% 1" 6% C(:::D% KK $! + . , "GG Laser Focus World * (&3@(;4% 1" )% TH % C(:3;D Optics, $7-% 1 +% 6% , % 6% 6 % % T" !% % C(::3D% KK.- .$ . * 7-" *- -> #$#@+ 7" ! $ " GG (&" - # # &2@&5 7--.#% 1. A% % A 6% 6% % C(::(D% KK

- . 1-" * GG J. Intel. Mat. Syst. and Struct. 2 ;((@;4'% 1-- <% % C(:3;D% KK + #$+. 7 GG Applied Optics 13 (594% 1-- <% % *-? A% C(::3D% KK# A " - .- GG J. Lightwave Technology 15 (&24@(&32% 1-- <% % H % 6 " % % < % % C(:35D% KK+" - # 70

- ,B - # GG Appl. Phys. Lett. 32 2;3@2;:% 1-- <% % *- % - % 6 " % % -# 6% C(::4D% KK A # * . +" - # # L )> " " +" *GG Appl. Phys. Lett. 62 ('49@('43% 1H-. % ,% % ,.#" 6% % % C(::2D% KK*- -> # $A . * L"- GG SPIE 2838 ;'@9(% 1H-. % ,% H !% % ,.#" 6% % 6% L% C(::3D% KK

- A " "? - * L"- * -GG Applied Optics 36 4&5@442% 1 % C(:53D% KK# . . GG Composites 18 4':@4(2% 1 % ,% % * ,% *% C(::'D% KK+ -. # - "? GG SPIE 1170 9;&@99'% 1 % 6? % L- % * ,% *% C(::(D% KK-

. # #@+ AGG SPIE 1588 # . L 4''@4'3% 1 % 6? % * % L- % * ,% *% C(::(#D% KK-

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.GG Optical Fiber Sensors: Applications, Analysis, and Future Trends L -% ; " 1

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1"- )-- - $* #GG J. Lightwave Techn. 8 &4@ 44% 1 % ". *% *% ! - *% ! ,% * ,% *% C(::;D% KK# $A # GG SPIE 2294 5(@:&% 1 % ! - *% " *% *% * ,% *% C(::9D% KK $ A - GG Applied Optics 34 9''4@9'':% 1 % ! - *% " *% *% * ,% *% C(::9#D% KK $ A - GG Applications of Photonic Technology CA% !.

$ - 6% " ,% *% * )%D 4(3@4&'% +-. + % 1 % " *% *% ! - *% ! ,% * ,% *% C(::;D% KK# $A # GG SPIE 2294 5(@:&% 1 % ! - *% ! *% * ,% * ,% *% C(::2D% KK# # " "

- GG Advanced Composite Materials in Bridges & Structures C)-$ *% *% )%D ::(@ ::5% " - ) * -% 1 % " *% *% ! - *% * ,% *% C(::5D% KK # + F- *. " # AGG Smart Mater. and Struct. 7 &;5@&92% 1 % ,% " +% !% - 6%$A% C(::(D% KK- *.# L# # GG J. Sound & Vibrations 149 4;5@494% ,% !% < . *% % < % *% C(::3D% KK*- -> A - # . )- 1" GG Smart Material and Structures J. 7 &':@&(2% ,% !% 7" <% ,% + 6% 7% L " % % " % % % % *% % C(::5D% KK* )- 1" - # GG Fiber Optic Sensors for Construction Materials and Bridges C % )%D (9:@(23%

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? <% C(:54D% Optical Sciences: Engineering Optics @L- -% . % C(:5:D% KK! - * - ! GG Optoelectronic Technology and Lightwave Communications Systems C! % )%D L ," - &2;@&:5% . % <% 1% C(::3D% KK > A # )$

- #GG (&" % % - # 7--.$ # &&9@&&5% % C(::3D% KK-

- # -. - GG (&" % - # 7--.$ # 9:2@9::% % C(::3#D% KK# . GG Optical Measurement Techniques and Applications C, +% <% )%D " 1 &99@&3;% % )-. % +B !% A % 6% L -- % C(::;D% KK! $ " . " * -$) GG Sensor and Actuators 44 (&9@(4'% % L-- !% +B !% L -- % 7 % C(::9D% KK! $ " . " * 7 GG SPIE 2444 (3'@(35% % % < # +% L -- % C(::3D% KK,- * -GG SPIE 3043 95@2;% % % < # +% *?? % L -- % C(::3#D% KK).# * # - - * $ GG +) . *- (@5% % L -- % % C(::2D% KK * # $ . . GG +) - +" " . .

