International Consumption Comparisons

International Consumption Comparisons

E. A. Selvanathan I S . World Scientific

i m**4

Infernofional ConsumpNon Comparisons OECD Versus LD

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International Consumption Comparisons (H>

E.

School of International Business and Asian Studies Faculty of Commerce and Management Griffith University, Australia

S. Selvanathan

School of Economics, Faculty of Commerce and Management, Griffith University, Australia

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World Scientific New Jersey • London • Singapore SL • Hong Kong

Published by World Scientific Publishing Co. Pte. Ltd. 5 Toh Tuck Link, Singapore 596224 USA office: Suite 202,1060 Main Street, River Edge, NJ 07661 UK office: 57 Shelton Street, Covent Garden, London WC2H 9HE

British Library Cataloguing-in-Publication Data A catalogue record for this book is available from the British Library.

INTERNATIONAL CONSUMPTION COMPARISONS: OECD VERSUS LDC Copyright © 2003 by World Scientific Publishing Co. Pte. Ltd. All rights reserved. This book, or parts thereof, may not be reproduced in any form or by any means, electronic or mechanical, including photocopying, recording or any information storage and retrieval system now known or to be invented, without written permission from the Publisher.

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ISBN 981-02-4005-8

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DEDICATION

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ABOUT T H E AUTHORS D t E A Selvanathan is an Associate Professor in the School of International Business and Asian Studies at Griffith University, Queensland, Australia. He was educated at the University of Jaffna (BA Hons), University of Bucurest (MSc) and Murdoch University, Western Australia (PhD). He has also taught for brief periods at the University of Jaffna, Murdoch University and the University of Western Australia. For the period 1994-1997, Dr Selvanathan was the Deputy Dean (Staffing) of the Faculty of International Business and Asian Studies, Griffith University. He has co-authored three research monographs and has widely published in international refereed journals such as Review of Economic Studies, Journal of Business and Economic Statistics, Journal of Econometrics, Review of Economics and Statistics and Marketing Science. In 1988, Dr Selvanathan was awarded the prestigious Inaugural 75th Anniversary Distinguished Teaching Award, The University of Western Australia. He has also co-authored two textbooks, including an Australian best-seller in Business Statistics entitled Australian Business Statistics. Dr Saroja Selvanathan is an Associate Professor in the School of Economics at Griffith University, Queensland, Australia. She was educated at the University of Jaffna (BSc Hons), Murdoch University (MPhil) and the University of Western Australia (PhD). Dr Selvanathan has also taught for brief periods at the University of Jaffna, Murdoch University and the University of Western Australia. For the period 1996-1997, Dr Selvanathan was the Deputy Dean (Research and Postgraduate Studies) of the Faculty of Commerce and Management, Griffith University. She has authored a research monograph and has co-authored another research monograph. Dr Selvanathan has also published widely in international refereed journals such as Review of Economics and Statistics, Empirical Economics, Economic Modelling and Economic Record. She has co-authored two textbooks, including an Australian best-seller in Business Statistics entitled Australian Business Statistics.

Vll

PREFACE Understanding consumer reaction to price and income changes is of crucial importance for a host of microeconomic policy issues such as public-utility pricing, the measurement of distortions, optimal taxation and the treatment of externalities. The modern system-wide approach to applied demand analysis provides a unique approach to determine the factors that influence consumer decisions. This book presents a detailed analysis of the consumption patterns of consumers from 46 countries. The countries considered in the analysis are classified into two groups, namely, the Organisation for Economic Co-operation and Development (OECD) group — made up of a number of highly industrialized, rich countries, and the Less Developed (LD) group — made up of a number of relatively poor countries (totaling to about 9000 data points). Such a large and diverse body of data should provide convincing evidence, one way or the other, about a number of empirical regularities as well as the validity of the theory of the consumer. While the book reviews the theory of the consumer, it contributes more to the analysis of the consumption patterns of consumers around the Globe.

A Preview of the Book One of the primary objectives of applied demand analysis is to estimate demand systems to obtain income and price elasticities in order to use them to design microeconomic policies. With this objective, in Chapter 1 we present an

Vlll

overview of international consumption patterns and in Chapter 2 we present a review of the basics of demand theory. In Chapter 1, we present an overview of the OECD and LD countries and their consumer characteristics as well as a review of some of the previous international consumption studies. In Chapter 2, we present the basics of the economic theory of the consumer, discuss various consumer utility preference structures, review the differential approach to deriving demand systems and present a number of popular demand systems such as CBS, ADDS, translog and Rotterdam demand systems. In Chapter 3, we provide a preliminary data analysis of the consumption patterns in the OECD countries. We start this chapter by giving information about the data sources and the characteristics of the data set. We present a summary of the data in the form of Divisia indices. We investigate a number of empirical regularities of the consumers such as the Engel's Law, Law of demand and the famous Frisch's conjecture in these 23 OECD countries. The analysis of this chapter reveals that consumption tends to be more variable than prices and the consumers move away from those goods which have above average price increases — supports the law of demand. Furthermore, we find that the allocation of consumers' income on food decreases with their increasing income — supports Engel's law. Also the income elasticity of the marginal utility of income is not related to consumers' income - does not support Frisch's conjecture. We also derive initial estimates for income and price elasticities for the nine commodity groups in this chapter using the double-log demand systems. These initial estimates suggest that the OECD consumers consider food, housing, medical care and education as necessities; and clothing, durables, transport and recreation as luxuries. We also find that the demand for all goods in the OECD countries is price inelastic. We start Chapter 4 by giving details about the data source and the characteristics of the data for 23 LD countries. We use the same data analysis

IX

techniques introduced in Chapter 3 to present a preliminary analysis of the LDC data. The results show that the LD countries data supports the law of demand, Engel's law and does not support Frisch's famous conjecture. The elasticity estimates reveal that consumers in the LD countries consider food, housing and medical care as necessities; and clothing, durables, transport, education and recreation as luxuries. In general, demand for all goods in the LDC appear to be price inelastic. In Chapter 5, we compare the consumption patterns of the OECD and LD consumers based on the results of Chapters 3 and 4. We then combine the data sets for the two groups of countries to investigate the empirical regularities for the "World Consumers" as a whole. A comparison of the income allocation shows that OECD consumers allocate less proportion of their income on food compared to the LD consumers. OECD consumers allocate a higher proportion of their income on housing, medical care, transport and recreation than the LD consumers. Based on the pooled data, an average world consumer allocates about 33 percent of his/her income on food, 8 percent on clothing, 15 percent on housing, 8 percent on durables, 5 percent on medical care, 12 percent on transport, 7 percent on recreation, 1 percent on education and the remaining 12 percent on all other things. The results also show that both OECD and LDC data support Engel's law. Individual prices of consumer goods play a major role in consumer decisions as well as determine the rate of inflation, which impacts the economy as a whole. Thus studying the price movements is also important in understanding consumer behaviour. In Chapter 6, we study the prices and consumption of individual goods using the stochastic index numbers. According to this approach, the proportionate change in each individual price is taken to be equal to the underlying rate of inflation plus other components, which are random and nonrandom. The overall price index is then obtained by taking some

X

form of average of the individual price changes. An alternative to the stochastic approach is the functional approach whereby the form of the index is related to the underlying utility function. The attraction of the stochastic approach is that it provides standard errors for the price index. These standard errors increase with the degree of relative price variability. This agrees with the intuitive notion that when the individual prices move disproportionately, the overall rate of inflation is less well defined. We start this chapter by outlining the stochastic approach to index numbers and derive a number of theoretical results. We then apply these results to measure the price and quantity movements of the OECD and LD countries using the data presented in the previous chapters. Chapter 7 presents the final form of the estimating demand equations and tests demand theory hypotheses, demand homogeneity and Slutsky symmetry. The results show that homogeneity is universally acceptable by the OECD and LDC data and symmetry is acceptable to a lesser extent. In Chapter 2 of the book, we introduce a number of competing demand systems such as the Rotterdam, CBS, AIDS, etc. In Chapter 8, we estimate four of these demand systems using the OECD and LDC data and test the demand theory hypotheses, homogeneity and symmetry. For each country, a comparison of the performance of these four demand systems is presented using the information inaccuracies and a preferred demand system is then selected. In Chapter 9, we investigate a special form of utility structure — preference independence. The results show that preference independent utility structure is acceptable for most of the LD countries and by the majority of the OECD countries. In Chapter 9, we also give the final estimates of income and price elasticities of the nine commodity groups. The Appendix to this book, written by Wana Yang, Ken Clements and Dongling Chen, presents a shorter version of the User's Guide to the Demand Analysis Package, DAP2000. DAP2000 is an enhanced version of the Demand

XI

Analysis Package (DAP) written by S. Selvanathan, E.A. Selvanathan and Ken Clements in 1989. Features of DAP2000 include Preliminary data analysis, Hypotheses testing using both conventional asymptotic procedures and the Monte Carlo simulation approach, Estimation of demand systems and the Matrix approach to simulation (MAS), which is a recently-developed technique to evaluate demand systems. DAP2000 is extensively used in producing the results for Chapters 3, 4, 7 and 9 of this book.

E.A. Selvanathan Saroja Selvanathan January 2003

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xiii

TABLE OF CONTENTS PREFACE

vii

TABLE OF CONTENTS

xiii

LIST OF TABLES

xviii

LIST OF FIGURES

xxiv

TECHNICAL NOTES

xxvi

ACKNOWLEDGEMENTS

xxvii

CHAPTER 1: AN OVERVIEW OF INTERNATIONAL CONSUMPTION PATTERNS E^4. Selvanathan and S. Selvanathan

1

1.1 An Overview of the OECD and LD Countries 1.2 Consumption Theory 1.3 A Review of International Consumption Comparisons 1.4 A Pioneering International Consumption Study 1.5 Are Tastes Constant? References

2 6 14 17 22 26

CHAPTER 2: CONSUMER DEMAND MODELS JB^4. Selvanathan andS. Selvanathan

31

2.1 2.2

31 39

The Economic Theory of the Consumer The Structure of Preferences

xiv 2.3 Differential Approach to Deriving Demand Equations 2.4 Other Popular Demand Systems 2.5 More on the Differential Demand Equations 2.6 Aggregation and Consumer Demand References

43 52 59 63 65

CHAPTER 3: DATA ANALYSIS: OECD COUNTRIES S. Selvanathan andE^4. Selvanathan

71

3.1 DataSource 3.2 Summary Measures 3.3 Engel'sLaw 3.4 Preliminary Estimates of Income and Price Elasticities 3.5 Preliminary Estimates of the Income Flexibility 3.6 Testing the Frisch's Conjecture 3.7 The Validity of Preference Independence References

71 74 94 102 105 116 118 120

CHAPTER 4: DATA ANALYSIS: LESS DEVELOPED COUNTRIES E^4. Selvanathan and S. Selvanathan

125

4.1 DataSource 4.2 Summary Measures 4.3 Engle'sLaw 4.4 Preliminary Estimates of Income and Price Elasticities 4.5 Preliminary Estimates of the Income Flexibility 4.6 Testing the Frisch's Conjecture 4.7 The Validity of Preference Independence References

126 126 141 153 156 165 166 168

XV

CHAPTER 5: A COMPARISON OF CONSUMPTION PATTERNS IN THE OECD AND LD COUNTRIES E^4. Selvanathan and S. Selvanathan

169

5.1

Summary Measures

170

5.2

Empirical Regularities

175

5.3

Conclusion

182

CHAPTER 6: STOCHASTIC PRICE AND QUANTITY INDEX NUMBERS E~A. Selvanathan and S. Selvanathan

187

6.1 An Unweighted Average of Prices 6.2 A Budget-Share-Weighted Average of Prices 6.3 The Extended Model 6.4 A Two-Step Estimation Procedure: Step 1 6.5 A Two-Step Estimation Procedure: Step 2 6.6 AnExtension 6.7 Application of Stochastic Index Numbers to OECD and LDC 6.8 Conclusion References

189 190 193 194 196 199 205 224 224

CHAPTER 7: TESTING DEMAND THEORY HYPOTHESES: OECD AND LD COUNTRIES S. Selvanathan andE.A. Selvanathan

227

7.1

The Demand Model

228

7.2

Demand Homogeneity

230

7.3

Slutsky Symmetry

235

7.4 Summary Results References

241 245

XVI

CHAPTER 8: A COMPARISON OF ALTERNATIVE DEMAND SYSTEMS £L4. Selvanathan andS. Selvanathan

249

8.1 Four Demand Systems 8.2 Measure of Goodness-of-fit 8.3 The Preferred Demand System 8.4 Conclusion References

250 256 259 264 265

CHAPTER 9: THE STRUCTURE OF PREFERENCES: OECD AND LD COUNTRIES S. Selvanathan andE^4. Selvanathan

267

9.1 The Demand Model 9.2 Model Estimation 9.3 Estimation Results 9.4 Testing Preference Independence 9.5 Implied Income and Price Elasticities 9.6 Conclusion References

268 270 273 279 285 291 292

APPENDIX: THE DEMAND ANALYSIS PACKAGE, DAP2000 ....295 Wana Yang, Kenneth W Clements and Dongling Chen A.l Using the Package A.2 InputOptions A.3 Preliminary Data Analysis A.4 Hypothesis Testing and Estimation A.5 The Matrix Approach to Simulation References

296 297 300 301 310 319

xvii

INDEX Subject Index Author Index

321 321 324

xviii

LIST OF TABLES Chapter 1 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9

General characteristics of the OECD and LD countries Economic characteristics of the OECD and LD countries Major studies in international consumption comparisons Characteristics of the LPW database Budget shares of eight commodities in 13 countries Prices and per capita quantities consumed of eight commodities in 13 countries Divisia moments in 13 countries Marginal shares and income elasticities for eight commodities in 13 countries Quality of budget share predictions in OECD countries and Australian states

4 5 15 18 19 20 21 23 25

Chapter 3 3.1 3.2 3.3 3.4

Details of the commodity groups Characteristics of the OECD database Budget shares of 9 commodities in 23 OECD countries Per capita quantity consumed of 9 commodities in 23 OECD countries 3.5 Prices of 9 commodities in 23 OECD countries 3.6 Divisia volume indices in 23 OECD countries 3.7 Divisia price indices in 23 OECD countries 3.8 Divisia quantity variances in 23 OECD countries 3.9 Divisia price variances in 23 OECD countries 3.10 Divisia price-quantity correlations in 23 OECD countries 3.11 Divisia moments in 23 OECD countries

72 73 75 77 79 80 82 84 85 86 88

3.12 Relative quantity log-changes of 9 commodities in 23 OECD countries 3.13 Relative price log-changes of 9 commodities in 23 OECD countries 3.14 Frequency distributions of relative consumption and relative prices of 9 commodities in 23 OECD countries 3.15 Frequencies of joint signs of relative consumption and relative price changes in 23 OECD countries 3.16 Estimates of Working's model for 23 OECD countries 3.17 Previous estimates of Working's income coefficient for food 3.18 Income elasticities of 9 commodities in 23 OECD countries 3.19 Own-price elasticities of 9 commodities in 23 OECD countries 3.20 Four sets of estimates for income flexibility in 23 OECD countries 3.21 Another set of estimates for income flexibility for OECD countries

90 91 92 93 99 101 103 104 107 114

Chapter 4 4.1 4.2 4.3 4.4

Details of the commodity groups Characteristics of the LDC database Budget shares of 9 commodities in 23 LD countries Per capita quantity consumed of 9 commodities in 23 LD countries 4.5 Prices of 9 commodities in 23 LD countries 4.6 Divisia volume indices in 23 LD countries 4.7 Divisia price indices in 23 LD countries 4.8 Divisia quantity variances in 23 LD countries 4.9 Divisia price variances in 23 LD countries 4.10 Divisia price-quantity correlations in 23 LD countries 4.11 Divisia moments in 23 LD countries 4.12 Relative quantity log-changes of 9 commodities in 23 LD countries

127 128 129 131 132 133 134 136 137 138 140 142

XX

4.13 Relative price log-changes of 9 commodities in 23 LD countries 4.14 Frequency distributions of relative consumption and relative prices of 9 commodities in 23 LD countries 4.15 Frequencies of joint signs of relative consumption and relative price changes in 23 LD countries 4.16 Estimates of Working's model for 23 LD countries 4.17 Income elasticities of 9 commodities in 23 LD countries 4.18 Own-price elasticities of 9 commodities in 23 LD countries 4.19 Four sets of estimates for income flexibility in 23 LD countries 4.20 Another set of estimates for income flexibility for LD countries

143 144 145 151 154 155 157 165

Chapter 5 5.1 5.2 5.3 5.4 5.5 5.6 5.7 5.8

Average budget shares of 9 commodities: OECD and LD countries Average per capita quantity consumed of 9 commodities in OECD and LD countries Average prices of 9 commodities in OECD and LD countries Divisia moments in OECD and LD countries Average frequencies of joint signs of relative consumption and relative price changes in OECD and LD countries Estimates for income flexibility for the 9 commodities in 46 countries Average income elasticities of 9 commodities in OECD and LD countries Average own-price elasticities of 9 commodities in OECD and LD countries

171 173 173 175 177 180 181 181

Chapter 6 6.1 6.2

Estimates of price inflation and standard errors for Australia Estimates of relative price changes: Australia

202 204

XXI

6.3

Rate of inflation estimates and their standard errors in 23 OECD countries 6.4 Rate of inflation estimates and their standard errors in 23 LD countries 6.5 Estimates of relative price changes for the 9 commodities in 23 OECD countries 6.6 Estimates of relative price changes for the 9 commodities in 23 LD countries 6.7 Quantity index estimates and their standard errors in 23 OECD countries 6.8 Quantity index estimates and their standard errors in 23 LD countries 6.9 Estimates of relative quantity changes for the 9 commodities in 23 OECD countries 6.10 Estimates of relative quantity changes for the 9 commodities in 23 LD countries

207 209 211 212 216 218 220 221

Chapter 7 7.1 7.2 7.3 7.4 7.5 7.6 7.7 7.8 7.9

Further characteristics of the OECD database 232 Testing homogeneity in 22 OECD countries 234 Further characteristics of the LDC database 236 Testing homogeneity in 23 LD countries 237 Testing symmetry in 22 OECD countries 240 Testing symmetry in 23 LD countries 242 Summary results: Testing demand theory hypotheses in 22 OECD countries 243 Summary results: Testing demand theory hypotheses in 23 LD countries 244 Summary of percentage acceptance of the demand theory hypotheses: 22 OECD and 23 LD countries 245

XX11

Chapter 8 8.1 8.2 8.3 8.4 8.5 8.6 8.7 8.8

Value of the test statistics for testing homogeneity and the symmetry hypotheses for four demand models, OECD countries Summary results for testing homogeneity and symmetry for four demand models, OECD countries Value of the test statistics for testing homogeneity and symmetry hypotheses for four demand models, LD countries Summary results for testing homogeneity and symmetry for four demand models, LD countries Mean information inaccuracies, OECD countries Mean information inaccuracies, LD countries Preferred demand systems, OECD and LD countries Preferred demand systems for 22 OECD and 23 LD countries (in percentages)

252 253 254 255 261 262 263 264

Chapter 9 9.1

Estimates of the intercept terms of the model under preference independence for 9 commodities in 22 OECD countries 9.2 Estimates of the income coefficients for 9 commodities and income flexibility in 22 OECD countries 9.3 Estimates of the intercept terms of the model under preference independence for 9 commodities in 23 LD countries 9.4 Estimates of the income coefficients for 9 commodities and income flexibility in 23 LD countries 9.5 Testing preference independence in 22 OECD countries 9.6 Testing preference independence in 23 LD countries 9.7 Summary results: Testing preference independence, 22 OECD countries and 23 LD countries 9.8 Estimates of the income elasticities under preference independence for 9 commodities in 22 OECD countries 9.9 Estimates of the own-price elasticities under preference independence for 9 commodities in 22 OECD countries 9.10 Estimates of the income elasticities under preference independence for 9 commodities in 23 LD countries

274 275 277 278 280 281 284 287 288 289

xxm 9.11 Estimates of the own-price elasticities under preference independence for 9 commodities in 23 LD countries 9.12 Summary of acceptance of preference independence hypothesis: 22 OECD and 23 LD countries

290 291

Appendix A. 1 Overview of output of preliminary data analysis A.2 The comparison matrix A.3 Simulation procedure for M(k I j)

301 314 315

xxiv

LIST OF FIGURES Chapter 1 1.1

Food budget share vs logarithm of per capita GDP for 46 countries ..

7

Chapter 3 3.1

Quantity standard deviation vs price standard deviation in 23 OECD countries 3.2 Food budget shares against logarithm of per capita real consumption expenditures in OECD countries 3.3a Food budget share vs Log (Income) for pooled data from 23 OECD countries 3.3b Food budget share vs Log (Income) for pooled data from 22 OECD countries (excluding Iceland) 3.4 Relative quantity against relative price in OECD countries 3.5 Relative consumption vs relative prices for 9 commodity groups .... 3.6 Own-price elasticity against income elasticity

87 95 100 100 108 115 119

Chapter 4 4.1

Quantity standard deviation vs price standard deviation in 23 LD countries 4.2 Food budget share against logarithm of per capita real consumption expenditures in LD countries 4.3a Food budget share vs Log (Income) for pooled data from 23 LD countries 4.3b Food budget share vs Log (Income) for pooled data from 22 LD countries (excluding Hungary) 4.4 Relative quantity against relative price in LD countries 4.5 Relative consumption vs relative prices for 9 commodity groups .... 4.6 Own-price elasticity against income elasticity

139 147 152 152 158 163 167

XXV

Chapter 5 5.1 5.2 5.3 5.4 5.5 5.6 5.7 5.8 5.9

Average budget shares of 9 commodities, OECD vs LDC Average quantity log-changes in OECD and LD countries Average price log-changes in OECD and LD countries Quantity vs price standard deviations, 46 countries Relative consumption vs relative price in 46 countries Adjusted food budget share vs the logarithm of income - Pooled data from 44 countries Income elasticities of 9 commodities: OECD vs LD countries Own-price elasticities of 9 commodities: OECD vs LD countries Income elasticities vs own-price elasticities for 9 commodities in 46 countries

171 174 174 176 177 180 183 183 184

Chapter 6 6.1 6.2 6.3 6.4

Standard errors of the inflation estimates, Australia Estimated inflation rates vs their standard errors, Australia Estimated inflation rates vs their t-values, Australia Estimated inflation rates and their 95% confidence intervals, Australia 6.5 OECD inflation rates vs their standard errors 6.6 OECD inflation rates vs their t-values 6.7 LDC inflation rates vs their standard errors 6.8 LDC inflation rates vs their t-values 6.9 OECD quantity index estimates vs their standard errors 6.10 OECD quantity index estimates vs their t-values 6.11 LDC quantity index estimates vs their standard errors 6.12 LDC quantity index estimates vs their t-values

203 204 206 206 214 214 215 215 222 222 223 223

xxvi

TECHNICAL NOTES This book contains nine chapters and an Appendix. To aid the reader, each chapter has been written so that it is more or less self-contained. Each chapter contains a number of sections, subsections and a list of references. The sections in each chapter are numbered at two levels. The first level refers to the chapter and the second to the order of occurrence of the section within the chapter. For example, Section 2.4 is the fourth section in Chapter 2. Subsections are unnumbered. Equations are indicated by two numbers, the first refers to the section and the second to the order of occurrence within that section. For example, 'equation (2.8)' of Chapter 3 denotes the eighth equation in Section 2 of that chapter (Section 3.2). This equation is referred to in Chapter 3 as 'equation (2.8)'. If this equation is referred to in another chapter, then we use the terminology 'equation (2.8) of Chapter 3'. Tables and figures are indicated by two numbers, the first refers to the chapter and the second to the order of occurrence. For example, 'Table 4.5' refers to the fifth table of Chapter 4 and 'Figure 3.2' refers to the second figure of Chapter 3. Sections of the Appendix are numbered at two levels. For example, the second section of the Appendix is referred to as Section A2. Equations in the Appendix are numbered at three levels. For example, 'equation (A2.5)' refers to equation 5 of Section A2. Tables of the Appendix are numbered at two levels. For example, Table A.2 refers to the second table of the Appendix. Matrices are indicated by a boldface uppercase symbol (e.g., X). Vectors are indicated by a boldface lowercase symbol (e.g., x). The notation [xtJ] refers to a matrix whose (i,j)th element is xy, while x = [x,] refers to a column vector whose ith element is xt.

XXV11

ACKNOWLEDGEMENTS We wish to express our profound gratitude to Professor Ken Clements of the University of Western Australia for many stimulating discussions and helpful comments in writing the various chapters of the book, and for his encouragement and support. We would also like to thank Professor Clements and his colleagues Wana Yang and Dr Dongling Chen for their contribution of the User's Guide to the Demand Analysis Package, DAP2000, as an Appendix to this book. We are also grateful to Professor Prasada Rao of the University of New England for his invaluable comments on some of the chapters of the book. We also acknowledge the comments and suggestions of the anonymous reviewers and the editor of the book, which have helped improve the quality and presentation of the book. We would like to thank Dr Renuka Mahadevan, Mrs Tanya Tietze and Dr Nerissa Salayo for excellent research assistance during various stages of the project. We would also like to thank the publishing staff at World Scientific for their patience and support throughout the duration of the project. Finally, we acknowledge the financial support of an ARC (Small) grant, Griffith University, in assisting with the data collection and preliminary analysis. Our special thanks to our loving children, Arthavan (11 yrs) and Prabha (9 yrs), for their patience, support and clerical assistance throughout the duration of this project.

CHAPTER 1

An Overview of International Consumption Patterns £L4. Selvanathan <& S. Selvanathan

With the increasing trend in the globalization of national economies, understanding the consumption patterns of the consumers of a particular country is not only important to that country but also to all other countries in the world. As the barriers to international trade reduce, exporters look for a global market for their product. Therefore, understanding consumer behaviour around the Globe is becoming much more important than ever before. Even in less developed countries, due to globalization of the local economy, a class of wealthier consumers is emerging while the size of the class of consumers living under the poverty line is also on the increase. The main aim of this book is to study the consumption patterns of consumers using a huge and diverse database consisting of 46 countries. Such a large body of data should provide convincing evidence, one way or the other, about the validity of consumption theory. The book also presents a large number of applications of recent innovations in the area. The database includes 23 countries from the Organisation for Economic Co-operation and Development (OECD) which are all high-income and highly industrialised countries, and 23 Less Developed (LD) countries which are low-income countries. The countries within each group share a number of common features among themselves. At

2

International Consumption Comparisons

the same time, however, there are obvious differences in language, religion, culture and geography. The book also analyses whether these differences are of economic importance within the two groups and whether there are any differences in consumer preferences between the high-income and low-income countries. Understanding the behaviour of consumers from such a diverse group is important for a number of reasons. First, consumer spending is considered as a good objective economic indicator to measure the health of an economy. Second, private consumption absorbs a major portion of the Gross Domestic Product (GDP) in most countries, thus having a significant influence on the state of the economy as a whole and business conditions. Finally, an understanding of the price and income responsiveness of consumption is of crucial importance for a host of microeconomic policy issues including public utility pricing, optimal taxation and introducing various welfare measures. We start this chapter with an overview of the OECD and LD countries and then in the following section provide a short review of consumption theory. In Section 1.3, we present a review of some of the international consumption studies available. In the following section, we present a review of one of the pioneering international consumption study by Lluch, Powell and Williams (1977). Finally, in Section 1.5, we look at the issue of identical tastes at crosscountry level from a study by Selvanathan (1993).

1.1

An Overview of the OECD and LD Countries

Table 1.1 presents some general information on a number of basic characteristics such as land size, language, religion, population size and population density of the OECD and LD countries and their consumers.

Chapter 1 An Overview

3

Column 1 of the table lists the names of the countries. Columns 2 and 3 give the language and religious background of the people in each country. Column 4 gives the land size of each country (in '000 square kms). As can be seen, the countries are diverse in terms of the size of the country, the languages spoken and their religious belief. Column 5 gives the population for the year 2001 and columns 6 to 8 give the distribution of the population for 3 different age groups. Column 9 presents the population density (i.e., population per square kilometer). Obviously there are similarities and differences in the population characteristics among the consumers in the 46 countries. It can be easily seen from the table that in both the OECD and LD group of countries, the percentage of consumers in the age group 15-64 is about the same, about 60 to 70 percent. While the proportion of consumers in the aging population group (over 65 years) is high in the OECD countries compared to the LD countries, implying that people in rich countries have a higher life expectancy than those in poor countries. Also, the proportion of consumers in the younger age group (0-14 years) is higher in the LD countries than the OECD countries. These kinds of differences in the consumer distribution could result in significant differences in the demand for certain commodities. Another significant difference is in terms of the population density among the 46 countries. For example, the population densities for Hong Kong and Singapore are about 3000 times higher than that of Australia. On average, the LD countries have a higher population density compared to the OECD countries. Table 1.2 presents the main economic indicators of the OECD and LD countries. Columns 2 and 3 of the table present the details about each country's trading partners (exports and imports). As can be seen, the leading economies in the OECD group, USA, UK, Japan, Germany and France are the dominant players in the OECD as well as the LD countries. Columns 4 and 5 present the rate of inflation (in 2000) and the rate of unemployment (in 2000). While the

International Consumption Comparisons

4

Table 1.1 General characteristics of the OECD and LD countries Country

Language

Religion

(2)

(3)

Area

1Ftopdation 2001

Percentage population by age group

Fbpuatjon persqkm

OOOOsqkm) (pillions) {>14yrs 15-64yrs 65-yrs (1)

(4)

(5)

OECD Countries English, Aboriginal 19.40 7713.36 Anglican, Romm Catholic 1. Australia German ai3 Roman Catholic Anglican 83.85 2. Austria 10.24 Roman Catholic Dutch, French, German 30.52 3. Belgium 31.28 9976.14 Roman Catholic, Protestant English French, Inuktitut 4. Canada 5.34 Danish 43.09 Lutheran 5. Denmark Finnish, Swedish 5.17 Frotestant 338.13 Finland 6. French 59.33 551.50 Roman Catholic Frotestant, Islam 7. France Gerrran 82.80 Lutheran, Roman Catholic 356.91 8 Germany Greek 10.60 Greek Orthodox 131.99 Greece 9. Icelandic 0.28 Lutheran 103.00 10. Iceland Roman Catholic Fbtestant Irish English 3.80 70.28 11. Ireland Italian 57.63 301.27 Roman Catholic 12. Italy Japanese, Korean, Chinese Shinto, Buddhist, Christian 126.55 377.80 13. Japan Letzburgish, French, Gerrran 0.44 Roman Catholic 2.59 14. Luxembourg Dutch, Frysian 15.89 37.33 Roman Catholic Frotestant 15. Netherlands New Zealand English, Maori 3.82 Anglican, Romm Catholic Presbyterian 270.99 16. 4.48 Norwegian 323.90 Lutheran 17. Norway Portuguese Rorran Catholic 10.05 92.39 18. Portugal Catalan Roman Catholk 40.00 504.78 19. Spain Swedish a87 Lutheran, Frotestant 449.96 20. Sweden 7.26 Romanist 41.29 Roman Catholic FTOtestant 21. Switzerland English, Welsh, Scottish, Irish 59.51 244.88 Frotestant, Roman Catholk, Islam. Hindu, Judaism 22. UK English, Spanish 275.56 Frotestant, Roman Catholkjudaism 9372.61 23 US LD Countries 39.69 Roman Catholk: Spanish Colombia 1138.91 1. 0.76 Greek Orthodox, Christian, Islam Greek, Turkish 9.25 Cyprus 2. Roman Catholic 12.92 Spanish, Cuediua 283.56 3. Ecuador 0.83 1&27 English, Fijian, Hndi Christian, Wndu 4. Fiji Roman Catholic 6.25 112.09 Spanish, English 5. Honduras 7.12 Buddhist, Confucian, Taoist, Christian, Islam Hindu English, Chinese Hong Kong 1.04 6. 10.14 Hungarian 93.03 Roman Catholic Frotestant 7. Hungary 1014 Ffindu, Islam Sikh, Christian Ffndi, English, Tanil 3287.59 8. India 65.62 Farsi, Turkic Kurdish 1648 Islam Christian 9. Iran 5.84 Hebrew, Arabk 20.77 JeiMsh, Islam 10. Israel 2.65 10.99 Frotestant, Romm Catholk English 11. Jamaica 47.47 99.02 Buddhist, Protestant, Roman Catholic Confudanist Korean 12. Korea 0.39 0.32 Rorran Catholk Maltese, English 13. Malta Roman Catholic Spanish 100.35 1958.2 14. Mexico 81.16 300 Roman Catholic Islam Filipino, English Spanish 15. Philippines Romm Catholic ftotestant Spanish, English 3.92 8.9 16. Puerto Rico Chinese, hfelay, Tanil, English Buddhist, Christian, Islam Taoist, Hindu 4.15 17. Singapore 0.62 Africaans, English, Xhosa, Zulu Christians, Ftoman Catholic 43.42 1221.04 18. South Africa 19.24 Buddhist, Hindu, Islam Christian Sinhalese, Tanil, English 65.61 19. Sri Lanka Buddhist, Confucian, Taoist, christian 22.19 35.74 Chinese, Taiwanese 20. Taiwan Thai, Chinese, Malay 61.23 513.12 Buddhist, Islam 21. Thailand Romm Catholic Spanish 23.54 22. \fenezuela 912.05 11.34 English, Bantu 390.58 Christian, Anirrist 23. Zimbabwe Source: The Wforld Fact Book', wm.ofa.gotJa^fxMi&tians/fdctixxi^ and US Bureau of the Census, International Database.

(6)

(7)

(8

(9)

21 17 17 19 19 18 19 16 15 23 22 14 15 19 18 22 20 17 15 18 17 19 21

67 68 66 68 67 67 65 68 67 65 67 68 68 67 68 66 65 67 68 65 68 65 66

12 15 17 13 15 15 16 17 18 12 11 18 17 14 14 12 15 16 17 17 15 16 13

2.52 96.96 335.52 3.14 123.93 15.29 107.58 231.99 80.31 2.72 54.07 191.29 334.97 169.88 425.66 14.10 13.83 108.78 79.24 19.71 175.83 243.02 29.40

32 23 36 33 42 18 17 33 33 27 30 22 20 33 37 24 18 32 26 21 23 32 39

63 66 60 63 54 72 69 62 62 63 63 71 67 62 59 66 75 63 67 70 70 63 58

5 11 4 4 4 11 15 5 5 10 7 7 13 5 4 10 7 5 7 9 7 5 3

34.85 82.15 45.56 45.43 55.76 6846.15 109.00 308.43 39.82 281.17 241.13 479.40 1218.75 51.25 270.53 440.45 6693.55 35.56 293.25 620.87 119.33 25.81 29.03

5

Chapter 1 An Overview Table 1.2 Economic characteristics of the OECD and LD countries

(1) OECD Countries 1. Australia 2. Austria 3. Belgium 4. Canada 5. Denmark 6. Finland 7. France 8. Germany 9. Greece 10. Iceland 11. Ireland 12. ItaJy 13. Japan 14. Luxembourg 15. Netherlands 16. New Zealand 17. Norway 18. Portugal 19. Spain 20. Sweden 21. Switzerland 22. UK 23. US LD 1. 2. 3.

Countries Colombia Cyprus Ecuador

Inflation Unemployment

Major Trading Partners

Country

Export

Import

(2)

(3)

Japan, US, Korea USJapan, China Germany, Italy, Switzerland Germany, Italy, Switzerland France, German/, Netherlands Netherlands, Germany, France US. Japan, UK Us Japan, China Germany, Sweden, UK Germany, Sweden, UK Germany, Sweden, Russia Germany, Sweden, UK Germany, Belgium, Italy Germany, UK Spain France, Nethedands, US France. US, UK Italy, Germany, France Germany, Italy, UK Germany, US, UK UK. Germany, US UK US, Germany UK, US, Germany Germany, France, US Germany, France, Netherlands US, China, Korea US, China, Korea Belgium, Germany, France Germany, France, Belgium Germany, US, UK Germany, Belgium, France Australia, USJapan Australia US, Japan UK, Netherlands, France Sweden Germany, UK Spain, Germany, France Spain Germany, France France, Germany, Italy France, Germany, Portugal Germany, UK Norway Germany, US, UK Germany, France, Italy Germany, US, France Germany, US. France US, Germany, France Canada, Mexico, Japan Canada, Mexico, Japan

2000 (4) 4.50 2.40 2.50 2.70 2.90 3.40 1.70 1.90 3.10 5.20 5.60 2.50 •0.70 2.90 2.50 2.70 3.10 2.90 3.40 1.00 1.50 2.90 3.40

Real per capita GDP in 1992

2000

inSUS

US-100

locXGDP)

(5)

(6)

(7)

(8)

6.3 3.70 10.90 6.80 5.40 9.80 9.50 10.50 11.40 1.30 4.10 10.50 4.70 2.70 2.60 6.00 3.40 4.00 14.10 4.70 2.00 5.50 4.00

18500 16989 18091 20970 18730 15619 18232 20197 8658 16324 12259 16724 19920 21144 17373 15502 17094 9005 12986 18387 21631 16302 23220

80 73 78 90 81 67 79 87 37 70 53 72 86 91 75 67 74 39 56 79 93 70 100

9.83 9.74 9.80 9.95 9.84 9.66 9.81 9.91 9.07 9.70 9.41 9.72 9.90 9.96 9.76 9.65 9.75 9.11 9.47 9.82 9.98 9.70 10.05

Food budget share 1992 (9) 0.20 0.19 0.18 0.16 0.21 0.24 0.18 0.21 0.36 0.25 0.33 0.20 0.19 0.19 0.15 0.19 0.22 028 0.20 0.20 0.27 0.21 0.12

4254 0.34 8.36 18 16.70 8.00 US, Venezuela, Ecuador US, Venezuela Mexico 9.37 51 11742 3.40 UK Greece, Russia 0.26 4.10 UK US, Italy 8.14 15 3420 10.30 96.10 US, Colombia, Venezuela US, Korea, Colombia 0.39 8.57 S288 Australia, re, Singapore 0.37 23 6.00 1.10 Australia, US, UK 4. Fiji 7.49 8 1792 28.00 11.00 US, Guatemala Japan US, Germany, Belgium 5. Honduras 0.45 21034 9.95 91 5.10 -3.80 China Taiwan Japan China, US, Japan 6. Hong Kong 0.16 866 0.37 25 5780 6.40 9.80 Germany, Samoa, Italy Germany, Russia Italy 7. Hungary 7 7.40 1633 4.40 4.00 US, Hong Kongjapan 8. India 0.53 US, Belgium Singapore 8.33 18 4161 14.00 14.50 Germany, Korea, Italy Japan, Italy, Korea 9. Iran 0.35 9.46 US, Belgium, Germany 0.24 55 12783 8.80 1.10 US, Belgium UK 10. Israel US, UK, Canada US, UK Canada 0.41 8.00 13 2978 16.00 8.80 11 .Jamaica 9.14 4.00 Japan, US, China 0.30 40 9358 2.30 US, Chinajapan 12. Korea 8.94 France, Italy, Singapore US, Singapore, Germany 0.31 33 7625 5.30 2.40 13 Malta US, Canada, Germany 8.97 34 7867 2.20 9.50 US, Japan, Germany 14. Mexico 0.28 2172 Japan, US, Korea USJapan, Taiwan 15. Philippines 0.58 7.68 9 11.00 4.30 8.87 31 US, Dominican, Netherlands US, lreland,japan 0.22 7120 9.50 5.70 16. Puerto Rico 72 17. Singapore 0.17 9.73 16736 3.00 1.40 Malaysia, USJapan Malaysia US, Hong Kong 8.26 17 3885 30.00 5.30 Germany, US, UK US, UK Japan 18. South Africa 0.36 7.93 12 19. Sri Lanka 0.59 2783 7.60 6.20 Japan, India Hong Kong US, UK Germany 9.20 42 9850 3.00 1.30 Japan, US, Korea US, Hong Kongjapan 0.28 20. Taiwan 8.52 Japan, US, China USJapan, Singapore 21. Thailand 22 5018 3.60 1.60 0.29 9.04 36 8449 US, Colombia, Brazil US, Nethedands, Brazil 22. Venezuela 0.41 13.90 16.20 South Africa UK Japan 23. Zimbabwe 7.30 6 1479 50.00 55.70 South Africa UK, Mozambique 0.30 Source: Columns 2-5 are based on year 2000 trade figures obtained from FACT sheet, Department ofForeign Affairs and Trade, Australia. GDP are from Perirvorld Tables by Heston and Summers. For Honduras, the entries are from The World Fact Book', vwiw.cxfci.Q^x^da/puHications/factbook; and GDP and budget share entries for Puerto Rico are for 1985 and for Taiwan are for 1990.

6

International Consumption Comparisons

OECD countries enjoy a lower rate of inflation combined with a lower rate of unemployment, the LD countries have a much higher rate of inflation coupled with a higher rate of unemployment, with the exception of the four Asian Tigers, namely, Hong Kong, Singapore, Korea and Taiwan. Column 6 of Table 1.2 gives the real per capita GDP (for the year 1992). As can be seen, among the LD countries, the per capita GDP of Hong Kong and Singapore are comparable with many OECD countries and are even higher than some of the OECD countries (for example, Greece and Portugal). For ease of comparison, in column 7, we present the GDP with US=100. Column 8 presents the logarithm of real per capita GDP for all countries. The last column of the table gives the food budget share for the 46 countries. Comparing columns 7 and 9, we can see an inverse relationship between the per capita real GDP and the food budget share. That is, the food budget share decreases with increasing real GDP. This is illustrated in Figure 1.1, where we plot the food budget share against the logarithm of per capita real GDP. As can be seen, a clear inverse relationship exists between food budget share and the per capita real GDP. This observation supports the famous law in consumption economics, the Engel's Law, which states that food budget share falls with increasing income. More on Engel' s law will be discussed in the later chapters.

1.2

Consumption Theory

The objective of consumption theory is to analyse the demand for goods and services in terms of income and prices. In Chapter 2, we present a detailed description of consumption theory. In this section, we present a simplified description of this theory.

Chapter 1 An Overview

y = -0.1196x+ 1.3748

Food budget share o o ro *.

0.6 -

^ $ * >

0.0 8

9

10

Ln(GDP per capita)

Food budget share vs logarithm of per capita GDP for 46 countries Figure 1.1

Consider a demand function for commodity i of the form M log # = a + P log —-1 + y log vP \Pj

(2.1)

where q-x is the quantity consumed of i; M is the consumer's money income; P is a general price index; pt is the price of i; and a, P and y are constants. The coefficient P in equation (2.1) is interpreted as the income elasticity, i.e.,

8

International Consumption Comparisons 8(log g| .)

T og yJ This elasticity describes the income sensitivity of consumption of the good. The coefficient y is the price elasticity of demand, i.e., dflogg,) '

< * * ) '

As demand curves slope downwards, this elasticity is negative. The income variable in equation (2.1) is money income (M) deflated by the general price index (P). Thus MIP is interpreted as real income. As real income is being held constant, if p/P changes, then the response of consumption to this change reflects the pure substitution effect only. As the coefficient y measures this response, it is known as the "income-compensated" price elasticity, or the compensated price elasticity for short. The size of y reflects the availability of substitutes; y will be higher (in absolute value) when there are more good substitutes available. As the two variables on the right-hand side of equation (2.1) are both expressed in real terms (real income and the relative price of i), it follows that an equi-proportional increase in the nominal variables M, p± and P has no effect on consumption. This property of the demand equation is known as the absence of money illusion of the consumer, or demand homogeneity (as the demand equation is homogeneous of degree zero in nominal variables). The key virtue of model (2.1) is its simplicity. Its parameters have a straightforward economic interpretation and the model can be easily estimated. However, it suffers from several deficiencies. The first problem is that it does

9

Chapter 1 An Overview

not give any explicit attention to consumer preferences, which lie behind the demand equation. Second, the model deals with the demand for commodity i in isolation from all other goods. The model consists of only one equation whereas in fact there is one equation for each of the n goods consumed. A related deficiency is that the model does not allow good i to be more closely related to some goods and less to others. This is because the model specifies that all crossprice elasticities d(logg,-)

i*j.

logy are zero. A simple way of rectifying the second deficiency is to extend model (2.1) by adding to it terms involving the prices of other goods. Let there be n goods with prices p\,..., p„. An extended version of (2.1) is then M log qx = a; + PJ log —

+ £ Ytj log

i=l,...,n.

In model (2.2) the coefficient pi is the income elasticity (as before) and aqogg,.)

n = —r

log

Pj

(2.2)

International Consumption Comparisons

10

is the compensated elasticity of demand for good i with respect to the price of good j . It is to be noted that (2.2) consists of n equations, which describe the demand for the n goods simultaneously. Accordingly, (2.2) is a 'system-wide' demand model (Theil, 1980). As p,qi is expenditure on good i, expenditure on all n goods is X"=i p,-<7,-..In what follows, we call this sum 'income' although strictly speaking it is total expenditure. The value of income (denoted by M, as before) is taken to be exogenous or outside the control of the consumer. Accordingly, the consumer's budget constraint takes the form

ZPiGi = M.

(2.3)

i=l

Differentiating both sides of (2.3) with respect to M yields

i=i

oM

As the income elasticity holds constant prices, it can be formulated as 3(log<7,) 3(logM)

Pi =

Using the identity d(log x) = dx/x, this elasticity can also be expressed as

&

=

-

!

&

•

(

2

'

5

)

11

Chapter 1 An Overview

We define Pitt

M

as the share of income devoted to good i. Using (2.5) and (2.6) in (2.4), we obtain

I w,A=l.

(2.7)

In words, the budget constraint (2.3) implies that a weighted-average of the n income elasticities is unity. It can also be shown that the budget constraint implies the following constraint on the price elasticities: E^fpO,

j=l,...,iL

(2.8)

The n equations in model (2.2) need to be estimated subject to constraints (2.7) and (2.8) to ensure that the estimates satisfy the budget constraint. It is to be noted that (2.7) and (2.8) are cross-equation constraints on the parameters of the demand equations. This emphasises the interrelationships between the consumption of the n goods; as income is fixed, a rise in expenditure on one good means that expenditure on at least one other must fall. Another cross-equation constraint that needs to be imposed on the parameters of model (2.2) is Slutsky symmetry, or symmetry of the substitution

International Consumption Comparisons

12

effects. This constraint, implied by the utility-maximizing theory of the consumer, takes the form dqj

%,

dPi

real income constant

*Pj

i,j=l,...,«. real income constant

To formulate this constraint in terms of the parameters of (2.2), we note that 9(logg,.) Pj) log

Yy

9(logg,) BQogpj)'

where the approximation is based on 9(log P)/3(log p,) ~ 0. As real income is held constant in (2.2), we have Pj dqt Yij

»

9i fyj

real income constant

Accordingly, Slutsky symmetry can be approximated by WiYu = WJYJI,

1,J—1,...,/X,

where we have used the definition of w} given in (2.6). To illustrate explicitly the effect of the consumer's preferences on the demand equations, consider the following algebraic form of the utility function:

13

Chapter 1 An Overview u(qu...,qn)

= I

(2.9)

a,. log(qr,--&,-),

where the a^s and bj's are coefficients satisfying X a,; = 1 and ft j < ^j. i=l

Maximizing (2.9) subject to the budget constraint (2.3) yields the following demand equations

q, = b,+

M- I Pi I

pjbj

i-l

"i

J=I

or, multiply both sides by p\, PU\

P\b\+ ai M - Z pjbj

i=l,...,n.

(2.10)

As model (2.10) expresses expenditure on i as a linear function of prices and income, it is known as the linear expenditure system (LES). This demand system was first used by Stone (1954a, 1954b). As can be seen, the form of the utility function implies the form of the demand equations. It is to be noted that the form of the utility function (2.9) is very simple. Its additive nature implies that there are no interactions between the goods in generating utility; i.e., the marginal utility of each good is independent of the consumption of all others. Such additive utility structure is called 'preference independence'. We shall

14

International Consumption

Comparisons

consider, in detail, preference independence and its implication to consumer demand in Chapters 2, 3, 4, 5 and 9. Another aspect of the LES should also be noted. That is, it cannot be used to test the homogeneity and symmetry hypotheses as these are built in or maintained hypotheses in this model. However, such restrictions may not be at great variance with the data if the model is applied to broad commodity groups. In the main, this book deals with system-wide demand models, which are closely linked to the structure of the consumer's preferences.

1.3

A Review of International Consumption Comparisons

The modern literature on international consumption comparisons probably started with Houthakker (1957) who estimates double-log Engel curves from cross-sectional data for a large number of countries. As Houthakker uses crosssectional data with no variation in prices, he does not estimate price elasticities. Subsequently, others have used time-series data for a number of countries to provide estimates of both income and price elasticities; more recently Selvanathan (1993) and Chen (2001). Selvanathan (1993) considered 18 OECD countries over the time period up to the early 1980s and Chen extended Selvanathan's analysis by adding 13 less developed countries (a total of 31 countries) with roughly the same time period. Table 1.3 provides a tabulation of the major consumption studies. We now discuss two of the most recent developments in international consumption comparisons. The first development was due to international consumption comparisons adopted by Clements and Theil (19961), who used

Published in 1996 but the research was carried out in the late 1970s at the University of Chicago.

15

Chapter 1 An Overview Table 1.3 Major studies in international consumption comparisons Authors

(1) 1.

Chen (2001)

Countries

(2) 31 OECD/LD countries

Type of Data

(3) Time series

Period

Number of commodities

Model

(6)

(4)

(5)

1960-1984

8

Working's

2.

Clements and Theil (1996)

16 countries

Cross-country

4

Working's

3.

Camaletsos (1973)

11 OECD countries

Time series

1950-1965

5

LES, GLES and IAES

4.

Coldberger and Gamaletsos (1970) 13 OECD countries

Time series

1950-1961

5

LES and DL

5.

Houthakker(1957)

30 countries

Cross-sectional

4

DL

6.

Houthakker (1965)

1 3 OECD countries

Time series

5

DL

7.

Kravis e t a l (1982)

34 countries

Cross-country

8.

Lluch and Powell (1975)

19 countries

Time-series

1946-1968

8

LES

9.