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. - . ).#GG SPIE 2721 (45@(;5% % L -- % ! % C(::2D% KK$! " *- -> -. # )> .GG SPIE 2718 &9(@&93% % L -- % < # +% C(::5D% KK* # - . # GG Smart Materials and Structures J. 7 (::@&'5% % et al. C(::9#D% ! " F#

- . $ % Structural Engineering International (=:9 5 ;4@;3% 6 % % C(:5(D% KK + - +" # .GG J. Phys. E: Sci. Instrum. 14 (&3;@(&35% 6 % % 6 6% % % C(:52D% KK# GG Optica Acta 33 (;2:@(9'4% 6 % % 6 6% % % C(:5:D% KK .GG Optical Fiber Sensors: Systems and Applications L -% & C-" % 6% )%D " 1 4&:@45'% 6 % % < % % *% 6 6% % % C(:5&D% KK+ $ 1 ". - .GG Electron. Lett. 18 ('5(@('54%

676

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6 % % ! # ,% , !% ".#- 6% !% C(::4D% KK. - *- -> ". #$ A GG Optic. Lett. 18 ((:&@((:;% 6. % 7% *% !% . ,% +% C(::2D% KK. - # A L -. 1 - .GG SPIE 2838 9&@93% 6. L% 1.#" *% )% - !% % # % +% C(::;D% KK7- #- $7 A +=+ . - A !GG Electron. Lett. 30 (;:&@(;:;% 6 % 7% 6% % C(::9D% KK . " ).# - #GG Fiber Optic Smart Structures C) )%D (':@(&'% 6 % 7% +- 6% 6% % C(::&D% KK+ . A "= .-. !. " ).# - # + 0 >- GG Smart Materials and Structures 1 4(@49% 6 % 7% +- 6% 6% % C(::&#D% KK+ . A "= .-. !. " ).# - # + 0 >- GG Smart Mat. & Struct. 1 &;@4'% 6" .. !% % C(:54D% Single-Mode Fiber Optics Principles and Applications * % 6-- 6% !% -#" A% ,% C(::&D% KK $). ! ). . " !# GG Laser Focus World * &(3@&&4% 6-- 6% % - % % C(::(D% KK . *" *. ". $ ".- )> FGG Appl. Optics 30 4292@422'% 6-- 6% -#" A% ,% ,% +% " % C(::&D% KK $). ! " , GG Photonics Spectra % (&2@(4'% 6 V% % 6% % C(::3D% KK - # .- *. . GG SPIE 3042 (&'@(&3% 6 6% % % C(::3D% KK, # "/ . @ . GG (&" % % - # 7--.# &'@ &4% 6 6% % % 6% % C(::3D% KK#$ * ) GG Optical Fiber Sensors L -% ; C 6% " % )%D " 1 &'3@&9:% 6 *% )% A % " L% * " <% % - ,% % *-- % )% L % *% C(::9D% KK$! # . - A GG SPIE 2444 &;5@&92% 6 ,% % --. % A% % % 6% % *% % +. *% % #- )% 6% < % % C(::5D% KK. - +- " 7-" *- -> # A !$/ $ - ".GG Smart Materials and Structures 7 (35@(55% 6 ,% % % % --. A% )- % % 6% % +. *% % #- )% 6% < % % C(::2D% KK- +- . * 7-" *- -> # A GG SPIE 2718 &95@&23%

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677

6 ,% % % ,% 1% A-- +% % % C(::'D% KK #$ ! 6 , GG Mag. Concrete Res. 42 9@(;% <-. % !% * - % % 7" +% % % C(::3D% KK+-

. ,+ . GG SPIE 3042 ;''@;':% <-- <% A% 7## 6% % , !% ".#- 6% !% 6 % % C(::;D% KK+ #-

" " .- *. . L . A GG ('" - # A-- - % <--

- % )% 1 L% % , % 6% C(::9D% KK.- . " +" $# AGG Opt. Soci. Am. 20 444@449% < % " 1% ". % .. *% " % C(::4D% KK , 7-" " A # ,B$ !GG Electronics Lett. 29 (':(@(':&% < <% % 1 ". A% % C(:22D% KK-$# 7 - /GG Proc. Inst. Electr. Eng. 113 ((9(@((95% < % +% 1% 1% C(::(D% KK" *. + # ! .GG Optical Eng. 30 3''@3'5% < <% !% * - % C(::9D% KK-- # # " " " " < - - ) GG SPIE 2444 :;@('9% <" ,% C(::;D% KK+" - #0

- GG Optical Fiber Technol. 1 (3@&;% < . <% C(::;D% KK " . .