Lluch e t a l (1977)

17 countries

Time series

1953-1969

8

ELES

10. Lluch and Williams (1975)

14 countries

Time series

1955-1969

8

ELES

1 1 . Parks and B a r t e n d 973)

14 OECD countries

Time-series

1950-1967

5

variant of LES

12. Pollak and Wales (1987)

Belgium, UK and US

Time-series

1961-1978

3

QES

13. SelvanathanS(1993)

18 OECD countries

Time-series

1960-1981

10

Working's

14. Theil (1987)

3 0 countries

Cross-country

10

Working's

15. Theil and Suhm (1981)

1 5 countries

Cross-country

8

Working's

16. Theil e t a l ( 1 9 % )

30 countries

Cross-country

10

Working's

1948-1959

103 and 25

DL and LES

* LES=Linear expenditure system; GLES=Ceneralised LES; IAES=lndirect additive expenditure system; DL=double-log demand model; ELES=Extended LES; QES=Quadratic expenditure system.

data from Kravis et al (1978) on 16 countries to estimate a common system of demand equations for all countries. In comparison with the usual time-series application for a given country, here countries play the role of time periods. This idea has been built on by Theil and Suhm (1981). Under this approach, tastes are taken to be the same internationally. Although this is obviously a rather bold assumption, it is one forcibly advocated by Stigler and Becker (1977). Stigler and Becker hypothesize that tastes neither change capriciously nor differ importantly between people. In an international context, this hypothesis amounts to stating that consumers in different countries are similar irrespective of

16

International Consumption Comparisons

differences in language, religion, culture and geography. In an innovative paper, Pollak and Wales (1987) formally tested this hypothesis. They use the quadratic expenditure system with time-series/cross-country data for Belgium, the UK and the USA. On the basis of likelihood ratio and nonparametric (revealed preference) tests, they conclude that the data from these countries cannot be pooled to estimate a common demand system. That is, they reject the hypothesis of identical tastes. Selvanathan (1993) also tested Stigler and Becker (1977) hypothesis using consumption data for the 18 OECD countries. First the consumers in different countries were allowed to be idiosyncratic and 18 separate systems of demand equations were estimated, one for each country. Then it was specified that consumers in different countries have identical tastes. That is, the parameters of the demand equations were taken to be the same across countries. This involves pooling the data and estimating a common demand system for all countries. Now, the restrictions of the pooled model against the individual country model are formally tested by means of a likelihood ratio test. Selvanathan (1993) also concluded that the data from these countries cannot be pooled to estimate a common demand system. That is, the hypothesis of identical tastes should be rejected. For more on the issue of identical tastes among consumers, see Section 1.5. The second development resulted from the analysis of the extensive detailed data collected and compiled by Kravis et al (1982). A leading example of such a cross-country application is by Theil (1987) and Theil et al (1996), who used data compiled by Kravis et al (1982). These data, which are part of the International Comparisons Project sponsored by the United Nations and the World Bank, cover 34 countries and provide comparable price and volume indices for more than 100 detailed categories of consumption. This study differs from other studies reported in the literature (see Table 1.3) in one or more of the following ways: the number of commodity groups used and the level of

Chapter 1 An Overview

17

aggregation, the countries included, the time period used and the demand model used. In the next section, we discuss one of the pioneering international consumption study by Lluch et al (1977).

1.4

A Pioneering International Consumption Study

The international consumption comparisons presented in this book consider the consumption data for 23 OECD countries and 23 LD countries. However, in this section, we present results from one of the pioneering international consumption studies, which uses a different database, but includes both developed and developing countries. Relative to the OECD or LDC separately, these data exhibit more cross-country variability in income as it contains a mix of both OECD and LD countries but for only a total of 13 countries. The material presented in this section is mainly from Selvanathan (1988). In a pioneering study, Lluch, Powell and Williams (1977) - hereafter LPW - used data for 8 commodity groups in 17 countries. Table 1.4 presents an overview of the data for 13 of the 17 countries with countries ordered in terms of declining per capita GNP. (See Selvanathan, 1988, for the reasons for not considering 4 of the LPW countries.) As can be seen, the US has the highest per capita GNP, while Korea has the lowest with only 4 percent of the US value. Table 1.5 presents the budget shares at sample means of the 8 commodities in each country. Note the strong tendency for the food budget share to decline with increasing GNP, which is in accordance with Engel's law. The upper half of Table 1.6 presents the average annual price log-changes, while the lower half presents the corresponding per capita quantity log-changes. Next, we summarize these data with Divisia indices. Let wic be the budget share of i

International Consumption Comparisons

18

Table 1A Characteristics of the LPW database CNPat sample midpoint Country

Sample period (2)

(1) 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13.

US Sweden Australia UK Israel Italy Puerto Rico Ireland Greece South Africa Panama Thailand Korea

1955-68 1955-68 1955-66 1955-68 1959-68 1955-68 1955-67 1955-68 1958-68 1955-68 1 960-68 1960-69 1955-68

GNPin 1970 US$ (3)

(3) with US=100 (4)

3669 2962 2192 1900 1468 1207 1023 1014 676 596 564 148 142

100 81 60 52 40 33 28 28 18 16 15 4 4

Source: Lluch etal. (1977, Table 3.2).

for country c at sample means (given in Table 1.5); and Dpic and DqiC be the mean price and quantity log-changes (Table 1.6). The Divisia volume and price indices for country c are then DQe = I

wicDqic,

DPC =

TwicDpic,

c=l

13,

and are presented in columns 2 and 3 of Table 1.7. As can be seen from the last row of the table, on average, per capita consumption grew at a rate of 3.5 percent per annum, while prices in these countries increased by 3.3 percent per

Chapter 1 An Overview

19 Table 1.5

Durables

Other services

Housing

Recreation

Clothing

Transport

Food

Personal care

Budget shares of eight commodities in 13 countries (Means x 100)

(2)

(3)

(4)

(5)

(6)

(7)

(8)

(9)

US

26.7

9.5

22.7

7.3

8.1

15.2

5.5

4.9

Sweden

36.6

11.5

15.9

7.0

3.7

14.2

8.9

2.4

3.

Australia

33.3

11.0

12.7

7.8

5.7

13.1

4.3

12.1

4.

UK

39.7

10.7

18.3

6.6

2.3

10.9

7.5

4.0 10.0

Country (1) 1. 2.

5.

Israel

31.9

9.4

19.2

7.4

6.6

7.3

8.1

6.

Italy

46.3

10.1

16.6

3.2

6.3

8.1

7.5

1.8

7.

Puerto Rico

35.6

10.6

15.3

6.9

6.9

12.3

8.8

3.7

8.

Ireland

49.2

10.0

12.8

5.7

1.3

8.8

6.3

5.9

9.

Greece

46.8

12.2

18.3

3.9

3.6

6.9

6.1

2.3

10. South Africa

36.8

11.8

16.7

7.8

4.8

13.2

4.7

4.1

11. Panama

45.5

7.4

16.7

6.4

4.7

9.4

7.5

2.3

12. Thailand

57.6

8.4

8.0

3.2

5.6

7.9

7.5

1.8

13. Korea

59.9

10.4

11.4

2.8

4.2

4.7

4.4

2.2

Mean

42.0

10.2

15.7

5.8

4.9

10.2

6.7

4.4

Source: Lluch et ai 0977, Table 3.3).

annum. Columns 4-6 of the table contain the corresponding second-order moments, Divisia quantity and price variances, defined in Chapter 2. As can be seen, the Divisia quantity variances systematically exceed the price variances. We will investigate this empirical regularity with data from 46 countries in Chapters 3 and 4. The last column of Table 1.7 presents the Divisia price-

International Consumption Comparisons

20

Table 1.6 Prices and per capita quantities consumed of eight commodities in 13 countries (Mean annual log-changes x 100)

o

Country

Li-

(2)

(1)

(J

(3)

o I (4)

Q

H

(5) P r i ices

(6)

(7)

V

6

a. (8)

(9)

1.

US

1.85

1.62

1.70

0.55

3.04

1.52

2.35

4.31

2.

Sweden

4.00

2.25

3.85

1.79

2.85

3.46

4.22

3.70

3.

Australia

2.32

1.39

4.87

0.48

3.15

1.96

2.92

3.02

4.

UK

2.1 1

1 .70

4.68

1.69

3.09

2.93

4.62

3.80

5.

Israel

4.85

4.65

7.81

1.94

6.46

8.06

5.97

7.22

6.

Italy

2.52

2.1 7

3.65

-0.16

4.24

2.27

4.07

4.19

7.

P u e r t o Rico

2.62

1 .44

1.27

0.83

5.76

2.83

3.20

2.46

8.

Ireland

3.18

0.89

3.98

3.1 5

1.33

3.13

3.63

4.24

9.

Greece

2.57

1 .20

1 .59

0.67

2.48

1.87

0.55

0.69

10.

South Africa

2.27

0.20

3.50

0.32

3.90

2.40

2.49

3.40

1 1.

Panama

1.95

0.59

0.54

0.1 1

2.24

0.04

0.97

0.00

12.

Thailand

1 3.

Korea

3.24 1 3.28

Mean

0.19 14.75

-2.63

-1.64

1.33

0.06

2.43

2.02

1 1.27

12.54

16.70

12.69

13.91

14.80

1 .71

4.35

3.29

3.95

4.14

3.60

2.54

3.54

Quantities 1.

US

0.99

2.42

2.79

3.70

3.90

2.78

2.86

3.63

2.

Sweden

1.51

1.76

2.77

5.25

5.62

5.32

2.28

4.03

3.

Australia

0.78

0.66

2.34

3.14

4.09

3.12

0.10

1.89

4.

UK

1 .62

2.44

1 .98

3.08

3.75

5.53

1.37

6.48

5.

Israel

4.62

6.87

5.41

1 1.67

5.96

9.24

8.58

5.17

6.

Italy

4.09

4.62

4.62

8.51

5.96

9.46

4.28

4.47

7.

P u e r t o Rico

-0.28

3.91

3.25

4.4 5

1.40

5.13

4.89

5.89

8.

Ireland

1.91

4.88

2.51

5.85

2.71

5.32

3.72

2.47

9.

Greece

4.14

7.92

5.99

6.41

5.67

8.94

8.08

6.48

10.

South Africa

1 .04

2.20

0.57

3.21

1.81

3.32

1.22

2.48

1 1.

Panama

2.59

3.23

1.92

5.06

2.55

2.01

4.36

2.84

12.

Thailand

2.1 5

5.30

1.06

10.16

3.70

6.55

5.59

7.16

13.

Korea

1.94

2.35

2.27

6.88

4.95

1 1.55

5.69

3.31

2.08

3.74

2.88

5.95

4.01

6.02

4.08

4.33

Mean

Source: Derived

from

Lluch et al. (1977,

Tables 3.4 and

3.5).

21

Chapter 1 An Overview

Table 1.7 Divisia moments in 13 countries

Country

Divisia quantity index

Divisia price index

Divisia quantity variance

Divisia price variance

Divisia price-quantity correlation

DQ

DP

K

n

P

(2)

(3)

(4)

(5)

(6)

1.

US

2.47

1.89

0.97

0.57

0.20

2.

Sweden

2.83

3.52

2.41

0.56

-0.42 0.09

(1)

3.

Australia

1.75

2.51

1.32

1.28

4.

UK

2.52

2.88

2.15

1.33

0.05

5.

Israel

6.30

5.85

4.40

2.89

-0.31

6.

Italy

4.94

2.82

2.53

0.79

-0.30

7.

Puerto Rico

2.49

2.40

5.17

1.32

-0.30

8.

Ireland

2.97

3.11

1.95

0.73

-0.42

9.

Greece

5.71

1.93

2.86

0.50

-0.80 -0.47

10. South Africa

1.67

2.23

0.96

1.24

11. Panama

2.76

1.21

0.73

0.65

-0.15

12. Thailand

3.37

1.92

4.51

3.63

-0.38

13. Korea

2.93

13.36

5.11

1.27

0.05

Mean

3.29

3.51

2.70

1.29

-0.24

All entries in columns 2 and 3 are to be divided by 100 and columns 4 and 5 by 10000.

quantity correlation. As can be seen, most of the correlations are negative with an average of -.24. The Linear Expenditure System

Stone's (1954b) linear expenditure system discussed in Section 1.2 is probably the most popular demand system. Notable studies using this model include

22

International Consumption Comparisons

Deaton (1975), Goldberger and Gamaletsos (1970), Kravis et al (1982), Lluch and Powell (1975), Lluch et al (1977), Parks (1969), Pollak and Wales (1969,1992) and Yoshihara (1969). In this section, we reproduce the estimation results of the linear expenditure system from the LPW study. LPW uses time-series data to estimate LES (or a variant thereof, Lluch's, 1973, the extended linear expenditure system) for the 13 countries listed in Table 1.4. The model is estimated for each country independently of the others. The upper part of Table 1.8 presents the estimates of the marginal shares (i=l,...,8 goods; c=l,..., 13 countries), while the lower part gives the implied income elasticities, ri

i c

=^, w

(4.1)

ic

using the mean budget shares from Table 1.5. As can be seen from the last row of Table 1.8, on average, food and housing are necessities (r|jc < 1), clothing is a borderline case while the remaining five goods are luxuries (r|iC > 1). Notwithstanding its popularity, LES has its drawbacks. Perhaps the most important is the parameterization whereby the marginal shares are treated as constants. It is clear from (4.1) that the constancy of the marginal share implies that the income elasticity is inversely proportional to the corresponding budget share. This can give rise to problems when income is subject to large changes.

1.5

Are Tastes Constant?

One of the other areas where consumer demand analysis is gaining significance is the argument that consumer tastes are the same or similar across countries. In

Chapter 1 An Overview

23

Table 1.8 Marginal shares and income elasticities for eight commodities in 1 3 countries

Country

o U-

u

I

a

CL

H

(5)

(6)

(7)

(8)

0.14 0.05 0.13 0.03 0.07 0.07 0.1 1 0.01 0.05 0.05 0.04 0.05 0.07

0.1 7 0.25 0.22 0.28 0.12 0.12 0.18 0.17 0.1 1 0.21 0.09 0.12 0.15

0.07 0.10 0.01 0.07 0.12 0.07 0.14 0.08 0.08 0.05 0.13 0.15 0.08

0.1 1 0.02 0.14 0.1 1 0.10 0.02 0.07 0.07 0.03 0.06 0.02 0.03 0.04

0.07

0.17

0.09

0.06

1.69 1 .41 2.33 1.30 1.00 1.05 1.65 1.08 1.33 1.02 0.94 0.93 1.76

1.1 5 1.78 1.71 2.54 1.59 1.44 1.43 1.93 1.55 1.56 0.90 1.56 3.1 1

1.18 1.09 0.21 0.88 1.44 0.93 1.56 1.19 1.36 0.98 1.69 2.00 1.77

2.31 1.00 1.14 2.65 0.97 1.06 1.95 1.19 1.22 1.44 0.83 1.56 1.73

1.35

1.71

1.25

1.46

(2)

(3)

(4)

Israel Italy 7. Puerto Rico Ireland 8. Greece 9. 1 0 . South Africa 1 1. Panama 1 2 . Thailand 1 3 . Korea

0.09 0.28 0.14 0.12 0.21 0.40 0.18 0.32 0.34 0.30 0.42 0.48 0.43

0.1 1 0.07 0.05 0.07 0.10 0.09 0.1 1 0.13 0.17 0.16 0.08 0.10 0.07

0.21 0.1 5 0.22 0.26 0.17 0.17 0.14 0.1 1 0.18 0.07 0.1 1 0.01 0.09

0.1 1 0.08 0.08 0.08 0.12 0.07 0.07 0.1 1 0.05 0.12 0.1 1 0.05 0.08

Mean

0.29

0.10

0.14

0.09

1.

US

2.

Sweden Australia

0.34 0.76 0.43 0.30 0.66 0.87 0.50 0.64 0.73 0.80 0.92 0.84 0.73

1 .14 0.62 0.46 0.63 1.10 0.86 1.06 1.34 1.38 1.39 1.10 1.20 0.66

0.91 0.91 1.73 1.41 0.90 1.03 0.94 0.84 0.96 0.40 0.68 0.16 0.75

1.45 1.13 1.05 1.1 5 1.61 2.16 0.99 2.00 1.28 1.47 1.77 1.63 2.75

0.65

0.99

0.89

1.57

(1)

O (9)

M arginal shares 1.

US

2. 3.

Sweden Australia

4.

UK

5. 6.

Income elasticities

3. 4.

UK

5.

Israel Italy Puerto Rico Ireland Greece South Africa Panama Thailand Korea

6. 7. 8. 9. 10. 11. 12. 13.

Mean

Source: Marginal shares are from Lluch et al. (1977, Table 3.6) and income elasticities are derived using equation (4.1).

24

International Consumption Comparisons

this section we present some cross-country and regional results directly from Clements and Selvanathan (1994, Sec. 8), which originated from the work of Selvanathan (1993, Chapter 4). In a highly-influential paper, Stigler and Becker (1977) advocates treating tastes as fixed. Their argument has merit as the utility maximization theory usually postulates that tastes are fixed, so that it is only the observable variables income and prices that explain consumption. Stigler and Becker show that a number of examples of apparently capricious behaviour (addiction, custom, tradition, fashion etc.) can in fact be reconciled with the assumption of stable preferences. Stigler and Becker (p.89) argue that, "no significant behaviour has been illuminated by the assumption of differences in tastes. Instead, they, along with the assumption of unstable tastes, have been a convenient crutch to lean on when the analysis has bogged down. They give the appearance of considered judgement, yet really have only been ad hoc arguments that disguise analytical failures." Selvanathan (1993, Chapter 4) carried out an analysis to test the hypothesis of stable preferences by estimating demand equations for different groups of consumers and then analysing the extent to which the parameters (such as the income and price elasticities) differ across consumers. Selvanathan performed the analysis with the OECD database (consisting of 15 countries with 10 commodity groups) by estimating (i) country-specific demand equations; and (ii) common demand equations for all countries whereby the data are pooled across countries. The test then involved an analysis of the deterioration in the fit of the demand equations when the data are pooled. In other words, this amounted to investigating the extent to which the same demand equations can explain consumption in the different OECD countries. The upper part of Table 1.9 contains the results using the root-meansquared (RMS) percentage prediction error as the goodness-of-fit criterion for

25

Chapter 1 An Overview

Table 1.9 Quality of budget share predictions in OECD countries and Australian states RMS percentage prediction error Country (1) OECD Countries 1. US 2. Canada 3. Sweden 4. Denmark 5. Australia 6. France 7. Belgium 8. Norway 9. Netherlands 10. Iceland 11. Finland 1 2. Austria 13. UK 14. Spain 1 5. Italy

Weight (xl 00) (2)

51.34 5.14 1.84 1.01 2.74 10.30 1.81 .72 2.42 .04 .82 1.25 8.57 4.78 7.20

16. Unweighted mean 1 7. Weighted mean Australian states 18. NSW 1 9. Victoria 20. Queensland 21. SA 22. WA 23. Tasmania 24. U n w e i g h t e d mean 25. W e i g h t e d mean

38.53 27.31 14.79 8.29 8.47 2.61

Individual country/state (3)

Pooled country/state (4)

1.65 3.16 1.88 2.16 2.41 1.39 2.59 2.07 3.20 4.70 3.68 2.34 1.77 2.33 1.88

1.72 3.32 1.91 2.16 2.46 1.39 2.74 2.35 3.58 4.99 3.67 2.50 1.79 2.29 2.13

2.48 1.87

2.60 1.95

2.16 2.49 3.07 2.47 2.54 3.42

2.14 2.59 2.97 2.51 2.46 3.56

2.69 2.47

2.70 2.48

The column 2 weights for the OECD countries are proportional to GDPs in 1975 in international dollars; and the weights for the Australian states are proportional to total consumption expenditures in 1981. The RMS percentage prediction errors in columns 3 and 4 are 100 times the square root of the budgetshare-weighted mean of the squared relative prediction errors of the budget shares; as an approximation, these are computed as 100 times the square root of twice the information inaccuracies.

26

International Consumption

Comparisons

the 15 OECD countries. Although the RMSEs for the country-specific models (given in column 3) are in general a bit lower than those for the pooled model (column 4), the differences are not substantial. In addition, the countries have similar rankings with respect to the two sets of RMSEs. Looking at the entries in row 17 of columns 3 and 4 of Table 1.9, the weighted means of the RMSEs are 1.87 percent for the individual country models and 1.95 percent for the pooled model. Accordingly, the average "cost" of taking tastes to be identical is 1.95 - 1.87 = .08 percentage points. This is clearly quite modest and points in the direction that tastes are not too dissimilar across countries. (For a different finding, however, see Pollak and Wales, 1987.) There are many non-economic differences between some of the OECD countries (see Tables 1.1 and 1.2). For example, language, culture and climate differ substantially in some cases. It may thus come as a surprise to some that tastes in these countries are more or less similar. In an attempt to control for some of the non-economic factors, Selvanathan and Selvanathan (1994, Chap.4) conducted a similar analysis with data from different regions of the same country, the six states of Australia. The lower part of Table 1.9 summarizes the findings and the result is that tastes are even more similar within a country, as expected.

References Chen, D.L. (2001). World Consumption Economics. Singapore, London: World Scientific. Clements, K.W., and S. Selvanathan (1994). "Understanding Consumption Petterns,' Empirical Economics 19: 69-110.

Chapter 1 An Overview

27

Clements, K.W., and H. Theil (1996). 'A Cross-Country Analysis of Consumption Patterns,' Chapter 7 in H. Theil (ed.), Studies in Global Economics. Advanced Studies in Theoretical and Applied Econometrics, Boston: Kluwer Academic Publishers, 95-108. Deaton, A.S. (1975). Models and Projections of Demand in Post-War Britain. London: Chapman and Hall. Gamaletsos, T. (1973). 'Further Analysis of Cross-Country Comparison of Consumer Expenditure Patterns,' European Economic Review 4: 1-20. Goldberger, A.S., and T. Gamaletsos (1970). 'A Cross-Country Comparison of Consumer Expenditure Patterns,' European Economic Review 1: 357-400. Houthakker, H.S. (1957). 'An International Comparison of Household Expenditure Patterns, Commemorating the Centenary of Engel's Law,' Econometrica 25: 532-551. Houthakker, H.S. (1965). 'New Evidence in Demand Elasticities,' Econometrica 33: 277-288. Kravis, LB., A.W. Heston and R. Summers (1978). International Comparisons of Real Product and Purchasing Power. Baltimore, Md.: The John Hopkins University Press. Kravis, I.B., A.W. Heston and R. Summers (1982). World Product and Income: International Comparisons of Real Gross Product. Baltimore, Md.: The John Hopkins University Press. Lluch, C. (1973). The Extended Linear Expenditure System,' European Economic Review 4: 21-32. Lluch, C, and A.A. Powell (1975). 'International Comparisons of Expenditure Patterns,' European Economic Review 5: 275-303. Lluch, C, A.A. Powell and R.A. Williams (1977). Patterns in Household Demand and Saving. Oxford: Oxford University Press.

28

International Consumption Comparisons

Lluch, C, and R.A. Williams (1975). 'Cross Country Demand and Savings Patterns: An Application of the Extended Linear Expenditure System,' Review of Economics and Statistics 57: 320-328. Parks, R.W. (1969). 'Systems of Demand Equations: An Empirical Comparison of Alternative Functional Forms,' Econometrica 37: 629-650. Parks, R.W., and A.P. Barten (1973). 'Cross-Country Comparison of the Effects of Prices, Income and Population Composition on Consumption Patterns,' Economic Journal 83: 834-852. Pollak, R.A., and TJ. Wales (1969). "Estimation of the Linear Expenditure System,' Econometrica 37: 611-628. Pollak, R.A, and T.J. Wales (1987). Pooling International Consumption Data,' Review of Economics and Statistics 69: 90-99. Pollak, R.A., and T.J. Wales (1992). Demand System Specification and Estimation. New York and Oxford: Oxford University Press. Selvanathan, S. (1988). A System-Wide Analysis of International and Interregional Consumption Patterns. Ph.D. Thesis, The University of Western Australia. Selvanathan, S. (1993). A System-Wide Analysis of International Consumption Patterns. Advanced Studies in Theoretical and Applied Econometrics, Boston: Kluwer Academic Publishers. Selvanathan, S., and E.A. Selvanathan (1994). Regional Consumption Patterns: A System-Wide Approach. London: Avebury Publishers. Stigler, A.J., and A.S. Becker (1977). 'De Gustibus Non Est Disputandum,' American Economic Review 67: 76-90. Stone, R. (1954a). The Measurement of Consumers' Expenditure and Behaviour in the United Kingdom, 1920-1938. Vol. 1, Cambridge: Cambridge University Press. Stone, R. (1954b). 'Linear Expenditure Systems and Demand Analysis: An Application to the Pattern of British Demand,' Economic Journal 64: 511527.

Chapter 1 An Overview

29

Theil, H. (1980). The System-Wide Approach to Microeconomics. Chicago: The University of Chicago Press. Theil, H. (1987). 'The Economics of Demand Systems,' Chapter 3 in H. Theil and K.W. Clements (eds.), Applied Demand Analysis: Results from System-wide Approaches. Cambridge, MA: Ballinger Publishing Company. Theil, H., and F.E. Suhm (1981). International Consumption Comparisons: A System-wide Approach. Amsterdam: North-Holland Publishing Company. Theil, H., D.L. Chen and C. Moss (1996). Studies in Global Econometrics. Boston: Kluwer Academic Publishers. Yoshihara, K. (1969). Demand Functions: An Application to the Japanese Expenditure Pattern,' Econometrica 37: 257-274.

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CHAPTER 2

Consumer Demand Models E.A. Selvanathan <& S. Selvanathan

One of the primary objectives of applied demand analysis is to estimate demand systems to analyse the income and price responses on consumer demand. With this objective, this chapter presents a review of the basics of demand theory. Section 2.1 presents the basics of the economic theory of the consumer. In Section 2.2, various structures of consumer preferences are discussed, and in Section 2.3, we discuss Theil's (1980) differential approach to derive the differential demand equations. Section 2.4 presents a number of flexible functional forms. In Section 2.5, we discuss the recently developed differential demand systems such as the CBS demand system (Keller and van Driel, 1985) and even simpler demand systems (Selvanathan, 1985). Finally, in Section 2.6, we briefly outline recent developments on issues associated with aggregation in consumer demand.

2.1

The Economic Theory of the Consumer

The objective of consumption theory is to analyse the demand for goods and services in terms of income and prices. Such a relationship between the quantity demanded, income and prices is called a demand equation. A most straight-

32

International Consumption

Comparisons

forward way of generating demand equations is to derive them by maximizing the consumer's utility function subject to his/her budget constraint. Let qu..., qn be the quantities consumed of n goods and let ph..., pn be the corresponding prices. Then,

M= z,Piqi

(i.i)

i=l

is the total expenditure, which shall be referred to as 'income1 for short. Equation (1.1) is also known as the budget constraint. The proportion of income spent on good i, Wi=ML

(1.2)

M is called the budget share of good i. These budget shares are positive and, in view of (1.1), they all sum to one. That is, I

w,=l.

(1.3)

The consumer chooses the n x 1 quantity vector q = [q{] to maximize the utility function u(q), subject to the budget constraint (1.1), written in vector form as p'q = M, where p = [p{] is the (n x 1) price vector. Thus the maximization problem takes the Lagrangian expression, u*(q,X) = u(q)-X(p'q-M),

(1.4)

33

Chapter 2 Consumer Demand Models

or, in scalar form, u*(qu ...,q„,X)

= u(qu

...,qn)-X

where X is the Lagrangian multiplier. The solution to this maximization problem leads to a Marshallian demand equation for good i: qx =

qi(M,pu...,pn),

i=l,...,n.

(1.5)

The first-order conditions for the above maximization problem are the budget constraint (1.1) and du

.

i=l,...,n.

(1.6)

i=l,...,n.

(1.7)

Re-arranging (1.6), we can write X =

du

tyPi^Y

The right-hand side of (1.7) can be interpreted as the change in utility for a $1 increase in income, where this increase comes from the increase in the expenditure on any commodity i, i=l,2,.. .,n. Therefore, one could interpret X in (1.4) as the marginal utility of income. We assume that there is a generalised diminishing marginal utility so that the Hessian matrix of the utility function

34

International Consumption Comparisons

is negative definite. As Hessians are symmetric, U is a symmetric negative definite n x n matrix. The main emphasis of this book is the utility-based approach to demand analysis. However, there is an older, more traditional approach that directly specifies the demand equations without any reference to the utility function (see, for example, Cassel, 1932; and Stone, 1954a). A popular example of such directly specified demand equations is the double-log demand system: log # = oti + rii log M + 2X-logpj,

i=l,...,«,

(1.8)

where 0Cj is an intercept term. The coefficient rj; is the income elasticity of commodity i, defined as

^=

*i±*L dM/M

=

*Q?*5LI, d(logM)

!=!,...,«.

(i.9)

The income elasticity answers the question, if income rises by 1 percent with prices held constant, what is the percentage change in the consumption of i? Commodities with income elasticity less than 1 are called necessities, while those with income elasticity greater than 1 are called luxuries. If the income elasticity is negative, then that commodity is said to be an inferior good as its consumption falls with increasing income. The coefficient r^ is the

35

Chapter 2 Consumer Demand Models

uncompensated price elasticity of commodity i with respect to the price of commodity j , defined as

dPj/pj

d(logpj)

This coefficient answers the question that, if the price of commodity j increases by 1 percent, with income and other prices held constant, what is the percentage change in the consumption of i? If i = j , riy is known as the own-price elasticity and if i^j, r|ij is known as the cross-price elasticity. The Marshallian (or money-income-constant) demand equation can be transformed into its Slutsky (or real-income-constant) counterpart by using the Slutsky decomposition for the uncompensated price elasticity,

•Hij = "njj - Wjtii,

(i.ii)

where r)^ is the (ij)* compensated price elasticity and Wj is the budget share of good j , the proportion of income spent on j . After some algebraic manipulation of model (1.8) and using (1.2), (1.3) and (1.11), we can derive the Slutsky demand equation for good i as: log # = a; + Tli log g + ZTU- logpj,

i=l,...,n,

(1.12)

where log Q = log M - log P, with log P - YJ)=\ wj log Pj. the Divisia price index. That is, log Q is money income (log M) deflated by the price index

International Consumption Comparisons

36

(log P), or a measure of the consumer's real income. Note that real income and the compensated price elasticities r\'tj appear on the right-hand side of (1.12), while money income and the uncompensated elasticities f]^ are in (1.8). Consider the multiplication of the budget share of commodity j by the corresponding income elasticity,

WjTlj

_ Pjlj

d(loggj)

_ pjqj

dqj/qj

~

d(logM)

~

dM/M

M

M

_ Pj

dqj^ _

d(pjqj)

dM

dM

~

The far right-hand term answers the question, if income increases by $1, how much of that will be spent on commodity j? This quantity is referred to as the marginal share, 0j, of commodity j . That is,

6j =

' J dM

,

j=l,...,n.

(1.13)

As with the budget shares, the marginal shares also sum to unity. That is,

£ 6 '" - 7=1 ??%* •-in—£

7=1

• >•

<«•">

If we divide the marginal share by the corresponding budget share, we obtain the corresponding income elasticity. That is,

37

Chapter 2 Consumer Demand Models 0d(pjqj) J —*- = — Wj dM

1

Bqj/qj = —dM/M

(Pjqj)/M

d(logqj) — = rij. d(logM)

=

(1.15)

Furthermore, the budget-share-weighted average of the income elasticities also sum to unity. That is, n E Wylly

=

7=1

n 0 .• n I W ; — = I Qj =1j=\

Wj

(1-16)

j=\

Equation (1.16) is also called Engle aggregation. The consumer's maximization problem implies two testable constraints on the demand equations. The first constraint on the demand equations is demand homogeneity, which states that if income and prices all increase proportionally, then the quantity demanded of each good will remain unchanged. For example, suppose that all prices and money income double, then demand homogeneity assures us that this change would have no effect on consumption [or, equivalently, the demand function (1.5) is homogenous of degree zero], that is, qiaM,apx,...,apn)

= a0qj(M,pu...,pn)

=

qi{M,pi,...,pn).

In the context of equation (1.8), demand homogeneity can be expressed as In,-, + r|,= 0, 7=1

i=l,...,n.

(1.17)

38

International Consumption Comparisons

That is, the sum of the own- and cross-price elasticities and the corresponding income elasticity for each good is zero. In the context of equation (1.12), demand homogeneity (1.17) can be expressed as

£

riij = 0,

i=l,...,/i,

(1.18)

where we have also used equations (1.3) and (1.11). The second constraint on the demand equations is symmetry of the substitution effects, or Slutsky symmetry. This states that, when real income is held constant, the effect of a $1 rise in the price of good j on the consumption of good i is equal to the effect of a $1 rise in the price of good i on the consumption of good j . Consider the price derivative (or equivalently, the slope of the demand equation), dqjdpj. Going back to equation (1.12), this slope can be written as

dqt dpj

=

qi d(log qt ) pj d(logpj)

=

qt Pj

iy

Symmetry states that, this slope is the same when we interchange the i and j subscripts, that is, dqjdpj = dq-Jdpt. This means that (q/Pj)viij = (#/Pi) ^ ;,•, or, multiplying both sides by p-p-JM, we have

wxViu = WjTl'-,.,

ij = 1

»•

(1.19)

Chapter 2 Consumer Demand Models

2.2

39

The Structure of Preferences

Consider demand equations (1.12) for i = l,...,n goods. In this system of n equations there are n intercepts, oci, ..., a„, n income elasticities, r\i, ..., r)„, and n2 price elasticities r)^, i,j = 1,...,«, so that the total number of coefficients is n + n + n2 = n(n + 2). For a moderate-sized system of n = 10 goods, this total equals 120, which is an impossibly large number of coefficients to be estimated in an unrestricted fashion. Even when we take account of the homogeneity, symmetry and adding-up restrictions, the number of coefficients is still in the order of n2. One way of reducing the number of coefficients to be estimated is to set to zero some of the cross-price elasticities (TU- for i ^ j) in equation (1.12), perhaps on the basis of the intrinsic nature of the commodities involved or on the basis of prior evidence. A more systematic approach is to pattern the n x n elasticity matrix [TU- ] by further structuring the nature of the consumer's utility function u(qu--;qn)- Important early contributions in this area include Barten and Turnovsky (1966), Goldman and Uzawa (1964), Gorman (1959, 1968), Leontief (1947), Pearce (1961, 1964), Sono (1961) and Strotz (1957). A number of publications in this area have also appeared recently (see, for example, Baccouche and Laisney, 1991; Driscoll and McGuirk, 1992; Edgerton, 1993; Lewbel, 1995, 1996; Moschini, 1992; and Moschini et al, 1994). Suppose the n goods are broad aggregates such as food, clothing, housing and so on. It is then not unreasonable to view the demand for each good as representing the desire for some characteristic(s) unique to each good: food provides nutrition and taste, clothing provides warmth and style, and housing provides shelter. These unique, or basic, characteristics represent fundamental desires which generate utility. Moreover, for them to be truly basic characteristics, it should be the case that there is little or no interaction between

40

International Consumption Comparisons

them in the utility function, so that utility is generated by the consumption of food and clothing and housing, with the emphasis on the 'ands' representing the notion of additivity. These ideas can be formalized by an additive utility function, whereby utility is the sum of n subutility functions, one for each good: u(qu...,qn)

n

= £ Ui(qi),

(2.1)

i=\

where u\(qd is the sub-utility function for good i. According to (2.1), each marginal utility is a function of only the good in question, du/dqt - 3w/3g„ and is independent of the consumption of all other goods, that is, d2u/dqidqj = 0, i * j . Accordingly, (2.1) is also known as the preference independence (PI) form of the utility function. An example of (2.1) is the well-known Klein-Rubin (1948) or Stone-Geary utility function, u(q) = £"=iPil°g(?i -Y;) which is additive in log(gi-Yi)."-.log(gB-Y„)To analyse the implications of preference independence, let 8y be the Kronecker delta (8y = 1 if i=j, 0 otherwise) and define § to be the reciprocal of the income elasticity of the marginal utility of income, =

f a(logX) |_3(logM)

< 0,

where X is the marginal utility of income, see the discussion below equation (1.7). For brevity, we shall refer to (() as the income flexibility. The income flexibility (> | is expected to be negative. If preferences are of the form (2.1), the (ij)* price elasticity then becomes (see, e.g., Clements et al, 1995):

41

Chapter 2 Consumer Demand Models Tly =
(2.2)

If we use (2.2) in demand equation (1.12), the substitution term then becomes £

Tly log p-} = (hidogpi-logP 1 ),

(2.3)

7=1

where log P' = 27J=j97logpy- is the Frisch price index. In contrast to the Divisia price index defined below (1.12), which uses budget shares as weights, the Frisch index uses marginal shares as weights. As luxuries (rjj > 1 or, equivalently, 0 ; > w;) have marginal shares in excess of their budget shares, it follows that luxurious goods are more heavily weighted in the Frisch index than in the Divisia index. Using (2.3) in (1.12), the i* demand equation under preference independence takes the form log q-, = <Xi + Tii log Q + <|nii log

i=l,...,/t.

(2.4)

This shows that preference independence implies that only the own-relative price appears in each demand equation and that the own-price elasticity is §r\i. Accordingly, under preference independence, there are no specific substitutes or complements (Houthakker, 1960). Additionally, as § and the own-price elasticity <pr|i are both negative, preference independence implies that each income elasticity r|j is positive, so that inferior goods are ruled out. A further implication of preference independence is that the own-price elasticities (<|>r)i) are proportional to the corresponding income elasticity (T);), with the

42

International Consumption Comparisons

income flexibility ((|)) the (negative) proportionality factor. In other words, luxuries are more price elastic than necessities. The final feature of preference independence to note is the reduction in the number of unknown parameters in the demand equations. As stated above, in the unrestricted demand equation (1.12) for i = l,...,n there are n2 unknown price elasticities. By contrast, in (2.4) for i = \,...,n there is only one free parameter in the substitution term, the income flexibility (j). Altogether, there are (2ra + 1) parameters, au oc2, ..., oc„; r|i, r)2, ..., t|„ and <|), in the system of demand equations (2.4), which is in the order of n rather than the previous system of equations (1.12) which is in the order of n2. A weaker version of preference independence is block independence whereby the consumer's utility function is additive in groups of goods, rather than individual goods. Let the n goods be divided into G (< n) groups, written Si, ..., SQ, such that each good belongs to only one group. Then, preferences are of the block independence form when the utility function is the sum of G group utility functions, each involving the quantities of only one group, G

u{qu...,qn)

=

X wg(9g),

(2.5)

8=1

where qs is the vector of the qfs that fall under group Sg. Thus, if, for example, alcoholic beverages (beer, wine and spirits) make up one block-independent group and all other goods another, the marginal utility of, say, beer would then be affected by the consumption of wine and spirits, but not by the consumption of any good outside the alcoholic beverages group. Demand equation (1.12) for good i e Sg implied by (2.5) is (see, e.g., Clements and Selvanathan, 1991):

Chapter 2 Consumer Demand Models log # = OCi + Tli log <2 + 2 jeSg

43

fi TU.log^-, P

(2.6)

where r)^ is the (ij)* price elasticity (strictly speaking, this is also a Frisch price elasticity which holds constant the marginal utility of income). The Frisch elasticities are subject to the restriction I

Viij

=


ieS g .

(2.7)

jeSg

Equation (2.6) is to be compared with (2.4), the corresponding demand equation under preference independence. The assumption of preference independence implies that only the own relative price affects consumption, while block independence means that only the relative prices of goods in the same group as the commodity in question play a role. If the alcoholic beverages group comprises beer, wine and spirits, and if these form a block-independent group, then only the relative prices of the three beverages affect the consumption of each beverage and the prices of other goods play no role. It can therefore be seen that there is an appealing unification between preferences and demand equations.

2.3

Differential Approach to Deriving Demand Equations

The double-log demand system (1.8) considered in Section 2.1 is directly specified without any reference to the utility function. In this section, we apply

International Consumption Comparisons

44

the method of comparative statistics to derive the demand equations (1.5) in the form of partial derivatives starting from a general form of the utility function. Divisia Indices in Differential form

The differential of the budget constraint (1.1) is n

n

I Ptdqi + I q-APi = dM i=l

i=i

Dividing both sides by M and using the identity that dx/x = d(log x) and (1.2), we obtain d(log Q) + d(log P) = d(log M) where d(logQ) = t

Wid{logqi)

i=l

and d(logP) = t

M>id(!ogPi)

i=l

are the Divisia volume index and Divisia price index, respectively. The above equation decomposes the change in income into a volume and price index.

45

Chapter 2 Consumer Demand Models Barten's Fundamental Matrix Equation

The derivation of the demand equations using the method of comparative statistics involves the use of the first-order conditions (1.1) and (1.6) of the consumer utility maximization problem (1.4). We treat p\, p2, •••, pn and M as exogenous. Differentiating the budget constraint (1.1) with respect to pj and M, we get L Pi^—

= -*.

I P / ^ 7

= 1-

j=l,...,n,

(3.1)

and ;=1

(3-2)

dM

Equations (3.1) and (3.2) can be written in matrix form as - dq PT7 dp

=

1

>

,,,,,, (3-3)

and P'^7 dM

= l>

(3 4)

-

where dq/dp' = [dqjdpj] is the n x n matrix of price derivatives of the demand functions and dq/dM = [dq\/dM] is the vector of n income slopes of the demand functions. Differentiating (1.6) with respect to/?j and M, we get

46

International Consumption Comparisons "

d u

dqk

k=l dqtdqk

=

dpj

, ,, dX h&ij + Pi dPj'

i,j=l,...,w,

(3.5)

i=l,...,n.

(3.6)

where 5;, is the Kronecker delta, and d2u

«

dqk

k=\ dqidqk

Pi

dM

dX dM'

We write (3.5) and (3.6) in matrix form as U

,_ dX XI + p——

dq dp'

(3.7)

and U

dX

dq dM

dM

(3.8)

P,

where U is the Hessian matrix defined below (1.7). I is the n x n identity matrix and dX/dp' = [dMdpfi. Combining (3.3), (3.4), (3.7) and (3.8), we get U

dq

dq

p

dM

dp'

O

dX

dX

dM

dp'

0

XI (3-9)

p'

1

-q

The above matrix equation is known as Barten's Fundamental matrix equation in consumption theory (Barren, 1964).

Chapter 2 Consumer Demand Models

Al

If we solve equation (3.9) with respect to the first-order derivatives, we obtain the solutions

dM

(3.10)

p'U~xp

—^-U-xp(V-1py--^-rV-lpq', p U p p U p

dp'

(3.11)

dA dM

(3.12) p'U^p'

and dA dp

A l

p'U p

U

. P

1 Tl T T T - ^ p'U p

(3.13)

where we have also used U

-l

1

(p'u-lP)U'1 -u-'pifj-'py

p'U'p

u'p

(u-'py

-l

Now, we return to equation (1.5), the Marshallian demand equation for good i. The differential of (1.5) is given by (e.g. Theil and Clements, 1987; and Selvanathan and Clements, 1995): dq,

a 8^ = ~^dM + £ 9iZ^-dp:, dM j=idpj

i=l,...,n.

48

International Consumption Comparisons

If we multiply both sides of the above equation by p-JM, it can be transformed into the form

wid(logqi) = Qid(logU) + i^p^d(logpj), 7=1 M

dpj

J

i=l,...,n.

(3.14)

Relative Price Version

Using equations (3.10)-(3.13) and (3.14), we can easily derive the following simplified demand equations in relative prices: wi d(log q-d = 6i d(log Q) + £ v dlog EL y=i F

i=l,...,n,

(3.15)

where 0j = w\f\t is the i* marginal share; d(log Q) = d(log M) - d(log P) = X"=i Wjd( log qt), is the Divisia volume index of the change in the consumer's real income; d[log (p/P')] is the change in the deflated price of j with d(log P') = X°=i#jd(log p.) is the Frish price index: and Vy = (k/M)piu''pj is the (ij)"1 price coefficient, with X the marginal utility of income and u'1 the (ij)* element of the inverse of the Hessian of the utility function, U = [d2u/dq,dqj\. Note that the coefficients 9j and Vy are not necessarily constant. The price coefficients, Vy, satisfy Z^i^y = <|>0i, i=l, ....,«, where <j) is the income flexibility, defined in Section 2.2. Equation (3.15) above is the i'h demand equation of the relative price version of Their s (1980) differential demand system. The first term on the right of (3.15) gives the effect of real income on the demand for goodi. This term is a multiple Q, of the Divisia volume index d(log g). As this volume index equals d(log M) - d(log P), where d(log P) is the Divisia price index, it follows that the Divisia price index transforms the change in money income into the change in real income. Furthermore, as the Divisia

49

Chapter 2 Consumer Demand Models

price index is budget-share-weighted, it follows that this index measures the income effect of the n price changes on the demand for the i* good. The second term on the right of (3.15), EjLiVjjdTlogCpj IF)], deals with the effects of relative prices. The Frisch price index acts as a deflator of each price change, so that we refer to d[log (p/P1)] as the change in the Frisch-deflated price of j . Using the fact that Z;=i v y =¥*i> it c a n be shown that the substitution term can be written as the difference between X"=i Vjjd(log Pj), which is the specific substitution effect of the n prices on the demand for good i, and 6id(log P') is the general substitution effect. Accordingly, the general substitution effect acts as the deflator of the specific effect by transforming absolute prices into Frisch-deflated prices. If Vy > 0, then an increase in the Frisch-deflated price of j causes consumption of i to increase. Consequently, we follow Houthakker (1960) and define goods i and j as specific substitutes (complements) if Vy > 0 (< 0). Absolute Price Version

Equation (3.15) is formulated in terms of relative (or deflated) prices. The corresponding absolute price version is

Wid(log^)

n = 9id(log<2) + X 7iijd(logpj),

i=l,...,n,

(3.16)

where 7ty = Vy - <|)9j0j is the (i,j)* Slutsky coefficient. Equation (3.16) is the absolute price version of the differential demand equation. These coefficients satisfy demand homogeneity £ 7=1

7Tij= 0,

i=l,...,«,

(3.17)

50

International Consumption Comparisons

and Slutsky symmetry 7tij =

7tji,

i,j = l, ...,«.

(3.18)

The n x n matrix [Tty] is negative semidefinite with rank (n-l). Dividing both sides of (3.16) by w\, we obtain 0/w, as the income elasticity of demand for i; and Tii/Wj as the (ij)* Slutsky price elasticity. Preference Independence Version The two versions of the demand model discussed above, the absolute price version and the relative price version, both have their own attractions. The absolute price version (3.16) and the constraints (3.17) and (3.18) are linear in the parameters, which makes estimation and testing straightforward. However, when n becomes larger, as discussed in Section 2.2, the number of Tty's grows rapidly, making the absolute price version of the model suitable for small systems only. For larger models, it is necessary to use the relative price version of the model (3.15) (which is non-linear in the parameters) with suitable constraints on the v^'s. These constraints take the form of postulating that certain goods do not interact in the utility function. One such form is the preference independence, discussed in Section 2.2, when no good interacts with any other. Under preference independence, we have Vy = 0 for i * j

and

VH

=

fyQ,,

i,j = 1, ..., n.

Then, under preference independence, the relative price version of the demand model, (3.15), becomes

51

Chapter 2 Consumer Demand Models Wj d(log qd = 8i d(log Q) + 00,.d log

F

i=l,...,n.

(3.19)

The number of unconstrained coefficients in (3.19) for i=l,...,/i is n, which is made up of n-\ unconstrained 6i's (1 is constrained by Z"=i#, = 1) and (j). The Rotterdam Model

The coefficients of the demand equations (3.15), (3.16) and (3.19) are functions of income and prices. In general, these coefficients need not be constants. The Rotterdam model, derived below, parameterizes these coefficients. Equations (3.15), (3.16) and (3.19) are formulated in terms of infinitesimal changes. The Rotterdam model, due to Barten (1964) and Theil (1965), are finite-change versions of these equations. We write, Dxt = log xt log xt.i for the finite log-change from period t-1 to t for any positive variable x. The variable d(log q{) on the left of (3.15) becomes Dqlt and d[log (p/P1)] becomes (Dpjt - DP't), where DP\ = J^^QiDpi,, is a finite-change version of the Frisch price index. As the budget share w\ on the left of (3.15) does not involve a change, we could use either Wj?t-i or Wj,t or a combination thereof which treats t and t-1 symmetrically. The natural choice is to use the arithmetic average of wiit.i and wiit, wit = V£(wijt.i + wiit), which is mid-way between the two extremities. The finite-change version of (3.15) is then witDqit = QiDQt + I

va(Dpjt - DFO,

i = 1,..., n,

(3.20)

where Dgt = Z?=i wu D
52

International Consumption Comparisons

known as the i'h demand equation of the relative price version of the Rotterdam model. The finite-change version of the absolute price version (3.16) is witDq,t = QiDQt+tniJDpjt,

i = 1,..., n.

(3.21)

When the coefficients 9j and 7iy are specified as constants, (3.21) is known as the i'h demand equation of the absolute price version of the Rotterdam model. It follows from the relationship, 7iy = Vy - 9j9j, that the constancy of the coefficients 9j, Vy and § in the relative price version of the Rotterdam model implies that the Slutsky coefficients 7iy are also constant in the absolute price version. The finite-change version of the Rotterdam model under preference independence, equation (3.19), becomes w„ Dqit = Gj D& +
i = 1,..., n.

(3.22)

where the coefficients (|) and 9j are specified as constants.

2.4

Other Popular Demand Systems

The differential demand system (3.15) in relative prices and (3.16) in absolute prices derived in the last section are completely general, as their coefficients are not necessarily constants. This is in contrast to most other approaches of generating systems of demand equations. The other approaches involve the algebraic specification of either the direct utility function, the indirect utility

53

Chapter 2 Consumer Demand Models

function or the cost function. Consequently, the coefficients of the resulting demand equations are constants. In this section, we introduce three such wellknown demand systems, namely, the linear expenditure system (LES), the Translog Demand System (TRANSLOG) and the Almost Ideal Demand System (AIDS). Linear Expenditure System (LES)

The linear expenditure system (LES) can be derived by directly specifying the utility function as U(q) = u(qu q2,...,q„)

=

£ P; log (q, -yt),

(4.1)

where Pi > 0, Yi < q, and Xf=iP< = 1- Th e utility function (4.1) is the well-known Stone-Geary utility function. This utility function has also been previously considered by Klein-Rubin (1948). Another point worth noting about the structure of U(q) is that this utility structure will fall under the preference independent type as U(q) can be written as the sum of n individual utility functions, n

u{q) = u{qh...,qn)

= £ «,•(
where Ui(^) = Pi log (qt - Yi )• If we apply the first-order condition (1.6) to the utility function (4.1) we obtain, PiGi = PiYi + Pi M-t

PjJj

i=l,...,n.

(4.2)

54

International Consumption Comparisons

This is the algebraic form of the demand equations (1.5) associated with the Stone-Geary utility function (4.1). As expenditure on good i is a linear function of the n prices and income, (4.2) is known as the linear expenditure system (LES). If the Yi's are all positive, then (4.2) has the following interpretation. The consumer first purchases Yi units of good i at a cost of p^; this can be termed subsistence consumption of that commodity. The total cost of subsistence is Y!)=\PjYj> which leaves M - YIj=\PjY j a s supernumerary income. A fixed fraction Pi of supernumerary income is then spent on good i. The linear expenditure system was first applied to data by Stone (1954b); for other applications, see Deaton (1975) and Lluch and Powell (1975). It follows from (4.2) that the marginal share 8j = dip, qi)/dM implied by the linear expenditure system is equal to the constant coefficient Pi. Consequently, the income elasticity of i takes the form r\> = —,

i=l,...,n.

(4.3)

A rise in income with prices held constant causes the budget shares of necessities to fall and those of luxuries to rise. It then follows from (4.3) that increasing affluence causes the income elasticities of necessities to rise, while those of luxuries fall; the elasticities of both types of goods become closer to unity. Take the case of food, a necessity. The linear expenditure system implies that as the consumer becomes richer, the income elasticity, r|j, for food increases, causing food to become less of a necessity or more of a luxury. This behaviour of the elasticity is implausible as food should be less of a luxury for a richer consumer.