- GG Laser Focus Worlds ::@('2% < % % C(::9D% KK# *- -> "/GG Fiber Optic Smart Structures C) )%D ;':@;;;% < % % C(::3D% KK*- -> "/ #$ GG Optical Fiber Sensors L -% ; C 6% " % )%D " 1 42:@;'3% < % % C(::3#D% KK - # GG Optical Measurement Techniques and Applications C, +% <% )%D " 1 &(3@&9;% < % % % % C(::4D% KK#$A " $ . 1"$, - . 7-"$" GG Optics Lett. 18 3&@3;% < % % % C(:55D% KK# *- -> # GG G55 - 2'@3(% < % % * 7% 7% C(::4D% KK*- -> A #$! $ . " * $! GG Electronic Lett. 29 ((&@((;% < % % * 7% 7% C(::4#D% KK*-$)-. $A #$! GG Electronic Lett. 29 :2;@:22% < % % ! % % 6 % % C(:5;D% KK+ $1 ". " A

GG Electronic Lett. 20 425@43'% < % % *% 6 % % C(:5;#D% KK!? ,. * . # + -. GG SPIE 514 - # G5; &;3@&9'%

678

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< % % % % * 7% 7% C(::&D% KK#$A " +" GG ( )

% . *- A- SPIE 1777 2(@23% < % % % % * 7% 7% C(::&#D% KK1"$, - #$ A " . 7-"$" GG Electronic Lett. 28 &42@&45% < % % % % * 7% 7% C(::&D% KK $"- # $A " 1"$, - . 7-"$ " GG # . Q L SPIE 1798 ;5@99% < % % #- )% 6% 7 ,% % C(::&D% KK)#.$

# , ! GG # . Q L SPIE 1798 &5'@&59% < % % % % * 7% 7% C(::4D% KK*- -> # A $. " # #@+ 7-" -GG Optics Lett. 18 (43'@(43&% < % % <

<% +% *% % C(::;D% KK# A ! GG SPIE 2292 # ! V ('&@((&% < % % *% % % % % 6 ,% % % -- A% 7 A% 1 A% % + <% < % C(::3D% KK ! * . 1-- " # # A GG SPIE 3042 ;&(@;4'% < % % *% % + 1% 6% ! - *% <

<% +% % A% +. *% % #- )% 6% C(::3#D% KK# A GG J. Lightwave Technol. 15 (;;&@(;24% < % 1 *% < # <% " % C(::4D% KK -. > # )- GG Optics Lett. 18 52;@529% <. % % - 6% % 1 % % " 1% 6% C(:53D% KK 1"- )-- # $* # GG Opt. Lett. 12 3&:@34(% <.$6%% C(::9D KK, # . ! -? - ". 1" +-$A GG Proc. SPIE, Smart Struct. & Mat. . . 1"% <. <% % .- % A% % C(::4D% KK*. . " ).# #@+ - # GG J. Composite Materials% <# A% % ! % <% *% % < % % C(::9D% KK .- ! " ). . GG SPIE 2444 423@432% < . *% % ,% !% C(::2D% KK . 1" * GG . Q *- . . 1" &5@&: # (::2 % < . *% % ,% !% < % % *% % --. % A% #- )% 6% +. *% % C(::2D% KK. . -- - - # * .GG SPIE 2719 &29@&39% < - 1% C(:32D% KK- , $ . -. + GG Bell System Tech. J. 55 (':@(&2%

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# % )% * " <% % +- % 6% L- % *% - ,% % C(::(D% KK1" . #@+ GG Optical Fiber Sensor-Based Smart Materials and Structures " . +#-% (55@(:4% < - )% % C(::9D% KK"/ * -"-- # +" $ GG Applications of Photonic Technology CA% % !.