55

Chapter 2 Consumer Demand Models

Recall that the coefficient Pi in the Klein-Rubin must be positive. As this coefficient is interpreted as the marginal share in (4.2), it follows that the LES does not admit inferior goods. The uncompensated price elasticities under LES are given by (liZiiis

-p.X^L,

a

i

i,j=l,2,...,«.

(4.4)

PiQi

Translog Demand System

Another way of deriving the demand equations is by specifying the form of the indirect utility function. By substituting the demand equations (1.5) into the utility function u = u(q), we can write the utility function as a function of income and prices, u = u[q(M,p)]=U1(M,p).

(4.5)

The function U] is called the indirect utility function and it gives the maximum utility attainable corresponding to given values of income and prices. Roy's (1942) theorem, duj /dp: %= , l . / ' ,

. , 1=1,...A

(4.6)

gives a way of generating a system of demand equations from a specified form of the indirect utility function. Christensen, Jorgenson and Lau (1975) applied Roy's theorem to the following translog indirect utility Junction,

56

International Consumption Comparisons U,(M,p) = I P,.to*- £ + Vz 11

Py log %-log ^-,

(4.7)

where Pi's and py's are constants. Application of (4.6) to (4.7) yields the following demand equations

ft + ipa-fo*-^ J

Wi =

—

n

n n

,

i=l,...,n.

(4.8)

V;

ZPt + I I P ^ ^ - J *=1

A=l;=l

M

This demand system is called the translog demand system. Almost Ideal Demand System (AIDS)

The consumer's cost function is dual to the (direct) utility function in that it gives the minimum expenditure needed to attain a specified level of utility, given the prices. The cost function is also referred to as the expenditure function. By specifying the form of the cost function and then applying the Shephard's lemma dC • — =
i=l,...,«,

(4.9)

we can derive the corresponding demand function. Deaton and Muellbauer (1980a, 1980b) specified the cost function as C(u,p) =

a(p) + ub(p) e

,

(4.10)

57

Chapter 2 Consumer Demand Models where a(p) = S a,- log Pi + Vi £ I Y«7 log pt log p • i=l

«=ly=l

and 1 KP) = Pon^ , 1=1

with otj's, Pi's and Yy's all being constants. Applying (4.9) to (4.10), the resulting demand system can be written in the form n M w-, = oil + ft log—-+ EYi/togPj,

i=l,...,n,

(4.11)

log P = a(p) = I or,, log p, + Vi I I r y log A log p , .

(4.12)

where

i=l

i=l y=l

Deaton and Muellbauer refer to (4.12) as the almost ideal demand system or AIDS for short. The income and uncompensated price elasticities implied by AIDS are i=l,...,n,

(4.13)

Wi

and Tlij = - 5y +

r0-PAwj-fijlog

'M^ \ r

, i,j=l,...,«.

(4.14)

j

The estimation of (4.11) is more complicated when we use log P defined by (4.12). A more simple variant form of (4.12) is known as Stone's index,

58

International Consumption Comparisons

logP = I wklogPk.

(4.15)

k

With (4.12) replaced by (4.15), the budget share equations (4.11) are linear in the parameters to be estimated, viz, o.\, PJ and the Yij's. Working's Model

If prices are constant, as is approximately the case for the household expenditure survey, and if we choose units such that the price of each good is unity, then the AIDS model (4.11) simplifies to w\ = oCj + PilogM,

i=l,...,«.

(4.16)

In words, the budget shares are linear functions of the logarithm of income, which was first proposed by Working (1943) to analyse the household budget data. As the sum of all budget shares is unity, it follows from (4.16) that £f=l a i = 1 and X?=iP; = 0. Choosing the income unit such that M=l for some household, 0Cj is then interpreted as the budget share of i for that household. The coefficient Pi gives us 100 times the change in the budget share of commodity i (AWJ x 100) resulting from a 1 percent increase in income. Under Working's model the marginal shares and the income elasticity are given by 6i = Wi+Ps

(4.17)

and Tii = 1 + i-i-. w

i

(4.18)

59

Chapter 2 Consumer Demand Models

Equation (4.18) shows that a good with positive (negative) Pi is a luxury (necessity). As the budget share of a luxury increases with income, prices remaining constant, it follows from (4.18) that increasing income causes the income elasticity r|j of such a good to fall towards 1. The income elasticity of a necessity also declines with increasing income under (4.18). Thus as the consumer becomes more affluent, all goods become less luxurious under Working's model, which is plausible. This behaviour of the income elasticities is the same as that under the AIDS model. By contrast, under the LES the income elasticities of necessities increase, which is implausible, as discussed previously.

2.5

More on the Differential Demand Equations

In this section, we derive the more simple demand systems developed by Keller (1984) and Selvanathan (1985). Taking the differential of wt = p\qJM, we obtain dw; = Wj d(log j d(log pi) - Wj d(log M).

(5.1)

Substituting for w\ d(log qi) from (3.16) into (5.1) gives, n

dwi = 6id(logQ)+ Y1nijd(logpj) +

wid(logpi)-wid(logM)

j=i

+ wi d(log P) - Wj f > • d(log p •), 7=1

60

International Consumption Comparisons

where we have added and subtracted the same term, Wj d(log P), on the right hand side and used d(log P) = £ w;d(log Pj). Recognising that d(log M) - d(log P) = d[log (M/P)] = d(log Q), we can simplify the right-hand side terms as n

dwi = (6i - Wi)d(log 0 + £ (7t,7 + w,-8(>- - w,-w,) d(log pj), 7=1

which can be written as dwi = pi d(log 0 + I Yyd(log /?;),

(5.2)

7=1

where Pi

= Gi-Wj

(5.3)

and yij=nu

+wiSij-wiwj.

(5.4)

Equation (5.2) is the differential version of the AIDS model (4.11). If we reparameterize (3.16) using (5.3) in the form fy = Pi + w;, we get

Wi[d(log qO - d(log 0 ] = ^ d(log 0 + 1 ^d(log Pj). 7=1

(5.5)

61

Chapter 2 Consumer Demand Models

Equation (5.5) is named by Keller and van Driel (1985) of the Dutch Central Bureau of Statistics (CBS) as the CBS demand system. This system has the AIDS income coefficients, (3;, and the Rotterdam price coefficients, Tty. After re-arranging, equation (5.2) can be written in the form dwi + Wi d(log 0 = 9i d(log Q) + tY«d(log Pj).

(5.6)

7=1

Equation (5.6) has the Rotterdam income coefficients and the AIDS price coefficients as constants. Equation (5.6) was considered by Neves (1987) and was called the NBR system. The restrictions on the new coefficients, Pi's and Yy's, are SP,=0;

lY(,-=0;

£ Y,>-=0;

/=i

(=i

j=\

Yy = Yji;

and [jy + WjWj - w ; 5 y ] is negative semi-definite. In order to reduce the number of parameters, fty's, which is in the order of n2, Keller (1984) proposed the following decomposition for ny, ny

=

X(\\fAj - \|Wj).

(5.7)

Under (5.7), equation (5.5) becomes Wi[d(log

q{) - d(log 0 ] = pi d(log Q) + >u|/i [d(log A ) - d(log PJ],

(5.8)

where d(log P^ = Z 7 ^ ; d(logp 7 ). Keller (1984) refers to equation (5.8) as the CBS substitution independence (CBS/SI) model.

62

International Consumption Comparisons With specification (5.3), the model under preference independence (3.20)

becomes Wi[d(log <7i)-d(log 0 ] = Pid(log Q) + (Kfr + wO[d(log Pi)-d(log P')l,

(5-9)

where d(log P') = Z / P 7 + Wj)d(log pj). Keller and van Driel (1985) refers to equation (5.9) as the CBS preference independence (CBS/PI) model. Note that if X|/i = Pi + w\ and X = <|>, then equation (5.8) becomes (5.9). If \|/i = W{, then equation (5.8) becomes Wi [d(log

?i)-d(log 2)] = Pid(log Q) + XwifdOog pO-dOog P)l

(5.10)

Selvanathan (1985) refers to equation (5.10) as an Even Simpler demand system. As most of the applications of these models are with finite-change data, we now present the finite-change versions of these models. The finite-change versions of the four demand systems, the CBS demand system (5.5), the NBR demand system (5.6), the CBS/SI demand system (5.8), the CBS/PI demand system (5.9) and Selvanathan's even simpler demand system (5.10) can be written as follows: CBS demand system: wit(Dqit

-DQt)

= ^DQt+

inijDpj,

(5.11)

NBR demand system: Aw, + wuDQ,

= 9iD<2t+ iVijDpj,

(5.12)

Chapter 2 Consumer Demand Models

63

CBS/SI demand system: wit(Dqit-DQt) where DP vt

= p i Dj2, + X\|/ i (Dp it -DP v )

=YJJ\fjDpjt.

CBS/PI demand system: wit(Dqu -DQt)

= (3iDQ, + (P, + wit)(Dpit -DPt)

(5.14)

Where DP/ =Z;(P;+W;,)Dp;,.

Selvanathan's even simpler demand system: wit {Dqit -DQt)

= Pi D(2, + Aw„(Dpft - DP,)

(5.15)

where £>F, = £,- wyrDp;-r.

2.6

Aggregation and Consumer Demand

Issues associated with the aggregation in consumer demand are considered as the most important theoretical as well as empirical problem by researchers working in the consumer demand area (eg, see Barnett, 1979a, 1979b, 1981; Blundell et al, 1993; Buse, 1992; Chavas, 1993; Heineke, 1993; Lewbel, 1996; Malinvaud, 1993; Selvanathan, 1995; Slesnik, 1998; and Theil, 1971). The term aggregation has two meanings in consumer demand analysis. One refers to aggregation over commodities and the other is the aggregation over consumers.

64

International Consumption Comparisons

Aggregation over commodities

The aggregation over commodities can be described as follows: Consider the situation where a consumer derives utility from the purchase of n commodities. In this situation the utility maximization problem will result in n basic demand equations; one for each commodity. However, in practice, it may not be possible to analyse the demand for each good for reasons such as limitations on data availability, the difficulties in estimating a large demand system etc. To overcome this problem it is essential to group the n commodities into a smaller number of groups, such as food, clothing, housing etc. This is termed 'aggregation over commodities'. We can show that the aggregate demand equation for a group reflects the basic properties of the individual demand equations. Aggregation over consumers

Now we consider aggregation over consumers. With the introduction of flexible functional forms such as translog and almost ideal demand systems (e.g. Deaton and Muellbauer, 1980b; Christensen, Jorgenson and Lau, 1973; Diewert, 1974), the differential demand systems came under severe criticism. One of the criticisms is based on the aggregation of these systems over consumers. As the differential demand equations we discussed previously are derived from the utility-maximizing theory of a single consumer, they are micro in nature. Usually since data are obtainable in some aggregate form (e.g. per capita), we estimate the aggregate (or macro) form of the micro demand system. The critics argue that the theoretical properties of the micro system (such as demand homogeneity and Slutsky symmetry) will not carry over to the macro system. Sonnenschein (1973) concluded that with respect to market demand functions, there is little left of demand theory beyond homogeneity. In a similar vein,

Chapter 2 Consumer Demand Models

65

Shafer and Sonnenschein (1982) consider the conditions under which a market demand function has the same characteristics as a demand function for an individual consumer. They conclude that the required conditions are strong. These conclusions are pessimistic indeed. The first response to these criticisms was offered by Barnett (1979a, 1979b, 1981). More recently Mountain (1988) and Selvanathan (1991) provided additional response. These authors use a completely different approach to tackle the problem, an approach which uses statistical tools of analysis (Theil, 1971). This yields much more encouraging results about the properties of the market demand function. Theil (1971) aggregates differential demand equations in relative prices under fairly strong assumptions about the macro parameters and variables. Barnett (1979a, 1979b) relaxes these assumptions but works with absolute (undeflated) prices. Selvanathan (1991) extended Theil's work under the weaker assumptions of Barnett and derived macro demand equations in relative prices. The results show that the properties of the macrocoefficients are analogous to those of the microcoefficients.

References Baccouche, R., and F. Laisney (1991). 'Describing the Separability Properties of Empirical Demand Systems,' Journal of Applied Econometrics 6: 181206. Barnett, W.A. (1979a). 'Theoretical Foundations for the Rotterdam Model,' The Review of Economic Studies 46: 109-130. Barnett, W.A. (1979b). 'The Joint Allocation of Leisure and Goods Expenditure,' Econometrica 47(3): 539-563.

66

International Consumption Comparisons

Barnett, W.A. (1981). Consumer Demand and Labour Supply. Amsterdam: North-Holland Publishing Company. Barten, A.P. (1964). 'Consumer Demand Functions Under Conditions of Almost Additive Preferences,' Econometrica 32: 1-38. Barten, A.P., and S.J. Turnovsky (1966). 'Some Aspects of the Aggregation Problem for Composite Demand Equations,' International Economic Review 7:231-259. Blundell, R., P.Pashardes and G. Weber (1993). 'What do we Learn About Consumer Demand Pattern from Micro Data,' American Economic Review 83: 570-597. Buse, A. (1992). 'Aggregation, Distribution and Dynamics in the Linear and Quadratic Expenditure Systems,' Review of Economics and Statistics 74: 45-53. Cassel, G. (1932) The Theory of Social Economy. Revised Edition. Translated from the 5th German Edition by S.L. Barrow. New York: Harcourt, Brace. Chavas, J.P. (1993). 'On Aggregation and its Implication for Aggregate Behaviour,' Ricerche Economiche 47': 201-214. Christensen, L.R., D.W. Jorgenson and L.J. Lau (1973). 'Transcendental Logarithmic Production Frontiers,' Review of Economics and Statistics 55: 28-45. Christensen, L.R., D.W. Jorgenson and L.J. Lau (1975). 'Transcendental Logarithmic Utility Functions,' American Economic Review 65: 367-383. Clements, K.W. and S. Selvanathan (1991). 'The Economic Determinants of Alcohol Consumption,' Australian Journal of Agricultural Economics 35: 209-231. Clements, K.W., E.A. Selvanathan and S. Selvanathan (1995). 'The Economic Theory of the Consumer,' Chapter 1 in E.A. Selvanathan and K.W. Clements (eds). Recent Developments in Applied Demand Analysis:

67

Chapter 2 Consumer Demand Models

Alcohol, Advertising and Global Consumption. Berlin: Springer Verlag, pp. 1-72. Deaton, A.S. (1975). Models and Projections of Demand in Post-War Britain. London: Chapman and Hall. Deaton, A.S., and J. Muellbauer (1980a). Economics and Consumer

Behaviour.

Cambridge: Cambridge University Press. Deaton, A.S., and J. Muellbauer (1980b). 'An Almost Ideal Demand System,' American Economic Review 70: 312-326. Diewert, W.E. (1974). 'The Application of Duality Theory,' in M. Intriligator and D.A Kendric (eds). Frontiers of Quantitative Economics,

Vol.2.

Amsterdam: North Holland. Driscoll, P.J., and A.M. McGuirk (1992). 'A Class of Separability Flexible Functional Forms,' Journal of Agricultural Economics 10: 13-22. Edgerton, D.L (1993). 'On the Estimation of Separable Demand Models,' Journal of Agricultural and Resources Economics 18: 141-146. Goldman, S.M., and H. Uzawa (1964). 'A Note on Separability in Demand Analysis,' Econometrica 32: 387-398. Gorman, W.M. (1959). 'Separable Utility and Aggregation,' Econometrica 27: 469-481. Gorman, W.M. (1968). 'Conditions for Additive Separability,' Econometrica 36: 605-609. Heineke, J.M. (1993). 'Exact Aggregation of Consumer Demand Systems,' Ricerche Economiche 47: 215-232. Houthakker, H.S. (1960). 'Additive Preferences,' Econometrica 28: 244-257. Keller, W J . (1984). 'Some Simple but Flexible Differential Consumer Demand Systems,' Economics Letters 16: 77-82. Keller, W.J., and J. van Driel (1985). Differential Consumer Demand Systems,' European Economic Review 27: 375-390.

68

International Consumption Comparisons

Klein, L.R., and H. Rubin (1948). 'A Constant-Utility Index of the Cost of Living,' The Review of Economic Studies 15: 84-87. Leontief, W.W. (1947). 'Introduction to a Theory of the Internal Structure of Functional Relationships,' Econometrica 15: 361-373. Lewbel, A. (1996). 'Aggregation without Separabilty: A Generalized Composite Commodity Theorem,' American Economic Review 86(3): 524-543. Lluch, C, and A.A. Powell (1975). 'International Comparisons of Expenditure Patterns,' European Economic Review 5: 275-303. Malinvaud, E. (1993). 'A Framework of Aggregation Theories,' Ricerche Economiche 47: 107-35. Moschini, G. (1992). 'A Non-nested Test of Separability for Flexible Functional Forms,' Review of Economics and Statistics 14: 365-369. Moschini, G., D. Moro and R.D. Green (1994). 'Maintaining and Testing Separability in Demand Systems,' American Journal of Agriculural Economics 76: 61-73. Mountain, D.C. (1988). "The Rotterdam Model: An Approximation in Variable Space,' Econometrica 56(2): 477-484. Neves, P. (1987) 'Analysis of Consumer Demand in Portugal, 1958-1981,' Memoire de Maitrise en Sciences Economiques, Universite Catholique de Louvain, Louvain-la-Neuve. Pearce, I.F. (1961). 'An Exact Method of Consumer Demand Analysis,' Econometrica 29: 499-516. Pearce, I.F. (1964). A Contribution to Demand Analysis. Oxford: Clarendon Press. Roy, R. (1942). De I' utilite. Paris: Hermann et Cie. Selvanathan, E.A. (1985). 'An Even Simpler Differential Demand System,' Economics Letters 19: 343-347.

Chapter 2 Consumer Demand Models

69

Selvanathan, E.A. (1987). Explorations in Consumer Demand. Ph.D. Thesis, Murdoch University. Selvanathan, E.A. (1991). 'Further Results on Aggregation of Differential Demand System,' The Review of Economic Studies 58, 799-805. Selvanathan E.A. (1995). 'Aggregation and Consumer Demand,' in E.A. Selvanathan and K.W. Clements (eds.). Recent Developments in Applied Demand Analysis: Alcohol, Advertising and Global Consumption. Spriger-Verlag, pp 359-90. Selvanathan, E.A., and K.W. Clements (1995) Recent Developments in Applied Demand Analysis: Alcohol, Advertising and Global Consumption. Berlin: Springer Verlag. Shafer, W., and H. Sonnenschein (1982). 'Market Demand and Excess C Demand Functions,' in K.J. Arrow and M.D. fntriligator (eds.). Handbook of Mathematical Economics, Vol.n. Amsterdam: North-Holland Publishing Company. Slesnik, D.T. (1998). 'Are our Data Relevant to the Theory? The Case of Aggregate Consumption,' Journal of Business and Economic Statistics 16: 52-61. Sonnenschein, H. (1973). 'The Utility Hypothesis and Market Demand Theory,' Western Economic Journal 11: 404-410. Sono, M. (1961). 'The Effect of Price Changes on the Demand and Supply of Separable Goods,' International Economic Review 2: 239-271. Stoker, T.M. (1993). 'Empirical Approaches to the Problem of Aggregation Over Individuals,' Journal of Economic Literature 31: 1827-1874. Stone, R. (1954a). The Measurement of Consumers' Expenditure and Behaviour in the United Kingdom, 1920-1938. Vol. 1, Cambridge: Cambridge University Press.

70

International Consumption Comparisons

Stone, R. (1954b). 'Linear Expenditure Systems and Demand Analysis: An Application to the Pattern of British Demand,' Economic Journal 64: 511527. Strotz, R.H. (1957). 'The Empirical Implications of a Utility Tree,' Econometrica 25: 268-280. Theil, H. (1965). 'The Information Approach to Demand Analysis,' Econometrica 33: 67-87. Theil, H. (1980). The System-wide Approach to Microeconomics. Chicago: The University of Chicago Press. Theil, H., and K.W. Clements (1987). Applied Demand Analysis: Results from System-Wide Approaches. Cambridge, Mass.: Ballinger Publishing. Working, H. (1943). 'Statistical Laws of Family Expenditure,' Journal of the American Statistical Association 38: 43-56.

CHAPTER 3

Data Analysis: OECD Countries S. Selvanathan &E^4. Selvanathan

In this chapter, we provide a preliminary data analysis of the consumption patterns in the OECD countries. In Section 3.1, we present the details of the data source and its characteristics. In the following Section, we present a summary of the data in the form of Divisia indices. In Section 3.3, we verify one of the wellknown empirical regularities in consumption economics, the Engel's law, for the OECD data. Section 3.4 presents some preliminary estimates of income and price elasticities based on a double-log demand system. In Section 3.5, we derive some preliminary estimates of the income flexibility. In the last two sections, we verify the famous Frisch's (1959) conjecture and.the assumption of preference independence. The results presented in this and the next chapter are obtained using the Demand Analysis Package, 2000 (DAP2000). A shorter version of the User's Guide to DAP2000 by Yang et al (2000) is presented in the Appendix to this book.

3.1 Data Source The basic data, consisting of annual consumption expenditures (in current and constant prices) and the population for the 23 OECD countries considered in this book are compiled from the Yearbook of National Account Statistics (United

International Consumption Comparisons

72

Nations: New York, various issues); National Accounts of OECD Countries (OECD: Paris, various issues) and International Financial Statistics Yearbook (various issues). Even though currently there are 30 OECD member countries, 6 of them have not been included as they have only recently joined the OECD (Mexico, 1994; the Czech Republic, 1995; Hungary, 1996; Poland, 1996; Korea, 1996; and the Slovak Republic, 2000) and, another country, Turkey, is not included due to data unavailability. Two of the 6 new OECD member countries, Korea and Mexico are included with the less-developed (LD) countries discussed in Chapter 4. Consumption data prior to 1981 for 18 of the 23 countries considered in this book were first considered in a previous study by Selvanathan (1993) and also reported in Chen (2001). For most OECD countries, goods and services are classified into 9 commodity groups, which are listed in Table 3.1. Table 3.1 Details of the commodity groups Commodity 1. 2. 3. 4. 5. 6. 7. 8. 9.

Food Clothing Housing Durables Medical Transport Recreation Education Miscellaneous

Description Food, beverages and tobacco Clothing and footware Gross rent, fuel and power Furniture, furnishings and household equipment Medical care Transport and communications Recreation, entertainment and cultural services Education and research Miscellaneous goods and services

Table 3.2 summarizes the general characteristics of the database. Column 1 of the table lists the 23 OECD countries considered in this study. Column 2 gives the local currency unit of each country, column 3 gives the sample period for

Chapter 3 Data Analysis: OECD Countries

73

Table 3.2 Characteristics of the OECD database Country

d)

Currency

Sample period

Sample size

Number of commodities

Comments (6)

1. 2.

Australia

(2) Dollars (Aus)

(3) 1960-1996

(4) 37

(5) 9

Austria

Schillings

1964-1996

33

9

3.

Belgium

Francs

1960-1996

37

8

4.

Canada

Dollars (Can)

1960-1995

36

9

5.

Denmark

Kroner

1966-1995

30

9

6.

Finland

Markkaa

1960-1996

37

8

7.

France

Francs

1964-1996

33

9

8.

Germany

Deutsche Mark

1961-1994

34

8

9.

Greece

Education is included in recreation.

Education is included in recreation.

Education is included in recreation.

Drachmae

1961-1995

35

9

10. Iceland

Kronur

1977-1996

20

9

11. Ireland

Irish Pounds

1973-1996

24

9

12. Italy

Lire

1964-1996

33

9

13. Japan

Yen

1970-1996

27

8

Education is included in recreation.

1970-1991

22

8

Education is included in recreation.

1952-1996

45

8

1983-1995

13

8

14. Luxembourg Francs 15. Netherlands

Guilders

16. New Zealand Dollars (NZ)

Education is included in recreation.

17. Norway

Kroner

1964-1996

33

9

18. Portugal

Escudos

1986-1995

10

8

Education is included in recreation.

19. Spain

Pesetas

1964-1996

33

8

Education is included in recreation.

20. Sweden

Kroner

1963-1996

34

9

21. Switzerland

Francs

1961-1994

34

8

22. UK

Pounds

1961-1996

36

8

23. USA

Dollars

1961-1996

36

9

Education is included in recreation.

International Consumption Comparisons

74

each country and column 4 presents the sample size. The number of commodity groups considered for each country is given in column 5 with some comments in column 6.

3.2

Summary Measures

Let there be n commodities. Let p^ be the price and qit be the per capita quantity consumed of commodity i and Mt be the total expenditure on the n commodities during period t. Therefore, the total expenditure Mt =X"=1p(V^(.,.The proportion of total expenditure devoted to commodity i, called the budget share of i, is

wit

=

^ - , M,

t=l, ...,T,

(2.1)

where T is the sample size. Table 3.3 presents the budget shares at sample means for each commodity, _ wt

=

1T — Xw,-f. T t=\

i=l, ...,«,

(2.2)

for the 23 OECD countries. For each commodity, the last two rows of the table present the mean budget share of each commodity group averaged over the 23 countries, wt = (1 / 23) Y,Hi w,•, and the corresponding standard deviation. As can be seen from the food column, among the OECD countries, on average, the

Chapter 3 Data Analysis: OECD Countries

75

Table 3.3

Miscellaneous

Education

Recreation

Transport

Medical

Durables

Housing

Country

Food

Clothing

Budget shares of 9 commodities in 23 OECD countries (Means x 100)

(1) Australia

(2)

(3)

(4)

(5)

(6)

(7)

(8)

(9)

(10)

1.

25.47

7.79

17.71

7.62

6.43

14.59

6.57

1.32

12.49

0.40

16.60

2.

Austria

25.05

10.53

14.55

8.40

3.88

14.30

6.28

3. 4.

Belgium

25.65

7.54

16.76

12.60

8.49

11.48

5.02

Canada

19.95

7.23

20.80

9.23

4.09

14.90

6.93

2.64

5.

Denmark

25.42

6.33

23.65

7.90

2.03

15.68

8.07

1.27

6.

Finland

29.85

6.72

18.56

6.85

3.30

15.11

8.18

7.

France

22.93

7.39

16.66

9.22

10.06

13.95

6.39

8.

Germany

27.00

9.57

18.24

10.57

3.02

14.31

9.25

9.

Greece

41.18

9.86

12.86

8.15

3.47

11.06

3.97

10.

Iceland

25.19

8.83

18.00

10.26

1.67

15.98

8.58

1.15 0.75

11.

Ireland

38.93

6.98

13.09

6.87

2.94

12.92

7.25

2.98

8.04

12.

Italy

30.14

9.57

13.94

7.81

4.84

11.31

7.40

0.56

14.44

13. Japan

23.23

7.05

18.47

6.09

9.68

10.17

10.43

14.86

14.

Luxembourg

23.85

7.49

19.07

9.81

6.75

15.34

3.82

13.88

15.

Netherlands

26.04

10.94

14.33

10.09

9.29

9.33

8.09

11.89

16.

New Zealand

18.42

5.25

18.49

11.32

6.04

15.80

8.73

17.

Norway

27.27

8.71

18.32

7.96

3.09

14.63

8.27

18. Portugal

29.90

9.20

9.35

8.07

4.79

29.87

9.40

13.86

7.64

4.36

15.58 12.27

6.78

19. Spain Sweden

25.52

7.65

24.78

6.78

2.82

15.10

9.28

21.

Switzerland

30.43

5.85

18.85

6.74

7.90

11.32

9.66

22.

UK

24.43

7.69

18.30

7.28

1.13

14.69

23.

USA

15.80

7.17

19.12

6.72

12.18

27.08

8.07

17.21

8.51

5.64

1.49

3.48

1.68

Mean

14.24 9.65 11.43

0.39

13.01 8.05 8.29 10.73

15.94 0.52

11.24 16.32

6.55

20.

Standard deviation

12.47

16.04 0.12

7.95

8.42

1.21

16.84

15.38

6.86

1.97

14.80

5.00

13.63

7.45

1.11

12.44

3.02

2.01

1.69

0.88

3.00

9.24

International Consumption Comparisons

76

American consumers allocate only about 16 percent of their income on food while the Greek consumers allocate about 41 percent of their income on food. On average, the OECD consumers allocate about one-fourth of their income on food. The remaining income is spent on clothing (8 percent), housing (17 percent), durables (9 percent), medical care (5 percent), transport (14 percent) and recreation and education (combined 9 percent). The standard deviations presented in the last row of the table reveal that there is more variation in the budget shares for food, housing and medical care across the OECD countries. We define price and quantity log-changes as Dpit

=

log^it-logpit.i

(2.3)

Dqit

=

logfjrit-logcjit.i,

(2.4)

and

respectively, so that when multiplied by 100, these log-changes can be interpreted as percentage growth rates from year t-1 to t. Here and elsewhere log refers to the natural logarithm. Columns 2-10 of Table 3.4 present the mean log-changes in per capita consumption of each commodity Dqt

=

-i.Dqu, T t=\

i=l, ...,n,

(2.5)

for the 23 countries. The last row presents the mean quantity log-changes averaged over all countries. As can be seen, the average growth in per capita consumption of food varies between .3 percent (USA) per annum and 2.4

11

Chapter 3 Data Analysis: OECD Countries Table 3.4 Per capita quantity consumed of 9 commodities in 23 OECD countries

(D

Miscellaneous

Education

Recreation

Transport

Medical

Durables

Housing

Clothing

Country

Food

(Mean log-changes x 100)

(2)

(3)

(4)

(5)

(6)

(7)

(8)

0)

(10)

1.

Australia

0.78

0.24

3.14

3.47

2.01

2.70

3.45

4.64

3.21

2.

Austria

1.13

2.94

2.99

3.99

3.74

0.87

Belgium

1.07

1.81 2.01

3.02

3.

2.43

2.77

3.80

3.37

3.66

4.

Canada

0.36

1.71

2.90

2.45

0.26

2.90

5.12

4.05

5.

Denmark

0.86

0.99

2.19

-0.25

2.34

2.33

3.41

6.40

6.

Finland

1.37

1.05

3.39

2.80

3.31

3.82

4.00

7.

France

1.03

0.34

3.66

1.65

5.57

3.14

4.03

8.

Germany

1.56

1.95

2.94

2.82

2.82

3.97

2.87

9.

Greece

2.27

1.76

4.05

2.99

5.31

6.12

5.66

-0.69

4.28

10.

Iceland

1.09

0.00

1.33

0.62

2.63

1.97

3.23

4.63

2.84

11.

Ireland

0.97

1.38

1.92

1.43

0.30

1.94

4.09

2.05

2.89

12.

Italy

1.41

1.78

2.39

2.83

5.00

4.18

3.51

2.61

13.

Japan

0.74

0.81

4.08

2.54

4.31

4.70

4.37

3.16

14.

Luxembourg

0.90

0.73

2.83

4.36

4.02

5.75

3.98

2.17

15.

Netherlands

1.71

1.87

2.31

3.35

3.57

4.91

3.98

3.31

16.

New Zealand

0.42

-1.06

0.88

3.07

2.92

3.41

2.35

17.

Norway

1.08

1.23

2.58

2.28

5.13

2.95

4.68

18.

Portugal

2.35

1.42

7.74

3.69

3.09

5.49

7.00

19.

Spain

1.23

1.55

2.12

1.74

6.08

5.78

3.27

20.

Sweden

0.53

0.97

1.33

0.44

3.34

1.97

2.59

21.

Switzerland

0.97

-0.26

1.56

-0.08

2.75

2.19

1.84

2.01

22.

UK

0.38

2.97

1.60

1.98

3.38

3.52

3.73

2.52

23.

USA

0.31

2.55

2.01

2.31

3.51

2.50

4.83

2.61

1.93

1.07

1.21

2.71

2.27

3.41

3.63

3.89

2.64

2.59

Mean

1.63 2.94 2.15 1.65 3.67

2.63

1.94 3.17

3.39

0.65 0.74

3.04 2.97 4.01

1.19

0.07

International Consumption Comparisons

78

percent per annum (Portugal) with an average of 1.1 percent per annum among the OECD countries. The average OECD annual growth in consumption of clothing is 1.2 percent, housing 2.7 percent, durables 2.3 percent, medical care 3.4 percent, transport 3.6 percent, recreation 3.9 percent and education 2.6 percent. Columns 2-10 of Table 3.5 present the annual mean log-changes in prices of each commodity Dp,

=

^i-DPu.

i=l, ...,«,

(2.6)

for the 23 countries. The last row of the table presents the mean price logchanges averaged over all countries. As can be seen, in the OECD countries, the average growth in the price of food varies between 2.6 percent (Germany and Netherlands) to 22.4 percent (Iceland) with an average of 6.4 percent per annum among the OECD countries. The average OECD annual growth in the price of clothing is 6.3 percent, housing 7.9 percent, durables 6.1 percent, medical 7.6 percent, transport 6.8 percent, recreation 6.6 percent and education 9.7 percent. Table 3.6 presents the Divisia volume index, DQt, for the period t, DQt

=

t

witDqit,

t=l,...,T,

(2.7)

where wit= Yi(w\t + wit_i) is the arithmetic average of the budget shares of commodity i in periods t and t-1. The last row of this table gives the Divisia volume index averaged over the whole sample period for each country,

DQ =

±i.DQt1 i=i

79

Chapter 3 Data Analysis: OECD Countries Table 3.5 Prices of 9 commodities in 23 OECD countries

(D

(2)

(3)

(4)

(5)

(6)

(7)

(8)

0)

Miscellaneous

Education

Recreation

Transport

Medical

Durables

Housing

Clothing

Country

Food

(Mean log-changes x 100)

(10)

1.

Australia

6.07

5.51

6.42

3.96

6.92

5.74

7.00

6.88

6.31

2.

Austria

3.06

3.33

5.96

3.28

5.97

4.22

3.79

5.66

5.28

3.

Belgium

3.59

4.20

5.01

3.25

5.72

4.51

4.48

4.

Canada

4.88

3.54

4.76

4.29

5.58

4.19

3.70

5.81

5.53

5.

Denmark

5.47

5.14

8.04

6.08 5.79

5.66

6.37

5.14

7.04

7.20

8.37

7.78

6.79

5.47

6.25

7.19

6.

Finland

5.62

5.73

7.

France

5.45

5.79

6.95 6.82

5.32

3.37

6.52 6.67

4.77

8.

Germany

2.58

2.82

4.71

2.17

4.15

3.64

4.16

9.

Greece

11.39

11.42

10.27

11.24

11.31

10.61

10.93

12.11

12.31

10.

Iceland

22.42

23.03

23.16

21.84

24.77

22.28

22.74

26.04

23.84

3.57

11.

Ireland

8.07

7.56

10.22

7.81

12.84

9.52

7.91

12.29

10.59

12.

Italy

8.05

9.83

10.62

10.03

9.44

9.13

8.55

10.67

10.10

13.

Japan

4.00

4.82

4.44

2.95

3.86

3.98

3.89

14.

Luxembourg

5.57

5.44

6.20

4.72

5.91

5.36

4.67

6.03

15.

Netherlands

2.58

2.40

5.87

2.38

6.12

4.00

4.11

5.03

16.

New Zealand

6.09

5.00

9.59

4.14

8.61

2.64

5.86

17.

Norway

5.76

5.22

7.33

5.32

2.29

6.74

4.86

18.

Portugal

7.79

8.91

10.34

7.52

10.21

8.23

10.23

9.72

19.

Spain

8.30

9.22

9.37

9.20

8.05

8.80

9.69

11.60

20.

Sweden

5.84

5.04

8.13

6.48

6.30

7.02

6.00

21.

3.56

3.23

5.67

3.90

7.31

4.53

4.63 8.30

3.29

22.

Switzerland UK

6.29

7.01

7.09

3.94 5.84

23.

USA

4.36

2.89

4.60

3.34

5.96

4.26

3.08

5.67

5.33

6.43

6.29

7.90

6.12

7.57

6.76

6.59

9.67

7.81

Mean

4.32

7.64 7.07

9.01

6.75

7.22 4.91 6.91

International Consumption Comparisons

80

Tcfcle3.6 DivisiavoliiTeindces in 23 OECD countries (x 100)

I I (1)

(2)

(3)

(4)

(5)

(6)

(7)

(8)

(9)

(10)

(11)

(12)

(13)

(14)

(15)

1953

(16)

(17)

(18)

(19)

(20)

(21)

(22)

(23)

(24)

649

1954

6.95

1955

4.87

1956

7.62

1957

-1.30

1958

-222

1959

4.47

1960

597

1961

0.64

1.21 -0.75

6.99

1962

299

3.38

5.56

5.19

359

386

5.18

347

0.58

3.03

1963

5.23

3.44

0.67

289

1.35

4.99

7.78

254

a73

241

1964

280

1.60

3.77

4.38

4.33

7.59

369

420

292

232

393

1965

0.94

4.05

321

4.06

4.73

526

7.18

295

5.74

3.14

2.15

0.56

4.27

1966

297

271

2.56

311

238

393

1.81

6.47

386

1967

4.19 203

2.28

393

3.46

1.85

4.01

086

4.38

1968

4.19

5.04

2.06

1.91

0.43 295

4.04 6.20

4.64 284

5.65

9.86

4.35

3.38

4.96

301

1.52

642

1.25

295

5.74

1.02

1.84

1.44

6.16

311

1.72

4.81

1.77

1.71

1.91

1.79

4.28

4.69

272

4.73

3.57

246

286

4.13

6.92

6.93

1969

4.35 2.73

5.46

696

5.63

329

4.07 027

243

1970

£73

231

7.42

356

605

8.01

6.39

6.41

0.15

3.05

0.58

4.25 251

0.96

1971

0.72 7.18

4.07 6.37 -0.04

1.96

5.10 385

5.95

224

4.81

397

2.12

4.13

3.81 -1.81

3.69 274

237

1972

1.50

6.28

547

5.13

312

6.26

261

7.87 3.76

247

1.99

6.84

1.84

2.72

5.84

4.86

1973

6.55

360

6.04

7.66

4.64

1.81

4.99

395

1974

1.61

0.43 271

1975

210

258

0.06

270

1976

1.29

353

4.59 4.40

5.77

0.99

5.98

6.29

5.71

5.97

1.47

7.52

5.42

5.66

5.50

4.63

1.31

7.48

3.39

312

4.96

6.61

1.77

4.07 -3.34

1.36

236

066 -1.06

-0.03 2.00 -1.68

4.21

1.63

2.56

4.07

3.64 -0.62 -0.97 -1.76

2.94 206

257

349

-5.47 -1.97 305

4.96 227

3.99

1.29

242 -240 -0.48

1.17

7.11

5.18

4.29 4.67

0.90 289

239

359

5.11

3.49

370

1.76

1.07

4.41

0.43

5.00

1977

0.18 4.12

2.19

1.97

025 -1.36 251

4.08 3.49

1978

2.06 -0.38

234

2.67

0.11

1979

4.16

538

1.85

293

3.06

3.91

5.92

1.44 -1.51

317

0.13

3.31

291

4.19

383

4.99

854

6.95

259

4.01 2.76

3.08

-224

0.44 -0.92

1.16

4.70

3.00

1.35

4.60 4.19 2.49 0.60 521

296

267

1.46 -1.64

1.83

500

527

2.41

246

3.66

0.12 223

0.85

4.03

1.19

1980

2.10

214

1.70

0.75 -3.63

1.47

1.00

1.47 -2.69 3.42 -0.91 4.06

0.76

295 -0.72

2.21

-0.49 -1.19 3.10 -1.82 -1.36

1981

230

0.42

0.16

1.00 -1.31

1.44

1.71 -0.21 0.37

1982

0.03

1.09

1.90 -307

1983

0.96

4.17 -0.79

1964

271 -0.79

0.90

1.59

2.09 2.19 -1.01 0.98

1.76

296

1.72

3.98

3.38 257

6.06

0.25

0.37

0.56 -0.99 -280

-0.07

-0.65 -0.71

564 -9.06

0.21

356

0.20

-0.10

0.82

-1.12 -1.10

1.16

3.80

370

295

0.14

1.19

1.71

399

1.67 -1.63

0.50 228

1.61 -9.70 -2.57 -0.92 241

1.51

0.71

1.81

0.67 -0.55

258

3.15 -0.93

1.96

0.48 284

1.52

1985

3.82

1.44

1.32

4.46 4.19 290

1.97

1.93

3.66

4.61

265

262

1.20

320

9.20

2.84

2.42

0.89

350

3.45

1986

-0.36

0.77

1.72

375

274

296

0.45

5.88 -0.44

328

269

212

2.01

311

4.16

3.34

4.19

229

5.76

300

1987

2.24

1.98 2.65 269 -1.99 4.70 234

4.83

1.14

9.11

3.64

3.78 351

4.24

1.72

1.73 -1.89 6.47

515

4.14

1.14

4.57

1.88

1988

233

355

0.29 2.56 -270

4.29

3.96

4.27

335

0.18 0.16 -232

7.31

4.19

1.86

1.32

6.35 3.0B

1969

2.36

4.32

1.51

3.31

4.14

0.53

1990

-0.37 3.20

3.98

325

2.92 -0.77 -1.09 4.52 2.55

5.20 -0.17

265

3.78 £75

1.93

0.24 -0.69 0.63

1.99 -0.82 0.67 -0.17

372

277

1.32 235 -254

7.59

3.12

4.16

3.25 -0.92 -O.10 -124

206

525

1.11 -0.05 2.43

215

4.08 3.90

4.47

1.03 -0.11

1991

1.56

2.27

230 -7.51

1.90 -3.85

0.72

1992

2.52

0.88

1.32 -0.03

1.17 -1.74

0.91 -0.14

1993

2.75

0.66 -1.93

1994

4.31 2.68

1995

294 -6.39

1996

0.81

5.53

3.02

Mean

226

235

245

2.97

0.37 -1.28

283

1.59

0.98

5.79 2.48 -1.56 0.73

024

0.65

221

3.79 239 -3.06

1.47

4.07

2.41

0.83

1.68

1.86

0.20

1.24

3.65

1.97 -213 -1.29 -1.66

1.87

0.71

1.X -218 -0.41 -1.48 0.09 -4.12 247 2.72

0.77

0.24

3.82

1.95 -0.56 -201 -204 -1.79 2.52

1.84

123

260

5.94

1.83

0.95 -Q44

1.73 -1.36

5.10

1.21

1.69

1.60 4.85

386

202

1.54

0.92 -0.69 230

214

0.63

0.44

0.70

353

1.01

0.65

4.93

3.84

1.49

1.57

1.24

3.02 2.35

1.35

1.74

0.55

1.26

1.55

5.58

6.01

0.81

248

251

4.13

203

0.83

3.06

214

1.60

1.72

264

297

2.38 3.71

267

1.19

203

222

1.49 -4.39 252

371 -0.90 221

1.62

270

252

260

2.00 4.22

1.49

365 -1.46

3.28

283

283

1.57

0.05

0.42 -1.68 -1.59

1.42

81

Chapter 3 Data Analysis: OECD Countries

As can be seen from the last row of the table, overall consumption growth in the OECD countries varies between 1.2 percent (Sweden) and 3.7 percent (Portugal) with an overall average of 2.3 percent per annum across all OECD countries. Table 3.7 presents the Divisia price index, DPt, for the period t,

DPt

=

£ witDpit,

t=l,...,T.

(2.8)

The last row of this table gives the Divisia price index averaged over the whole sample period for each country, 1 T

—

DP

=

-I.

DR.

Tt=i

As can be seen from the last row of Table 3.7, the overall annual price growth in the OECD countries varies between 3.4 percent (Germany) and 22.8 percent (Iceland) with an overall average of 6.9 percent per annum among all OECD countries. The Divisia quantity index (DQt) and the Divisia price index (DPt) are first-order moments. The second-order moments, the Divisia quantity and price variances that correspond to the Divisia volume and price indices are

Kt

=

iwit[Dqit-DQt]2, i=i

t=l, ...,T,

(2.9)

82

International Consumption Comparisons Table a 7 Divisia price indices in 23 OECO countries (Means x 100)

(1)

(2)

(3)

(4)

(5)

(6)

(7)

(8)

(9)

(10)

(11)

(12)

(13)

(14)

(15)

1953 1954

(16)

(17)

(18)

(19)

(20)

(21)

(22)

(23)

(24)

1.41

-0.65 3.59

1955

1.23

1956

0.87

1957

5.57

1958

1.36

1959

Q67

1960

1.25

1961

0.42

280

0.68

1.60

1962

1.77

1.01 -1.27

3.07

314

1.25

1.59

4.91

4.38

1963

0.48

3.66

3.96

5.21

293

3.14

207

3.49

1.75

1.43

1964

312

4.07

1.28

7.95

236

209

615

3.25

4.05

3.50

1.46

1965

3.30

4.39

4.47

1.95

343

264

308

4.36

3.51

313

4.16

9.18

5.11

391

5.10

1.64

1966

296

250

4.08

331

270

317

371

3.39

282

5.61

3.34

695

6.15 4.65

3.82

273

1967

3.48

3.91

246

3.48

603

4.79

3.10

1.73

1.85

300

3.00

4.31

5.61

4.26 4.36 254

248

1968

3.18

248

273

3.99

663

9.66 4.94

1.68

069

1.42

266

3.14

5.02

1.33

2.57 4.39

399

1969

3.13

3.35

3.02

3.76 4.50

1.95

685

1.95

292

282

4.66

3.42

3.34

3.32

269

4.42

1970

5.45

3.85

252

3.44

698

253

4.85

364

3.11

4.88

1971

6.46

4.65

500

246

665

6.47

537

536

289

5.33

560 4.51

1972

7.46

5.95

5.39

4.08

7.63

809

5.71

538

3.57

620

4.91

4.69

840

649

1973

887

7.02

698

S14

9.14 11.15 661

635 14.03

11.77 9.11

656

866

4.42

1974

1622 9.86 11.77 10.10 14.10 17.64 1244

659 21.24

14.40 19.01 19.34 9.41

9.59

896

1611

1975

14.32 7.83 1202 1004

9.65 15.10 10.82 593 1210

2Q61 1630 1Q91 9.70 1009

11.18

14.54 1025

635 2128

1976

11.04 655

9.37 1264

1857 1659

S74

9.07

841

a06

15.52 1024

238 1429

575

1355 1674

7.08

5.61 1205

7.80

21.54 10.10

1.09 15.19

641

7.58 1213

4.63

3.53 4.37

7.30

17.61 10.69

1.16

9.15

677

5.00

4.41

15.17 7.63

4.18 1270

S74

5.60

1.53

7.84

7.35

9.37 4.23 1281

691

7.00 10.23 11.05 866

4.14

9.51

637

5.77

3.86 5.76

4.46

813

623

7.70

720

683

4.28

7.9B 556

7.43

5.79

340

10.88 10.83 895

7.09

7.85

S22

9.37 9.63 15.50 9.84 7.74

1977

9.20

1978

878

4.08

4.05

7.17

9.08

7.31

S43

270 11.60 35.83

1979

9.91

4.07

388

829

9.77

7.64

9.95

4.37 1624 37.92 13.93 13.85 346

1980

9.24

640

608

9.59

9.85 11.01 1227

672

7.20

656

9.36

1981

9.21

7.08

7.77 10.79 11.45 10.70 11.80 578 21.29 41.42 1873 17.59 4.23

S30

5.99

1283

1342 10.81 616 1093

889

1982

1064

5.74

7.16

9.96 9.30

9.54 11.22 4.70 19.04 41.28 14.98 15.77 251 1Q16 509

1Q64

1369

602

1983

7.57

3.68 646

5.42

664

812

4.93

210 15.60 6377 1Q08 27.68

11.88 11.02 261

5.45

386

1984

7.37

5.25

3.87 611

673

7.43

11.29 723

4.82

3.93

1985

5.91

3.17 4.84

3.66

4.31

5.45

561

886

3.47 5.30

3.59

1986

836

1.69

1.53

3.81

3.26

3.10 266 -Q60 19.95 19.05 14.26 607

1987

7.70

0.98

1.57

3.96 4.62

3.55

1988

7.28

1.53

1.54

3.95

1989

623

239

3.03

4.90 4.02

1990

4.92

3.07 3.33 4.22

1991

253

290

1992

1.85

1993

603

3.87 4.38

4.94 19.72 44.14 17.31 1836

397

1380 11.76 4.09 15.62 10.40 9.51

5.47 857

300

7.73

270

1394

278 1680 27.29

7.39 11.32 254

642

251

9.B2 602

1.37 1688 27.84

7.13

224

4.09

617 1366

5.56

7.10

674

Q86

1.34

Q23 1285

658

9.09

4.64 0.47

3.80

5.62

248

3.13 -1.54 14.72 15.76 249

5.28

Q56

1.62

025 1057

7.57

5.10

1.48

4.37

386

270

5.67

Q55

270

052

650

5.93 10.08 4.98 5.85

208

5.07

4.12

4.71 1208

322 1274 21.86 4.71

642

1.87

366

1.15

650

652

652

3.13

5.72

4.54

256 17.91 15.51

1.97

610

235

357

225

5.46 4.60 11.46 636

9.3B

5.34

5.38

5.16

4.80 213

5.33

316

362 1753

282

668

250

308

314

1.97

370 11.05 625 10.07 5.58 508

3.97

3.96 270

1.11

230

3.53

242

392 14.15 4.47 258

5.47

1.90

303

1.03

273

a92

635

218

394

5.81

3.04

1.49

3.29

289

1.41

0.35

3.89

227

357 1291 4.16

1.88

4.87

1.32

211

1.10

205

680

5.40 4.93

332

321

271

1994

1.25

3.61

273

0.56

204

1.54

213

276 1Q08

1.66

274

4.55

Q78

270

233

1.12

546

4.64

285

1.26

270

233

1995

264

1.64

1.61

1.55

251

0.37

1.54

896

1.61

201

5.58 -Q45

1.43

292

236

4.17 4.63

259

281

223

1996

1.65

246

203

1.27

1.82

221

1.33

4.22 -Q18

1.27

1.26

3.34

1.20

266

206

Maan

5.98 4.22

4.43

6.36

5.76

335 11.20 2275

8.91

9.28 4.12

9.31

677

4.06 698

4.51

324

4.65

639

3.46 278 1398 19.61 3.85

9.34

3.02

5.68 294

282

4.89

358 11.32

548

677

5.62

3.85

623

605

682

83

Chapter 3 Data Analysis: OECD Countries and

H

=

Iwft[Dpft-DP,]2,

t=l,...,T.

(2.10)

These two variances measure the degree to which the quantities and prices of the individual commodities change disproportionately. When all quantities and prices change proportionately, these two variances will vanish. Tables 3.8 and 3.9 present these two variances for the OECD countries over the sample period. As before, the last row of the table gives the mean variance for each country averaged over the whole sample period. A comparison of these two variances reveals that the Divisia quantity variances systematically exceed the corresponding Divisia price variances. To confirm this relationship, in Figure 3.1, we plot -JfCf against yrif fort=l,...,Tandc=l,...,23. As can be seen, most of the points lie above the 45° line indicating that, on average, -yjKf >-y/nj\ This pattern agrees well with the results of Clements (1982, 1983), Meisner (1979), Selvanathan (1987), Selvanathan (1993), Selvanathan and Selvanathan (1993), Selvanathan and Selvanathan (1994) and Theil and Suhm (1981). To measure the co-movement of prices and quantities, we define the Divisia price-quantity correlation as

Kt

—

i

>

t=l, ...,T,

(2.11)

VKJl7 where Tt = £"=1w;,[£>p,r -DPt][Dqit -DQt]

is the Divisia price-quantity

International Consumption Comparisons

84

(16)

N z (17)

(18)

(19)

(20)

(21)

(22)

*: D (23)

USA

(15)

Switzerland

(14)

Sweden

(13)

Spain

(12)

Portugal

(11)

Norway

(10)

Netherlands

(?)