- 6% " ,% *% * )%D ;(4@;(5% +-. + % <-# 6% % ".#- 6%$!% , !% 6% )% L A% A% + % % C(::;D% KK1"-$) F ! $ A$# )4: #4

# !GG Electron. Lett. 30 :3&@:34% <".

" ,% <% -# % """ <% 7 % )% C(::3D% KK1# . ,# . GG SPIE 3043 29@3(% < " % % C(:55D% Fiber Optic Sensors Fundamentals and Applications . .% < # +% % % L -- % C(::3D% KK. * $ " # . GG SPIE 3043 &@((% <"? % - ,% % * " % * ,% A% A" *% % C(::&D% KK - # " = *. GG ( )

% % . Q *- A- SPIE 1777 &;(@&;;% < 6% 1% * % +% 7% C(::&D% KK. . - $)-. -GG Smart Mater. & Struct. 1 ('5@((&% <". % C(::'D% KK# . .- -$ - - - #GG Optics Lett. 15 ('45% <". % 1 H" % "? % 1% *% C(::(D% KK*. # ! , #. - # #-GG Appl. Optics 30 44;@443% <". % *% 1 " % < . C(::3D% KK+ . . . .# , # ! *. # , .? " , !" + -? GG IEEE Photonics Technology Lett. 9 42'@42&% <H % ,% % C(::(D% KK *"- +

!"0 ..GG Optical Engineering 30 25(@25:% <H % 1% C(::(D% KK - # ,-#-GG Opt. Eng. 30 23:@25'% <H % ,% < 6% % *" *% 6% C(:5:D% KK"

- - #GG J. Lightwave Technol. 7 (42'@(43'% !. % % 7% A % C(:5(D% KK"? - * #GG Appl. Opt. 20 ;;'@;;9% !.#- +% H--? +% % !.# 1% A% -"R ,% +% T.. % A- 1% 1% C(::4D% KK A "? # - ! $ " ,B$ .GG IEEE Photonics Tech. Lett. 5 929@923% !. ,% % + % % C(:5:D% KK)- ). - 1"- - #GG J. Lightwave Tech. 7 &'5;@&':;%

680

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! % *% - % L% . 6% ,% % )% C(::2D% KK*. + $ . *- ).# # GG SPIE 2718 2'@25% ! % - % % )% C(::3D% KK-

. " > . # A GG SPIE 3042 &&:@&42% ! % *% - % L% % )% C(::3#D% KK*. " # AGG SPIE 3042 &(5@&&5% ! % *% - % L% % )% 6% ,% C(::3D% KK. + $ ,- . *- ).# # GG SPIE 3042 (9;@(23% ! - *% C(::5D% KK *" ).# -$) # - $ *. "/GG +"%% "

% ! - *% < % % C(::3D% KK# $A #@+ 7-" ! $ " .GG (&" # # &2@&5 7--.#% ! - *% * ,% *% C(::&D% KK. . . . $ *- " ).# # GG J. Composite Engineering 2 934@ 9:2% ! - *% * ,% *% C(::4D% KK* ."- ).# -$) GG . *- -#// SPIE 1918 &(9% ! - *% * ,% *% C(::9D% KK# . .GG Fiber Optic Smart Structures C) )%D 95(@2(4% ! - *% 1 % " *% * ,% *% C(::;D% KK#- " # A - .GG Electron. Lett. 30 &(24@ &(29% ! - *% 1 % * ,% *% C(::9D% KK# $ A A GG SPIE 2444 (42@(;3% ! - *% 1 % " *% * ,% *% A. % " % C(::2D% KK# *. # A ,B$ . -GG Opt. Lett. 21 (;'9@(;'3% ! % !/. *% L +% ! % 7" % ,% *% "?- 6% -" % *" % +

- +% C(::4D% KK " ,)$), * . + HGG SPIE 2075B-43 3@ (' % ! % C(::5D% *% %% " - ) % ! % )% - 1% % C(:55D% KK . # - * GG Electron Lett. 24 (:4@(:;% ! % )% - 1% % C(::'D% KK . # . ! " !" GG SPIE 1370 # . 492@42;% ! % )% - 1% % C(::&D% KK$! # #@+ . " 1" ,B - * GG + % 5" % % - # +G:& ('9%

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681

! % )% - 1% % C(::9D% KK . " #@+ .GG Fiber Optic Smart Structures C) )%D &;:@ &3'% ! % )% - ? 6% 6% A#- 7% ,% % - 1% % C(::(D% KK*" ).# - # - # *- $ GG SPIE 1588 # . L (('@((2% ! % !% C(:52D Electromagnetic Principles of Integrated Optics 6% 7- Q % ! 7% 1 % - 1% % 6. ,% ! % )% L% A#- 7% % ,% % A. 7% A% C(::3D KK,- . " # GG (&" % % - # 7--.$ # ;(&@;(9% !. +% 6% ,% *% L?" L% , 7% % C(::4D% KK1" + 1& ! "/ " -"" L +" ". A&

- #GG Electron. Lett. 29 ((:(@((:4% ! )% 6% C(::2D% KK"$ - . . GG Laser Focus World % ('4@((&% ! )% 6% C(::2#D% KK -" +" " +" GG Laser Focus World % :4@('&% ! )% 6% C(::2D% KK .

- GG Laser Focus World * :4@(''% ! )% 6% C(::2D% KK 1" GG Laser Focus World 6 (99@(2;% ! )% 6% C(::5D% KK ! !" .. +GG Laser World (&4@(4&% ! 6% . A% , <% L % *-- % % - ,% C(::(D% KK

- #@+ # . *

* -GG Optical Fiber Sensor-Based Smart Materials and Structures " . +#-% 29@2:% ! 6% 6% . A% +% % ,% *-- 7% L% L % *% , <% !% - ,% % C(::&D% KK).# #@+ # " * . - . GG Opt. Eng. 31 (4@&'% ! % <% % )- % - % C(::3D% KK - # GG SPIE 3042 &54@&:&% ! !% C(:5'D% Applied Optics L -% & 6 " 7- % ! <% C(::2D% KK+- - . 1"GG Laser World 6 :2% ! <% C(:::D% KK- -# # * GG Laser Focus Word .# 44@49% ! A% +% * % *

,% +? % C(::&D% KK(%99 m. >=A - ! " $! *-$=. 7-- AGG Electronics Lett. 28 (3&2@(3&3% ! *%$6% H F % % C(::4D% KK+ -? A$ 7 ,B GG Appl. Optics 32 ;9(3@;9&(% ! % C(:5:D% Optoelectronic Technology and Lightwave Communications Systems L ," - %

682

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!# % < % <% C(::;D% KK -$# $ * # " $ GG Smart Mater. Struct. 3 (2;@(3'% ! <% * ,% *% C(::&D% KK- + "/ ! -? . #$ GG J. Intell. Mat. Syst. Struct. 3 ;4&@;2(% ! <% * ,% *% C(::4D% KK - * $ . - *. " ).# #$ GG Smart Mater. Struct. 2 22@3'% ! <% % *% * ,% *% C(:5:D%GG . . " ).# # . KKSPIE 1170 # . &'9@&('% ! <% % *) <% )% * ,% *% C(::'D%GG ). . ).# -$ * # . GG SPIE 13700 # . 4(2@4&4% ! %

% * % ,% A% % C(::2D% KK # )- - # - Q . *. " 7" !" .GG SPIE 2718 ;'5@ ;(2% ! % A% % , % 6% T" !% % 6 % % C(::3D% KK.- . *. . *- -> # A )> #@+ GG SPIE 3042 &'4@&(&% ! % A% % T" ! % , % 6% 6 % % C(::3D% KK.- . *. .# # A=)> #@+ GG (&" % % - # 7--.# &'@&4% ! % 7 *% A% % , % 6 % % C(::3D% KK *- -> )> #@+ .GG Smart Mater. Struct. 6 ;2;@;2:% ! % 7 *% A% % , % 6 % % C(::3D% KK *- -> )> #@+ . $ . . $ . GG SPIE 3042 &:4@4'4% ! % !% 6% % C(::3D% KK. - *" * . > .- - $# $A GG Smart Struct. Mat. 1997 SPIE 3042 &43@&;4% ! % C(::'D% KK) # " - ,+ . GG *% %% " C".- )%D% ! <% % A% 1. % * A% T... % C(::9D% KK# * -. , F " . 6 ->- ! GG SPIE 2446 (2@&;% ! -- +% % + % 6% C(::3D% KK ,. 7- . . * " 1-" ! - GG SPIE 3043 (&@&&% ! T% 6% -" % % C(:5:D% KK # . . . *-GG SPIE 1170 # . &4:@ &;&% ! T% 6% -" % % C(::(D% KK