Luxembourg

(8)

Italy

(7)

Japan

(6)

Ireland

(5)

Iceland

Finland

(4)

Greece

Denmark

(3)

France

Canada

(2)

Germany

Belgium

1 (1953 >

Austria

Year

Australia

Table 3.8 Divisia quantity variances in 23 OECD countries ( x 10000)

(24)

2072

1954

19.70

1955

20.17

1956

1841

1957

11.32

1958

2273

1959

11.72 14.11

1960

507

1961

4.55

14.X 85.18

14.21

1962

23.47

2.43 34.20

1281

814 14.32

614

581

7.83 642

1963

31.67

4.86 55.34

1600

510 7.43

387

1.55

9.33 4.08

1964

4.73

10.90 4.37

37.78

555 2224

3225

596

7.37 347

1965

1.63 8.32 4.80 5.32

4214

5.20 7.77 7.91

4.91

19.56

4.48

1680 622 277

501

1966

4.95

1662

205

41.71 622 299

1.29 4.51

1967

5.67 8.53 280 7.50 5.38 4.07 1.19 4.67 6.07 2.63 4.16 5.01 4.35 7.23 332 350 14.48

1968

8.05 3.04

578

1057

15.35

672

4.55 2040

0.69

13.18

3.44

10.87 5.49 4.63 340 1207 25.73 4.99 1610 11.12

7.77

5.92 a i 8

664 286

685

508

1653 11.71

149 303

7.26

2264

2322

9.03 366 200

2.57 14.65 206 1602

687 a31 566

7.11 5003

5.81

21.42

2620

379 376

1971

3.88 25.30 7.27 25.09 13.92 1221 624

274 1056

3.99 553 1390

1.05

9.52

1972

27.91 24.11

1973

64.48 6.83 30.42 22.19 13.36 2620 7.47 698 5022

1974

5.94 10.86 15.91 5.30 33.63 14.97 11.89 9.47 1559

1975 1976

5.71

605

9.17 1289

8.09 4.01 10.92 2252 9.86 3.90 14.49

7.34 1539 214

7.76

2564 346

1.24 1070 7.12

180.26

1Q91 392

693

17.25 558 41.22 7.40 8.90

541

878 1614 7.89 11.34 1230

31.99 9.54 2071 11.50 3208 43.05 3.16 10.35 19.75 099

666

4.44 254 17.26

1359

275 4.86 4.19 215 371

5.91 2210 11.86 4.59

7.78 659

1296

381

500 321

1978

7.70 2205 3.61

4.87 7.56 659 662

1.72 1253

57.15 15.51

1.18 11.85 1669 363

2567

1.84

534

1979

3.56

7.27 993

2.95 3.60 532 299

222 1062

29.96 14.84

592 11.51

1960

3.98 4.61 16.34 4.46 22.18 4.44 4.93 1282 4649

1023 3.60 308 15.22

1981

2.11

4022 37.63 676

1982

8.76 2.65

879

3.45 2383

1983

6.52 7.53 3.84 350 2046 5.93 7.84

4.13 2341

1984

4.51

595

5.08 7.99 10.86 3.39 868

233 1Q70

1985

4.49

1.52

1.15

1986

5.07 4.67 243

9.17 a60 4.11 4.17 21.78

5.78 23.32 382 10.14

819

11.19 248 3.67 656

9.94 15.27 4.02 250 1586 9.26 0.48 1.93

10.65 551

7.14

5.40 4.31 2.36 377 1279 4.38 244 39.23 7.00

1988

4.71

4.52 335

4.63 630 7.32

520

380

697

1.77 212 283

500

665

317

698 660 1210

1232

283

4.38 258 311

24.01 70.29 4.28 5.97 1Q36 4.31 65.03 1009 667 433 4.98 1.03

7.55

24.70 392 3.32 1680 17.94 3.79

588 1241 4.14 307 692

349

1.75 5208

63.75 11.18 508

558 11.85 302 1353

1.78 4.10

262

3645

344

666

1.38

17.98 346

1070

7.89 1526

4.05

1.26 287 1593 543 1.19 224 274 1.24

049 0.61

3553

a 91

1.82 626

517 1201

876

578 4.24 119.45 19.10 4.20 1Q83 1241 3.34 7.20

1987

7.14

9.62 604

ace

10.20 1260 7.22

1977

7.36 857 4.37 654 2536

1.80 4.90

1.08 374

5.63 536 1547 21.71

661 14.55 834 9.51 5.48 3.65 1381

11.67 3.54 20.52 4.19 17.39 30.67 7.41

1.64

1.45 312 4.77

1970

1969

281

0.61

4.42 7.01 4.94

7.66 384 293

1.26 1Q57 353

30.17

9.73 31.43 4.75 5.37 17.12 674 4.60 34.97 1.10 15359 20.38 511 11.04 7.17 4.64 2001

1395 1596 14.81 0.97 677 4.58 3506 221.85 7.94 516 1.64 23.84 1.77

1969

5.87 8.99 3.44 3.00 604 282 4.87 214 7.67 11276 1017 4.20 11.22 1347

1990

3.11

1.93 3.83 4.26 1.83 10.16 5.08 4.92 588 4.35

647

5.38 843

267

544

673

4.70 632

1.46 4.11 297

641

1248

10.73 4.20 571

371

504

4.81

5.14

9.84 317 11.67

aso

9.17 263

4.29 7.62 309 14.80

19.23 357

1.85 4.45

1993

1.82 3.77 6.57

1994

1.38 5.62 290 316 49.34 4.24 249

1995

1.X

6.77

1996

5.01

8.25 17.87

Mean

8.74 876 7.23 11.55 11.63 13.06 521 7.40 1611

1.05 10.41 211 3073

1.73 278 14.38 5.07 10.66 11.22

1.05 215

19.72

854

633

1.34

1.84

9.41

541 23.91 241

1991 1992

1.05

1.16

19.55 ia93 553 1024 11.62 323 9.82 3.01 264 4.51 lass 359

4.71 4.59

1.97

4.15 1295 14.45

7.31 266

276

547

1216 249 1097 4.91

243

869

1.04 9.44

1.93 1Q65

5.19

235 11.84 883

605

362 4.22

1.55

588

1.83 1307

7.55

1.06

1.95 375 a61

4.15 4.97

13.99 14.59 233

572

0.92 1Q09

546

0.65

576

1.99

7.61

359

1.71

215 672

9.47 9.37

13.12 2307 601 11.89

Q53

4289 17.94 513 9.98 10.84 1Q12 1324

17.75

ax

17.34 30.63 9.81 617 324 582 534

Chapter 3 Data Analysis: OECD Countries

85

Ireland

Italy

(9) (10)

(")

(12)

(13

1953

(14) (16)

N

(16) (17) 344

1954

11.84

1955

271

1953

902

1957

326

1953

7.16

1953

1.02

1960

845

(18) (19)

(20)

Switzerland

Iceland


Sweden

Greece

(7)

Spain

Germany

(6)

Portugal

France

(5>

Norway

Finland

(4)

Netherlands

Denmark

(3)

Luxembourg

Canada

(2)

Japan

Belgium

(1)

Austria

Yea-

Australia

Table 3L9 Ovisia price variances in 23 OBCD oartries ( x 1000(9

<

(21) (22)

(23) (24)

1961

563

iaoo 082

1.30

1962

945

551 3606

212

1.69 560

1.31

1.23

079 078

1933

871

933 41.66

291

1.82 291

1.70

1.49

7.22 026

1954

272

1.73 1.64

1329

121 1.06

674

396 Q55

1.66 047

1935

246 237

1515 1.80

aio

1.66

1.53 4.00

1.16

346

1.72

7.99

Q93 315

1.96 Q37

1966

126 220

653 296

316

1.43

240 293

Q72

4.11

1.89

1.87

1.53 1.54

1.42 1.91

1967

131

4.07

Q99 319 854

398

323

328 243

1.53

900

318

590

207 497

1.10 227

1966

221

4.87

1.33 1.69 4.45

3255

365

7.79 4.33

1.90

12887

080

866

1.57 413

1.83 1.10

1939

629

1.91

Q49 210 1.27

045

1.45

266 3C0

051

1.69

1.57

545

429 291

Q56 122

491 393 234 17684

1.09

090 583

1.12

4.37

227

879

1.82 246

1.59 055

293 336 562

437

Q71

265 4.15

217 349 293

7.04

1.41

ace an

4.75 224

090 1.56

1.07

1970

541 261

1971

4.91

536

1972

27.37

305

397 241 4.18

Q65

1.28

1.00 1.10

1.96 4.59 077

898

054

1973

1909 1499

1066 2523 31.80

876

222 23259 2273

503 31.41 7.91

351

161.36

1974

9 8 7 1Q3B

874 4.02 1274

1983

596

4.57 1556

1655

1346 31.48 315

9.73

368

7.51

2583 1.90

480 445

1975

63 355

920 395 1.51

27.38

1.07

067 550

S78

720 887 382

807

822

4.58

282 252

897 272

1.44 7.19

362 4.71

815 340

476 1.44

533 11806 568

5380 31.69

1976

4.76

520

400 a 93 4.06

1589

231

057 4.12

2478

7.39 342 927

394

536

839

1977

245 341

4,75 336 4.04

512

239

094 341

24.80

578 4.66 232

74.35

587

1506

1978

586

4.43

1.81 617 253

390

032

1.00 1.84 1Q20

27.89

423 7.00 336

4.70

582

270

4.63 379

383 296

1979

264 384

593 1.98 2253

1.82

224

7.52 4.62 2864

14.99

4.54 281 430

423

391

1222

7.19 852

474 478

4.23 Q15 35370 391

1930

1.54

521

11.34 257 11.08

4.17

7.40

326 503 378

11.72

994 540 11.15

4.40

338

597.00

1.95 1.54

937 1049

1961

358 653

1433 541 367

4.36

225

272 584 1Q19

2818

294 1.40 202

588

1294

1.58

392 241

1486 411

7.55 422 1.29

925

407

1982

595

1933

2 6 9 7383

4.29

Q74

1.48 1.47 1.96

226

aeo

227

1.40 7.55 1Q50

549

422 1.97 7.13

240

934

363

548 24.77 9916

527 167.56 1016 1.03

248

25396

567

31.95 Q74

1.14 1034

1.02

205 1229 2027

526

1.71 813

1.16

225

1.19 035

308 244

13641 506 Q59 8368 :36209

801 094 088

7.86 556

1934

6871

1935

505

1.43

054 051 Q42

1.57

1.85

250 467 656

5567

287 393 Q70 11533 5575

0.59

201

035 021

040 1.74

1966

Q66

4.60

11.76 280 1.53

369

332

581 706 8907

4221

1.30 089 1935

288 14.46

233

821

383 989

318 537

1987

212 059

255 089 601

362

1.27

3343 1519 1313

7.01

am

1.30

668 2031

210 66S

1.53

1.96 1.77

204 Q55

1933

284 Q63

059 Q71 1.81

214

240

44.44 893 27.96 12393

341 033 1.75

1.57 37.18

1.68 540

1.66

297 Q89

1.46 251

1939

1.71

1.55

Q74 042 227

1.70

1.41

1.79 11.59 21.66

046

1.19 072 293

067 1358

239 680

1.84

264 1.71

120 262

1.51

1990

1.3

1.75

073 Q76 353

120

1.95

029 368 648

046

1.37 1.35 Q75

1.52 1.50

322 216

1.77

11.00 1.88

827 289

1981

1.03

084

1.97 387 313

446

1.07

1.86 650 511

080

418 1.48 Q16

214 816

274 1Q43

318

44.47 094

727 093

1992

091

1.39

479 1.07 1.73

285

126

084 944 686

1.48

1.41 1.33

123 1.31

1.17 363

245

1932 261

836 1.94

1983

094

1.01

542 045 1.62

823

1.55

1.58 1050 670

1.07

354 075

083 216

1.16 4.82

383

937 337

1.67 227

1994

1.33

262

074 374 1.08

087

1.03

1.18 601 288

1.78

277 1.63

332 532

1.08 212

1.06

1.58 Q49

332 1.43

1995

211

4.96

097 098 093

994

Q48

490 053

211

295 254

370 879

1.13 1.09

Q67

1.07

200 204

1996

1.44

4.31

1.43

278

027

1.63

346

1.01 267

329

252

Q18

975

093 204

Mm

643 589

1325

1330

11.62 7.10 1633

1805

S87 543 512

872 524 415

1122 14.72

1595 4.80 2329

1Q52 269

1539 361

International Consumption Comparisons

86

1954

N

(17)

(18)

(19)

(20)

Switzerland

(16) -0.44

Spain

(15)

Sweden

(14)

Portugal

(13)

Norway

Netherlands

(11)

(12)

Luxembourg

(10)

Italy

Greece

(9)

Japan

Germany

(8)

Ireland

France

(6)

(7)

Iceland

Finland

(4)

(5)

Denmark

(3)

Canada

(2)

Belgium

(1) 1953

Austria

Year

Australia

Tablea-IO Divisia price-quantity correlations in 23 OECD countries

(21)

(22)

< ^

V)

(23) (24)

-0.89

1955

0.21

1956

-0.95

1957

0.20

1958

0.19

1959

-0.60 •0.32

1960 1961

0.10

-0.97 0.02

-0.24

1962

0.06

-0.43 -0.95

-0.09

-0.69 -0.60

-0.03

1963

-0.21

0.64 -0.97

0.33

0.74 -0.44

-0.83

-0.24 -0.52 0.18

1964

-0.87

0.28 •0.42

-0.72

-0.81 •0.25

-0.58

-0.46 -0.27 -0.64 -0.07

1965

0.35 -0.86 -0.03 -0.27

-0.55

0.42 -0.75 •0.27

0.14

-0.40

-0.06

-0.57 -0.31 -0.63 -0.X 0.05

1966

0.61

0.55 -0.32 -0.49

0.24

0.16

0.12 -0.57

-0.06

-0.26

-0.34

-0.60 -0.C9 0.13

1967

-0.32 O X -0.36 0.23

0.78

0.63

0.25 -0.74

-0.16

-0.13

-0.51

-0.09 -O.08 0.16

0.32 0.01

1968

0.05

Q25 -0.38 0.54 -0.52 0.25

0.12 -0.39

0.00

0.21

-0.70

-0.79 -0.X

0.39 -0.32

1969

-0.74 -0.24 -0.58 0.10 -0.67 -0.36

0.44 -Q72 •0.62

-0.66

-0.39

-0.67

0.47 -0.27 -0.07 -0.07 -0.24

1970

-0.35 -0.57 -0.24 -0.03 0.01 -0.07 0.44

-0.35

-0.18

-0.26

-0.32 -0.21 -0.47 0.03 055

1971

-0.44 -0.50

0.34

0.07 -0.24 0.05

-0.27

045 -0.74 -0.06 0.32 0.52

1972

-0.94 -0.43 -0.44 -0.67 -0.75 -0.32 -0.91 -0.77 -0.51

-0.59 -0.42 -0.69 0.30

-0.05

-0.62 -0.42

0.18 -0.29 -0.82

1973

-0.78 -0.32 -0.79 •0.17 -0.77 0.38 -0.85

0.23 -0.05

-0.57 -0.52 -0.69 -OX

-0.99

-0.77

0.44 -0.60 -0.62

1974

-0.35 -0.14 -0.52 -0.48 -0.28 -0.17 -0.71 -0.40 •0.15

-0.67 -0.55 -0.79 -0.04 -0.07

-0.05

-0.63 -0.X -0.13 -0.67 -0.59

0.71 -0.52 0.10

0.23

0.25 0.17

0.05

0.08

-0.60

0.54 -0.04

0.01 0.00 0.04 •0.83

0.11 -0.22

-0.65 -0.29 0.41

0.61

0.73

0.08 -0.X

1975

-0.63 0.52 -0.02 -0.67 0.22 -0.48 0.16

0.41 -0.24

-0.86

-0.34 -0.71 -0.11 -0.21 -0.53

1976

-0.23 0.27 -0.39 -0.03 -0.37 -0.86 -0.09 O X -0.53

-0.18 0.30 -0.76 -0.26 -0.34

0.06

0.61 -0.48 0.34 -OX 0.12

1977

0.68 -0.53 0.71

0.47 -0.31 -0.01 -0.78 -0.06

0.26

0.00 -0.51 -0.57 -0.40 -0.19

1978

-0.39 0.02

0.13 0.00 -0.34 -0.29 0.27 -0.30 -0.19 -0.32 0.02

-0.19

-0.79 Q22 -0.74 0.28 -0.X

0.00 -0.60 -0.65 -0.68 -0.78 -0.49

0.38 -0.80 -0.44 -0.45

1979

0.08

0.31 -0.13 -0.82 -0.03 0.47 -0.23 -0.26 0.11 -0.78 -0.22 0.02

0.45

0.28

-0.63 -0.67 -0.59 0.32 -0.81

1980

-0.57

0.20 -0.58 -0.71 -0.30 -0.33 -0.40 -0.80 0.55 -0.55 -0.52 0.42 -0.67 -018 -0.53

-0.16

-031 -0.15 -0.44 -0.03 -0.70

1981

0.28 -0.57

0.07 -0.18 0.33

0.24

-0.59

-015 -0.14 -0.73 0.20 -0.32

1962

0.30 -0.26 -0.22 -0.25 -0.80 -0.74 -0.90 0.18 -0.68 0.19 -0.14 0.16 -0.44 -Q06

0.65

-0.39

0.06 -0.44 0.24 -0.29 -0.11

1983

-0.30 -0.43

0.37 -0.37 -0.82 0.31 -0.46 0.20 -0.45 0.33 -0.61 -0.64 -0.32 0.26 0.30

0.62

Q49

1984

-0.01

1985

-0.94 0.00 -0.59 -0.66 0.06 -0.83 -0.47 0.75 -0.01 0.43 0.70 -0.03 -0.72 -0.41 0.19 -0.76 0.11

1986

-0.91

1987

-0.18 0.27

0.31 -0.50 0.02

0.34 -0.06 •0.96 -0.03 -0.54 -0.28 0.55

0.10 -0.40 0.08

0.34 0.07

1983

-0.53 -0.11

0.20 •0.49 -0.51

0.11 -0.59 -0.96 -0.35 -0.47 -0.57 0.07 -0.53 -0.19 -0.43 -0.40 0.29 -0.87 0.23 -0.06 0.17

0.10 -0.08

1969

-053

1990

0.73 -0.51 -0.56 -0.07 -0.03 0.27 -0.88 -0.77 0.00 -0.60 0.33

1991

0.01 -0.57

0.13 -0.34 •0.71

0.79

0.07

0.17 0.01

1992

-0.36 -0.07

0.51 0.02 -0.53 0.32

0.13

0.09 0.48 -0.54 •0.29 -0.40 0.06

0.51

1993

-0.18

0.10 -0.35 -0.36 0.31

0.05

0.55 -0.29 -0.17 -0.22 0.09

0.65 -0.17 -0.03 •0.43 -O50

1994

-0.14 0.29

0.31 0.19

1995

0.20 0.03

0.45 -0.59 -0.35

0.39

0.15

1996

-0.40

0.33

0.06

0.29

Mean

-0.21 -0.06 -0.05 -0.34 -0.31 -0.05 -0.18 -0.16 -0.30 -0.25 -0.16 - O X -025 -020 -0.10 -0.22 -0.23 -0.07 -0.21 -0.25 -0.06 -0.19 -023

0.19 -0.63 -0.66 0.00 -0.61 -0.50 -0.62 -0.56 -0.75

0.22 -0.51 -0.73 -0.77 -0.64 -0.56 -0.02 -0.69 -0.35 0.06 0.27

0.OB -0.42 -0.13 0.28 -0.32 -0.75 -0.65 -0.87

0.51

0.03

0.15

0.26 -0.66 -0.44 -0.26 -0.63 -0.68

0.16 -0.07 -0.72

0.28 -0.05 0.02 -0.15 -0.34

0.36 -0.18 -0.63 -0.60 0.41 -0.24 0.09

0.17 0.34 -0.71 -0.07

0.X -0.61

-Q41 -0.81 -0.12 -0.07 -0.37

0.56 0.06 -0.69 -0.94 -0.69

0.01 -0.14 0.59 -0.22 0.04 -0.69 -0.13 -0.63 -0.84 -0.68 -0.36 -0.19 -0.76 0.56 -0.90 -0.18 0.11 -0.59 -0.56 -0.05 -0.08 -0.17

0.31

0.51

0.29

0.29

0.04 -0.50 -0.50 -0.66 0.16 -0.61 0.46

0.17 0.28 0.24 0.82 0.41 0.31 -0.72 -0.28 0.46 -0.31 -0.42 -0.44 0.18

0.18

0.64 •0.78 0.06 -0.23

0.75

0.67

0.23 -0.48 0.25 -0.71

0.00 -0.58 -0.67 -0.47 -0.04 0.53 0.16 -0.16 0.X

0.00 •0.46 0.01

0.16

015

0.72 -0.11 0.58 0.37 -0.76 0.03

Q27 -0.11 -0.52 -0.51

0.65 -0.35 0.17 0.42 -002 -0.61 0.23 -0.84 - O X 0.28 -0.17 0.10

0.63 -0.X

0.11

-0.47 -0.81

-0.58

-0.63

0.10

-0.70 -0.69

0.54

Chapter 3 Data Analysis: OECD Countries

Quantity standard deviation vs price standard deviation in 23 OECD countries Figure 3.1

covariance between price and quantities. Table 3.10 presents these correlations for the OECD countries over the whole sample period. The last row of the table presents the mean correlation for each country averaged over the whole sample period. As can be seen, about two-thirds of the correlations presented in the table are negative. The last row of the table shows that, on average, the correlations are negative for all OECD countries. This reflects the tendency of the consumer to move away from those commodities having above average price increases. Table 3.11 presents the averages of the Divisia moments over the sample period for each country from the last row of Tables 3.6-3.10. Columns 26 of the table present the average quantity index, average price index, average quantity variance, average price variance and average price-quantity correlation,

87

88

International Consumption Comparisons Table 3.11 Divisia moments in 23 OECD countries

Country

Divisia quantity index

Divisia price index

Divisia quantity variance

Divisia price variance

DQ

K (4) 8.74

n

Divisia price-quantity correlation

1.

Australia

2.26

DP (3) 5.98

6.48

P (6) -0.21

2.

Austria

2.35

4.22

8.76

5.89

-0.06

3.

Belgium

2.45

4.43

7.23

8.87

-0.05

4.

Canada

2.21

4.65

11.55

5.43

-0.34

5.

Denmark

1.62

6.39

11.63

5.12

-0.31

6.

Finland

2.70

6.36

13.06

13.25

-0.05

7.

France

2.52

5.76

5.21

13.30

-0.18

8.

Germany

2.60

3.35

7.40

11.62

-0.16

9.

Greece

3.28

11.20

16.11

7.10

-0.30

10.

Iceland

1.60

22.75

42.89

16.38

-0.25

11. 12.

Ireland

8.91 9.28

17.94

18.05

-0.16

Italy

1.72 2.64

5.13

8.72

-0.08

13.

Japan

2.97

4.12

9.96

5.24

-0.25

14.

Luxembourg

2.83

5.62

10.84

4.15

-0.20

15.

Netherlands

2.83

3.85

10.12

11.22

-0.10

16.

New Zealand

1.57

6.23

13.24

14.72

-0.22

17.

Norway

2.38

6.05

17.34

15.95

-0.23

18.

Portugal

3.71

8.82

30.63

4.80

-0.07

19.

Spain

2.67

9.31

9.81

23.29

-0.21

20.

Sweden

1.19

6.77

6.17

10.52

-0.25

21.

Switzerland

1.42

4.06

3.24

2.69

-0.06

22.

UK

2.03

6.98

5.82

15.39

-0.19

23.

USA

2.22

4.51

5.34

3.61

-0.23

2.34

6.94

12.09

10.08

-0.18

(D

Mean

(2)

(5)

All entries in columns 2 and 3 are to be divided by 100 and columns 4 and 5 by 10000.

Chapter 3 Data Analysis: OECD Countries

89

respectively, for each country. The last row of the table gives the grand mean, over all sample periods and over all countries. Tables 3.12 and 3.13 present the mean relative quantity log-changes ( Dqt - DQ ) and the mean relative price log-changes ( Dpt - DP ) for the 9 commodity groups for the 23 OECD countries. The last row of both tables present the average for each commodity group over the 23 countries. As can be seen, a clear pattern emerges in terms of the relative growth in consumption of food, clothing, transport and recreation, and of the relative growth in price of housing. In all OECD countries, food and (except for the UK and USA) clothing have a negative relative per capita growth in consumption, while transport and recreation have a positive relative per capita growth in consumption. In all OECD countries (except for Greece), the average relative growth in prices of housing is positive. Table 3.14 presents a summary frequency distribution (in percentages) of joint signs of relative consumption and relative prices for the OECD data. The entries in the first quadrant of the table are the percentages of the total number of observations having a simultaneous increase in relative prices and consumption, disaggregated by commodity and country. The entries in the other quadrants have a similar interpretation. For example, for food in Australia, relative prices and consumption move in the same direction for 8 + 28 = 36% of the time, while they move in the opposite directions 25 + 39 = 64% of the time. As can be seen, from the "all countries" rows and the "all goods" columns, over all, 31 + 29 = 60% of the pairs of relative prices and consumption have opposite signs, while 19 + 20 = 39% have the same sign. These results clearly support the law of demand, i.e. other things being equal, an increase in the relative price of a commodity causes its consumption to fall. Table 3.15 presents the summary results from Table 3.14.