- # GG SPIE 1588 # . L &32@&5(%

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* 6% 7% T" 7% C(::3D% KK $ ) # .- *. . GG SPIE 3042 &(4@&(3% * ,% - % * ,% *% " *% < % A- % 7 % A% ,?-- % C(::;D% KK# A -- , GG SPIE 2191 ;93@;29% * ,% - % * ,% *% A% ,?-- % 1% A"$ " % C(::3D% KK#$ A * GG Cement and Concrete Composites 19 &(@44% * ,% - % % * ,% *% C(::5D% KK , )> * " # A GG Fiber Optic Sensors for Constructional Materials and Bridges C" )%D (&:@(49% * % , - % L-- *% +% C(::3D% KK$ $ )- " # A , 0

- . # . ) # GG Applied Optics 36 :;43@:;;3% *" *% 1% )% A% C(::4D% KK)- # A 1" " .GG Applications of Fiberoptic Sensors in Engineering Mechanics C" )%D (&'@(44% *- % 6 " % % - % -# 6% 1-- <% % C(::4D% KK-$ )>.$+- 7 # A # T $ -- +" *0 A - , L-? > +# GG Opt. Lett. 1 (&33@(&3:% *- % "- % 6 " % % - % -# 6% 1-- <% % C(::9D% KK $# A ,B +" . +" * 7" L#- ) FGG Electron. Lett. 31 &&&@&&4% * % A 6% < 6% % C(::4D% KK " -$

- 1-" * GG SPIE 1917 . *- -#// #% (@;% * % C(:5&D% KKB " ! #- - #GG Appl. Optics 21 ;&'5@;&(4% * % C(:5:D% KK#$ - " #@+ , GG J. Lightwave Tech. 7 52:@532% * 6% -- % C(::;D% KK - 7 "/ ! 1"- ,B $# AGG Electron. Lett. 30 5((@5(&% * % ,% 1 % % A% % 1- <% % C(::9D% KK. . -. 7 # -? ).# - #GG SPIE 2444 ;':@9'(% * % ,% "- % A% % C(::3D% KK - #$ GG Photonics Technology Lett. 9 :5&@:5;% *" +% *% A% 7-- % A% * % - A% 7-$ "% < 1% <% C(::5D% KK - . . ! + .GG )- ".% % . % !" ). -%

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. . GG SPIE 1588 # . L 32@59% * ,% *% C(::&D% KK. . " ).# GG J. Composites Eng. 2 9:3@2(5% * ,% *% C(::&#D% KK. , - - )GG < . *- <% 7% - +% !# _ )% " - ) * - 4(@9:% * ,% *% C(::4D% KK# . . GG Composite Eng. 3 3(9@39'% * ,% *% C(::9D% KK# GG Fiber Optic Smart Structures C) )%D (3(@&;3% * ,% *% 1 % ,% % L-- % A-# *% 6% C(:55D% KK-- # , GG SPIE 986 # Q 4&@;&% * ,% *% A-

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* ,% *% - % < % % C(::4D KK. " , - 0 A ! " K GGG SPIE 1918 . *- -#// # (@;% * ,% *% 1 % ! - *% " *% - % % C(::;D% KK $A . - . GG SPIE 2191 ;42@;;9% * ,% *% - % % * ,% " *% < % 1 % C(::9D% KK -- A ! . # # + 1" GG Smart Materials & Structures 4 &'@4'% * ,% *% 1 % ! - *% ! *% " *% * ,% C(::2D% KK# # - A ,B GG SPIE 2838 4(@4:% * ,% *% " *% *% 1 % % 6% % % C(::5D% KK#- ! . - L # A * -GG Smart Materials and Structures 7 &43@&;3% * % *% * 1% "- A% C(::&D% KK" " ,+ !.0 ,"

- ?-GG Advanced Composite Materials in Bridges and Structures C- <% 7% !# +% )%D - ) &;4@&9&% * % *% * 1% "- A% C(::4D% KK" " . GG . Alternative Materials for the Reinforcement and Prestressing of Concrete C6% !% - )%D " . Q 1-- A- % * 6% 7% - L% <- % C(::3D% KK * + GG (&" % % - # 7--.# ;'5@;((% *-- % *% C(::;D% KK G . G GG Photonics Spectra 55@:;% *-- % *% ! <% * ,% *% C(::(D% KK # AGG SPIE 1588 # . L

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SPIE 1798 &&3@&42% *-- % - % < % % ! <% * ,% *% C(::4D% KK A$ # ! .GG Photonics Technology Lett. 5 &24@&22% *-- % *% ! <% * ,% *% C(::4#D KK+- # A A .GG Applied Optics 32 42'(@42':% *-- % A. - % % - A% *-- *% C(::3D% KK-$

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- ).# # , - GG SPIE + % 1170 # . % Q 2'@2:% *R? % * % % ," !% 6% C(::4D% KK)> .- ,- ).# - # GG SPIEE Proc. 1918 . *- -#// *% * % -- % +% C(::9D% KK -0 )>.- ! GG Structural Engineering International 6% ;5@9'% *?#" % % < % % #- )% % C(::2D% KK# 0 ,GG Smart Mater. Struct. 5 (:2@&'5% *- ,% C(::9D% KK * " - ! GG New Scientist 6% &( (2% *"- % C(::;D% KK# < 7 " GG Photonics Spectra * 9&% *" 7% % -" % , # % % 6% ,% C(::(D% KK# "/ .- *. . L . *-GG SPIE 1588 # . L 4;&@ 492% *" 7% % "# A% 6 " 7% -" % C(::&D% KK "/ . " ) >$,$ .GG # . Q L SPIE 1798% *" % -" % "# A% 6 7% < *% C(::2D% KK . *.GG SPIE 2718 (4;@(;2% *" % -" % "# A% < *% *% ! % " % !/. *% L +% L % ! % <-# +% ,% , # % +

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-- - # AGG SPIE 2718 ;&3@;45% * % " % C(::(D KK!$ . #- 7$A )- $ # * - GG Can. J. Phys. 69 ;:3@9'3% * - +% C(::&D% KK#- -$ !GG IEEE 80 4;5% * % % ) *%$ % 6 !% A% )% C(::(D% Advanced Composite Materials with Application to Bridges KK " + #-GG &45@ &4: - ) * -% * % % ) *% % 6 !% A% )% C(::&D% Advanced Composite Materials in Bridges and Structures in Japan - ) * -% *" 6% % C(::&D% KK- ,## # GG Photonics Spectra 6- :5@454% *-"-- +% C(::3D% KK* - # A " )>. ! 1"$ *- -> ).#

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" # . * -. *. 1" . GG SPIE 1588 # . L ((3@(&;% * " <% % A" *% % L % *% - ,% % C(::(#D% KK#@ + # --$- $(9 GG SPIE 1588 # . L (4;@(;;% * " <% % A" *% % L % *% - ,% % C(::(D% KK= +"$" )> #@+ - # GG Optics Lett. 16 &34@&39% * " <% % A" *% % 7 % - ,% % C(::&D% KK)> #@ + - # GG 5" - # * (:4@ &''% * " <% % A" *% % - ,% % % % *-- *% % C(::4D% KK - # *. 7GG . Q *- G:4 -#// SPIE 1918 (('@(&'%

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SPIE 1798 (&;@(44% " % <% - A% 7% A F % )% 1 % % 1 % ," !% 6% + % % * % % C(::(D% KK+ -. ).# - # GG - SPIE 1489 (3@4&% 1% A% 6% % +% C(::'D% KK. F *" - GG % % - ,-#- ) (453@(4:4% "" 6% ,% % L A% % - % % C(:23D Atomic Light Lasers, - +#% % -- +% *% +% . ,% " % C(::3D% KK

-$ # - , A ! $. -- - ) GG SPIE 3043 33@52% -- +"% *% % * +% " % C(::5D% KK! . ,-#- ).# - #GG Fiber Optic Sensors for Constructional Materials and Bridges C" )%D (54@(:4% . )% A% C(:5:D% Single-Mode Fibers $L- -% "

6% +% * % % C(::2D KK , -$ -# " -. , GG Concrete International 18 4'@4;% - % C(::'D% KK, ,GG New Scientist % 43% % +% " % 6 6% % % 6 % % C(:5:D% KK, . ! +" . - . # GG Apo. Opt. 28 ;&('@;&(9% - *% "? !% , # +% % C(::;D% KK. - # . -- A . -GG ('" % % - # A- - SPIE 2360 (45@(;(% . ,% !R % " % 7--. ,% !% C(::(D% KK* -" $). . L#- ! . 7* # .. .GG IEEE J. Quantum Electron. 27 (9&'@ (94'%

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.- % L? % C(::5D% KK GG Popular Science *" ;5@94% % % C(:9;D% Physical Properties of Crystals% > + ! &49@&9:% G-- % C(::4D% KK " -- GG New Scientist % 42% G-- % C(::4#D% KK! ! . . .GG New Scientist # & 4&@4;% % 6% . <% C(::3D% KK *- -> ! * . + . ! # AGG (&" # # &2@&5 7--.#% " *% % ! <% * ,% *% C(::&D% KK).# # -

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- * GG # . Q L SPIE 1798 (4;@(;4% " *% % 1 % * ,% ## ,% "- % * ,% 1% C(::9D% KK+" $A AGG SPIE 2444 (&3@(49% " *% *% 1 % % ! - *% * ,% *% C(::2D% KK$ # ! # AGG SPIE 2838 22@39% " *% *% 1 % % * ,% *% " 6% C(::3D% KK # + F- *. " # A . . "/GG Electronics Lett. 33 (&;&@(&;4% " % ! V% C(::9D% KK - . *" 7 A " +" *GG IEEE Photon. Tech. Lett. 7 ((54@((59% " % - % *-- % < % * ,% *% C(::4D% KK# A ! GG Optical Engineering 32 &5;(@&5;2% " % ! V% * ,% *% C(::;D% KK . *- - AGG Electron. Lett. 30 (:3&@(:34% -- % C(:53D% KK -- !- " A - - 7GG Opt. Lett. 12 5;3@5;:% -- % C(::(D% KK --$# - ) F . GG Opt. Lett. 16 4'4@4'9% + )% A% ! +% % A" 1% C(::&D% KK - * - " . - *. GG Opt. Eng. 31 :52@::;% + % C(::2D% KK #- GG Popular Science 7 ;'% + % )% C(::&D% KK! - " # GG Smart Maerials and Structures 1 93@2&% + 6% 6% "" *% " <% C(::4D% KK1" + ./ #

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A% % C(::4D% KK . " ).# - # - - *" GG % )> % *" C)*D % 3@: 6 # *"% +- % % H A% +% . A% +% C(::4D% KK " . )> #@+ . $ C)+$DGG . Q *- G:4 -#// SPIE 1918 (9;@(2;% + % A% +"- 7% ,% -" % A" % *# % 1. A% C(::2D% KK- ,+ +- # GG SPIE 2718 4;9@49;% +

- % % + % % . *% )% C(:59D% KK# ! $! - # ,$)" GG Electron. Lett. 21 343@345% + ,% 6% < % % ! - *% *% C(::3D% KK! $ " 7-"$) ! $A !" # GG (&" % % - # 7--.# 93;@ 933% + " 6% % ? )% " % *" *% 1% )% A% C(::&D% KK# A !$- GG # . Q L SPIE 1798 &52@&:;% +?. 6% % (:59D Theory of Matrix Structural Analysis +#- % +. *% % % A% 7--. A% *% #- )% 6% *% ,H 6% C(::9D% KK- +- # # A +"$ H , )>. !GG SPIE 2444 ;'4@;':% +. *% % 7--. A% *% #- )% 6% C(::9#D% KK# $A " # AGG Electron Lett. 31 4':@4('% +. *% % *% !% < 6% % % )% - % % #- )% 6% C(::3D% KK A . - +- * ! # !GG SPIE 3042 49&@493% , % 6% 6 % % C(::4D% KK+ #$ + + # " -$ . . " - , # " ,GG Appl. Optics 32 3(('@3((4% , % 6% 6 % % C(::4#D% KK+ #$ -"" + ,. -$7-" " ,GG Appl. Optics 29 &(;&@&(;4%

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