International Consumption Comparisons

90

poo

lothi

ousi

urab

edic

rans ort

ecre tion

dues on

isce aneous

Table 3.12 Relative quantity log-changes of 9 commodities in 23 OECD countries (x 100)

LL

O

X

Q

^

H

DC

LLI

s

(D

(2)

(3)

(4)

(5)

(6)

(7)

(8)

(9)

(10)

o>

Country

D)

CO

Q.

Australia

-1.49

-2.02

0.87

1.21

-0.25

0.44

1.19

2.38

0.95

Austria

-1.21

-0.54

0.67

0.59

0.64

1.64

1.40

-1.47

-0.71

Belgium

-1.38

-0.44

-0.01

0.32

1.35

0.92

1.21

Canada

-1.85

-0.50

0.69

0.24

-1.95

0.69

2.92

1.84

-0.06

Denmark

-0.76

-0.63

0.57

-1.87

0.73

0.72

1.79

4.78

0.03

Finland

-1.32

-1.65

0.69

0.10

0.61

1.12

1.30

France

-1.48

-2.17

1.15

-0.86

3.06

0.63

1.51

0.11

-0.57

Germany

-1.04

-0.65

0.34

0.22

0.22

1.37

0.27

Greece

-1.01

-1.51

0.77

-0.28

2.03

2.84

2.38

-3.96

1.00

10. Iceland

-0.51

-1.60

-0.27

-0.98

1.04

0.37

1.64

3.04

1.25

11. Ireland

-0.75

-0.34

0.20

-0.29

-1.42

0.22

2.37

0.33

1.17

12. Italy

-1.23

-0.87

-0.25

0.19

2.36

1.54

0.86

-0.03

0.75

0.49

0.97 0.57

13. Japan

-2.23

-2.16

1.12

-0.43

1.35

1.73

1.41

0.20

14. Luxembourg

-1.93

-2.11

0.00

1.53

1.19

2.92

1.15

-0.66

15. Netherlands

-1.12

-0.97

-0.52

0.51

0.74

2.07

1.14

0.47

16. New Zealand

-1.15

-2.63

-0.68

1.50

1.36

1.85

0.79

-0.92

17. Norway

-1.30

-1.15

0.21

-0.10

2.75

0.57

2.30

18. Portugal

-1.36

-2.29

4.03

-0.03

-0.62

1.77

3.29

19. Spain

-1.44

-1.12

-0.55

-0.93

3.41

3.11

0.60

20. Sweden

-0.66

-0.21

0.14

-0.75

2.16

0.78

1.41

-0.45

-1.68

0.14

-1.50

1.33

0.77

0.42

-1.65

0.94

-0.43

-0.04

1.35

1.49

1.70

-1.91

0.33

-0.21

0.09

1.29

0.28

2.61

-1.27

-1.13

0.38

-0.07

1.08

1.30

1.55

21. Switzerland 22. UK 23. USA Mean

-1.64

0.67 -0.74 1.34

0.00

-1.12 0.59 0.49

0.39

-0.29

0.48

0.26

91

Chapter 3 Data Analysis: OECD Countries

1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. Mean

(1) Australia Austria Belgium

(2) 0.08 -1.16 -0.84

(3) -0.47

Canada Denmark Finland France Germany

0.22 -0.92 -0.75 -0.32 -0.77

Greece Iceland

0.18 -0.33

Ireland Italy Japan

-0.84 -1.23 -0.12

Luxembourg Netherlands New Zealand Norway Portugal Spain Sweden

-0.05 -1.27 -0.14 -0.30 -1.03 -1.01 -0.93

Switzerland UK USA

-0.50 0.33 -0.16

-0.83 -2.44

-0.52

-0.89 -0.23 -1.11 -1.25 -0.63 0.03 -0.53 0.22 0.28 -1.35 0.55

(4) 0.43 1.74 0.58 0.11 1.64 0.59 1.06 1.35 -0.93 0.41

(5) -2.02 -0.93 -1.17 -0.36 -0.31 -0.57 -0.44 -1.18 0.04 -0.90

1.31 1.34 0.32

-1.10 0.75 -1.17

0.58 2.02 3.36 1.27 1.52 0.06 1.36 0.57

-0.90 -1.47 -2.09 -0.74 -1.30 -0.10 -0.29 -0.77

-1.63

1.32 0.09

-0.68 -1.18

-0.65

0.96

-0.82

0.70 -0.18 -1.45 -1.23 -0.83 0.09 -0.09 -1.73

(6) 0.94 1.75 1.30 0.93 -0.74 2.01 -2.40 0.80

(7) -0.24 0.00 0.09 -0.46 -0.02 0.15 0.90 0.29

(8) 1.02 -0.42 0.05 -0.95

0.11 2.02

-0.59 -0.46

-0.27 -0.01

3.93 0.16

0.61 -0.14 -0.14

-1.00 -0.73

-0.26 0.29 2.28 2.38 -3.77 1.39 -1.26 -0.47

-0.26 0.16 -3.59 0.69 -0.59 -0.51 0.25

-1.25 -0.12 -1.00 0.81

-0.23 -0.95 0.27 -0.37 -1.20 1.41 0.39 -0.78

Miscellaneous

Education

Recreation

Transport

Medical

Durables

Housing

Clothing

Country

Food

Table 3.13 Relative price log-changes of 9 commodities in 23 OECD countries (x 100)

(9) 0.90 1.44

(10)

1.16 0.65

0.88 0.80 0.83 1.03 0.22

2.01

0.33 1.06 1.04

0.91

1.11

3.29 3.37

1.10

1.39

1.68 0.83 0.20 0.41 1.18 1.41

1.02

-0.12

0.03 1.45

-0.16 0.11 -0.25

-1.13 -1.43

1.16

0.69 0.90 2.29 0.45 0.85 -0.07 0.82

0.63

-0.18

-0.35

1.63

0.87

1.61

2.24

92

International Consumption Comparisons Table 3.14 Frequency distributions of relative consumption and relative prices of 9 commodities in 23 OECD countries (percentages)

1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23.

Australia Austria Belgium Canada Denmark Finland France Germany Greece Iceland Ireland Italy Japan Luxembourg Netherlands New Zealand Norway Portugal Spain Sweden Switzerland UK USA

All countries

1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23.

Australia Austria Belgium Canada Denmark Finland France Germany Greece Iceland Ireland Italy Japan Luxembourg Netherlands New Zealand Norway Portugal Spain Sweden Switzerland UK USA

All countries

o O

(2)

(3)

3

£4

<)

1

(5)

1

re

(6)

f)

7

1 £

(8)

8 6 6 9 3 3 3 3 6 5 9 3 15 14 2 17 6 0 16 9 6 11 11

14 9 0 20 14 22 13 24 26 16 13 31 46 14 14 17 22 11 25 9 21 0 9

11 41 14 6 38 11 41 18 6 16 13 6 4 14 30 33 19 22 13 21 15 20 3

8 13 22 11 17 39 13 15 21 26 17 25 8 10 14 8 19 0 28 30 9 11 11

8 25 22 54 10 25 19 12 12 26 9 9 4 29 18 8 13 33 19 12 21 29 14

22 34 33 11 24 25 53 36 29 11 30 34 12 33 25 25 53 44 19 24 30 29 31

56 6 11 14 10 22 13 9 21 16 17 16 19 5 18 25 6 11 19 15 24 6 6

7

17

18

16

19

29

16

(9)

19 31 37 14 19 32 11 17 25

18 25

9

37 23

25 31 28 17 34 25 13 27 18 26 26 28 23 10 20 17 19 0 31 42 55 17 14

58 66 50 60 62 50 34 64 50 32 52 44 27 29 57 58 44 11 28 58 61 63 69

3 0 8 14 3 8 3 0 12 26 13 3 4 19 7 8 3 11 9 9 15 6 14

72 47 39 51 41 36 63 52 41 37 43 53 73 67 64 50 41 89 41 45 76 63 74

14 3 22 23 24 19 53 18 38 16 17 31 19 43 16 8 28 11 50 21 6 11 6

42 38 33 51 52 42 25 36 47 37 35 41 42 33 41 42 25 56 59 39 39 49 54

25 25 28 54 52 39 59 30 26 26 48 28 42 29 30 25 72 22 34 52 36 37 86

33 19

24

49

9

55

22

42

39

15

9 21 6 21 0 22 13

9

30

0

j

Tra/

(1)

o

Misi

Country

Clot

Negative relative consumption

Positive relative consumption

1 1

16

49

11

40

18

22

45

40

29

Negative relative prices 47 35 28 14 22 28 50 9 33 30 42 25 11 32 20 11 17 34 34 10 22 30 42 19 19 31 56 22 21 31 45 9 38 32 32 15 16 24 32 26 17 30 35 26 19 29 53 16 23 32 38 15 29 32 24 38 18 32 52 20 17 28 33 8 16 28 25 13 11 44 26 78 3 32 22 19 15 35 18 24 3 36 24 15 26 34 49 29 14 37 14 40

33 16 44 34 7 36 16 18 53 26 26 25 12 14 9 8 38 11 44 15 24 11 37

17 34 33 26 14 19 16 21 21 16 26 13 8 14 23 42 25 0 13 15 6 14 9

33 9 11 14 24 19 19 12 18 32 13 28 31 14 20 17 19 22 13 30 12 20 6

19 13 11 14 3 14 3 3 9 16 9 16 27 24 7 33 6 0 0 12 18 6 6

0 38 33 23 24 14 22 36 21 26 13 41 19 48 23 42 13 0 22 24 9 29 3

17 9

11

8 9 3 14 10 6 3 12 12 16 9 9 4 24 18 8 13 0 19 12 12 0 6

19 21 25 19 16 21 18 20 23 24 19 25 19 25 22 24 18 19 19 19 15 20 15

24

18

19

12

23

16

10

20

^ (")

1 8 1

^

§ (12) (13) (14) (15) (16) (17) (18) (19) (20) (21) Positive relative prices 11 14 17 33 28 18 39 19 53 31 3 44 50 41 31 19 20 13 16 44 16 31 6 63 14 25 50 20 25 22 28 25 6 44 33 34 22 54 40 37 26 11 9 23 9 46 9 14 21 17 28 21 14 52 52 52 28 33 41 44 24 19 28 44 25 31 8 25 6 36 59 30 19 21 28 31 19 6 41 66 9 9 24 58 9 16 24 3 24 64 33 12 58 29 44 21 24 25 20 9 15 32 29 18 32 37 42 37 26 33 19 26 32 63 32 21 26 35 39 33 18 30 9 26 22 48 48 13 61 47 27 19 16 9 25 9 16 41 66 9 31 27 19 23 12 46 19 81 30 12 46 19 33 14 24 52 14 19 38 33 10 19 10 27 23 18 25 9 30 55 41 29 0 45 33 21 33 17 42 50 27 67 0 8 0 20 50 22 16 56 41 34 16 9 53 16 41 11 17 22 33 0 67 78 56 38 11 33 21 28 50 34 29 31 28 25 19 19 22 42 30 18 30 9 24 55 42 29 9 36 9 22 45 15 3 12 30 39 45 27 9 61 49 17 29 27 11 19 23 9 26 63 40 37 18 34 9 43 46 31 6 74 9 6 51

(10)

30

20

19

31

30

39

19

17 14 9 24 26 13 22

13

18

Chapter 3 Data Analysis:

93

OECD Countries

Table 3.15 Frequencies of joint signs of relative consumption and relative price changes in 23 OECD countries (in percentages) Country

1. 2. 3. 4.

(1) Australia Austria Belgium

Positive consumption

Negative consumption

Opposite signs

Positive price (2) 18

Negative price (3) 35

Positive price (4) 28

Negative price (5) 19

(3)+(4)

20 20 22

28 30 32

21 25 19 16

59 55 58 67

(6) 63

5.

Canada Denmark

17

34

31 25 26 33

6.

Finland

24

30

25

21

55

7.

21

31

8.

France Germany

16

18 20

61 64

9. 10. 11. 12. 13. 14. 15. 16.

Greece Iceland Ireland Italy Japan Luxembourg Netherlands New Zealand

20 19 18 19 19 19 18 21

31 32 24 30 29

30 33 25 33 33 27

57 57

32 32 32 28

30 24 29 27

23 24 19 25 19 25 22 24

17.

Norway

28

34

1.8.

Portugal Spain

20 17

26 32

38 29 29

19

61 64

27 27 31

15 20 15

63 61 68

29

20

61

21

19. 20.

Sweden

18

21. 22. 23.

Switzerland UK USA

22 19 18

35 36 34 37

19

31

Mean

18 19 19

63 56 62 56 61 55 62 64

International Consumption Comparisons

94

3.3

Engel's Law

One of the most important empirical regularities in consumption economics is the Engel's law. This law sates that the budget share for food (wFt) falls with increasing income (Mt). Working (1943) and then Leser (1963) modelled the Engel's law into a linear regression framework, which is known as the Working's model, wR

=

ocF + P F logM t .

(3.1)

Choosing Mt =1 for some year t in equation (3.1), a F can be interpreted as the budget share of food during that year t. The coefficient p F gives 100 times the change in the budget share of food resulting from a 1 percent increase in income. Figure 3.2 presents the plot of food budget share (wFt) against the logarithmic of the per capita real consumption expenditure (log Mt) for the 23 OECD countries. As can be seen, in all plots, the points are scattered around a negatively sloping line. This clearly shows that Engel's law is well supported by the data. Table 3.16 presents the estimates for the Working's model parameters, ccF and PF for food in each country. As can be seen from column 3, all the income coefficient estimates are statistically significant. The cross-country average, for the 23 OECD countries, p F = -.20 (standard error = 0.02), is close to the findings from a number of previous studies, see Table 3.17. In Figure 3.3a, we pool the data across the 23 countries and plot the adjusted budget shares (wFtc - aFc) against the logarithm of income (log Mtc) in one graph. However, the points on the far right, which corresponds to Iceland, appear to be extreme among the 23 countries. In Figure 3.3b, we present the same graph for 22 OECD countries (excluding Iceland). As can be seen, the

95

Chapter 3 Data Analysis: OECD Countries

Australia

Austria

0.4 y=-0.1846x+1.9621 Ff=0.9706

0.1 8.8

9

9.2 9.4 LogQncome)

10.5

9.6

10.7

10.9 11.1 LogQncome)

11.3

Canada

Belgium 0.5

y=-0.1261x+1.34e9

y = -0.2108x+a9139 Ff=0.9452

Ff=0.9513

1

0.14 0.1

12.2

12.4

12.6

128

13

8.6

9

8.8

Logflncome)

9.2

9.4

Log(lncome)

Denmark

Finland

y = -0.2822x+3.2525

0.45 y = -0.1984x+23747

ff = 0.9571

Ff=0.9539

m 0.2 0.15 10.3

0.15 10.5

10.7

10.9

LogQncome)

9.8

10

10.2

10.4

10.6 10.8

Logflncome)

Food budget shares against logarithm of per capita real consumption expenditures in OECD countries Figure 3.2

96

International Consumption Comparisons

Food budget shares against logarithm of per capita real consumption expenditures in OECD countries Figure 3.2 (continued)

Chapter 3 Data Analysis: OECD Countries

97

Luxembourg

Japan 0.35 £

y = -0.1826x+1.574B Rz = 0.9764

0.3 ?

7.1

7.3

7.5

12.3

7.7

125

r 1

129

NewZealand

Netherlands

•> 3

127 Logflncome)

Logflncome)

0.2 0.19

0.3 0.2

Z 0.18

^ y=-0.22x+23556 ^

^

R?=0.9371

^ H k ^ ***^fc

n-i . 8.7

m 0.17

y = -0.1361x+1.4778 R? = a7218

0.16 4 9.1

9.5

9.9

9.4

9.45

Logflncome)

9.5

9.55

9.6

Logflncome)

Portugal

Norway 0.35

0.3O)

•o 0.25

y = -0.2123x+1.6944 «0 0.27

10.6

R?=0.9228

0.25

0.2 10.8

11

11.2

11.4

11.6

6.35

6.45

6.55

6.65

Logflncome)

Log(lncome)

Food budget shares against logarithm of per capita real consumption expenditures in OECD countries Figure 3.2 (continued)

International Consumption Comparisons

98

Sweden

Spain 0.35 a

0 3

% 0.25 m 0.2

y=-0.294x+4.1663 Bf=0.8801 0.1 12.6

12.8

13 13.2 Log(lncome)

y=-0.313x+a7341 Ff = 0.8675

0.15 4 10.8

13.4

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^^•^» ^ < V

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0) CD

w % 0.25 o>

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10

™

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|

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*W

«0.2

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^

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^ ^ ,

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9.1

9.3

9.5

9.7

Log(lncome)

Food budget shares against logarithm of per capita real consumption expenditures in OECD countries Figure 3.2 (continued)

Chapter 3 Data Analysis: OECD Countries

99

Table 3.16 Estimates of Working's model for 23 OECD countries (Standard errors are in parentheses) Country

(D 1.

Australia

Intercept

Income coefficient

ctvxlOOO

PF

fl2

(2)

(3)

(4)

1.962 (0.050)

-0.185 (0.005)

0.97

Austria Belgium Canada Denmark Finland France 8. Germany 9. Greece 10. Iceland

2.867 2.914 1.347 3.253 2.375 1.667 1.968

-0.238 (0.005) -0.211 (0.009)

-0.152 (0.002) -0.177 (0.003) -0.097 (0.005)

0.98 0.95 0.95 0.96 0.95 0.99 0.99 0.92

11.

3.357 2.439 1.575 2.157 2.356 1.478 2.516 1.694

-0.064 (0.023) -0.355 (0.041)

0.31 0.77

-0.314 (0.016)

0.93 0.98 0.92 0.94 0.72 0.94 0.92

2. 3. 4. 5. 6. 7.

Ireland

12. Italy 13. 14. 15. 16. 17. 18.

Japan Luxembourg Netherlands New Zealand Norway Portugal

(0.060) (0.108) (0.045) (0.120) (0.077) (0.018) (0.027)

1.411 (0.052) 1.421 (0.417) (0.345) (0.108) (0.043) (0.126) (0.083) (0.242) (0.103) (0.143)

-0.126 (0.005) -0.282 (0.011) -0.198 (0.007)

-0.183 -0.152 -0.220 -0.136 -0.202 -0.212

(0.006) (0.010) (0.009) (0.025) (0.009) (0.022)

19. Spain 20. Sweden 21. Switzerland

4.166 (0.256) 3.734 (0.240) 2.062 (0.086)

-0.294 (0.019) -0.313 (0.022) -0.177 (0.009)

22. UK 23. USA

1.725 (0.138) 1.493 (0.039)

-0.138 (0.013) -0.142 (0.004)

Mean

2.258 (0.166)

-0.199 (0.015)

0.88 0.87 0.93 0.77 0.97 0.89

100

International Consumption

-0.5

!i

I

9 , s

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*» " »

17

13

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%

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n

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Food budget share vs Log(lncome) for pooled data from 23 OECD countries Figure 3.3a

10

12

0> 3 XI

1 3

-4

y = -0.2453x+0.4128 Log(lncome)

Food budget share vs Log(lncome) for pooled data from 22 OECD countries (excluding Iceland) Figure 3.3b

Comparisons

Chapter 3 Data Analysis:

101

OECD Countries

Table 3.17 Previous estimates of Working's income coefficient for food Authors) 1. Aasness and Rodseth (1983) 2. Adams et al (1988)

Country Norway

Estimates derived from Time series Cross-section -.174 (.008)

3. Barten(1993)

Australia Netherlands

-.121 (.033) -.121 (.023)

4. Barten(1993) 5. Blanciforti and Green (1983)

Netherlands USA

-.125 (.023) -.127 (.031)

6. Chen (2001)

Cross-country Spain

7. Chung and Lopez (1988) 8. Chung and Lopez (1988) 9. Deaton and Muelbauer (1980) 10. Rebigetal(1988) 11.Rnkeetal(1984) 12. Finkeetal(1984) 13. lmhoff(1984) 14. Izan and Clements (1979) 15. Musgrove(1985) 16. Rajapakse(1992) 17.Selvanathan,S.(1993) 18. Theil (1987)

Spain Great Britain Cross-country Japan Sweden Netherlands Cross-country Dominican Republic

-.140 (.008) -.153 (.013) -.106 (.027) -.127 (.033) -.104 (.007) -.139 (.003) -.139 -.128 (.014)

Cross-country Netherlands

20. Theil etal (1987)

China Cross-country

Mean Weighted mean*

-.156 (.017) -.160 (.026)

Sri Lanka Cross-country

19.TheilandBnke(1984) 21. Yuen (2001)

-.149 (.011) -.183 (.013)

-.154 (.020) -.130 (.016) -.134 (.020) -.118 (.006) -.130 (.017)

-.144 (.023)

-.136 (.013)

-.137 (.020)

Source: Chen (2001) and Chung and Lopez (1988). The weights are inversely proportional to the individual standard errors.

points are scattered around a downward sloping straight line with slope PF = -.25. This estimate is in line with the cross-country average of p F = -.20 from column 3 (last row) of Table 3.16.

102

3.4

International Consumption Comparisons

Preliminary Estimates of Income and Price Elasticities

In Chapter 2, we introduced the double-log demand equations as an example for the demand equations without specifying the form of the utility function. In this section, we use double-log demand equations to obtain preliminary estimates for the income and price elasticities. In Chapter 9, we use the differential demand systems to obtain final estimates for the demand elasticities and then compare the two sets of estimates. We consider the double-log demand equation (2.4) given in Chapter 2 for commodity i in finite-change form DqA = oCi + Tii DQt + Yi [Dp* - DPt] + eit,

i=l,...,«,

(4.1)

where oti is an autonomous trend term; r); is the income elasticity of commodity i; Yi is the Slutsky own-price elasticity; and eit is a disturbance term. It is worth noting that this double-log demand equation includes only the own-relative price and not other prices. We estimate (4.1) by least squares (LS) for each country separately. Tables 3.18-3.19 present the estimates for the income elasticity (T);) and own-price elasticity (Y), respectively, for each commodity for the 23 OECD countries. The last row of the table presents the elasticities for each commodity averaged over the 23 countries. As can be seen from Table 3.18, all the income elasticites, except the ones for education corresponding to Denmark and Iceland, are positive. However, the two negative elasticities are statistically insignificant. All the elasticities in column 2 for food are less than one indicating that food is a necessity in all OECD countries. The average value of the food elasticity for the OECD countries is .6. On average, the income elasticities for clothing, durables,

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Chapter 3 Data Analysis: OECD Countries

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International Consumption Comparisons

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Chapter 3 Data Analysis: OECD Countries

105

transport and recreation are larger than one indicating that these commodities are luxuries in the OECD countries, while the income elasticities for housing, medical care and education are less than one indicating that they are necessities. In Table 3.19, most of the own-price elasticities (164 out of 196) are negative as they should be. On average, all the price elasticities are negative and less than one in absolute value, indicating that demand for all 9 commodities in the OECD countries are price inelastic.

3.5

Preliminary Estimates of the Income Flexibility

In this section, we discuss various informal data analysis techniques to obtain estimates for the parameter, income flexibility. While the estimates we derive in this section have only a preliminary status, we formally estimate the income flexibility in Chapter 9. The estimate of income flexibility is exclusively used as an input for general equilibrium models, where the price elasticities are estimated based on the <j) value. The study of income flexibility is important for a number of reasons. One of them is to test the well-known Frisch's (1959) conjecture, which states that the income elasticity of the marginal utility of income (1/0) decreases in absolute value as the consumer (or country) becomes more affluent. Frisch (1959, p. 189) provides some numerical conjectures for the dependence of the elasticity on the level of real income. The value of the elasticity varies from -10 (for an extremely poor population), -2 (for the middle income bracket) to -. 1 (for the rich part of the population). Later in this section, we verify whether or not Frisch's conjecture is supported by the OECD data. In Chapter 2, we derived the finite-change version of the CBS/PI demand equation (5.14) under preference independence, which we reproduce here.

106

International Consumption

wit(Dqit-DQt)

= PlT>Q[ +
where DP, = X ; (/? ; +wjt)Dpjt. elasticity of commodity i, Tli =

1+=

Comparisons

i=l,...,n,

(5.1)

Under the assumption of unitary income

= 1-

That is, Pi = 0. Therefore, under the assumption of unitary income elasticity, equation (5.1) becomes (Dqit-DQt)

= ty(Dpit -DPt),

i=l,...,/i,

(5.2)

where DPt = ~£jWjtDpjt is the Divisia price index. For a given i, if we regress the growth in consumption of i relative to the overall growth in consumption, (Dqit - DQt), against the growth in relative price (Dpit - DPt) of i for t=l,...,T, the slope of the regression line can be interpreted as (|), the income flexibililty. For each country, we obtain the estimates of <>| for i=l,..,«, and calculate the average (j) over i=l,...,/i, which we refer to as an unrestricted average estimate of the income flexibility. These estimates § for the 23 countries are reported in column 2 of Table 3.20. In the above regression model (5.2), as <j) is the same for all i=l,...,n for each country, we can also perform a restricted pooled regression by considering (Dqit -DQt) against (Dpit - DPt) for all i=l,...,/i and t=l,...,T. Figure 3.4 gives the plots (Dqit - DQt) against (Dpit - DPt) for t=l,...,T and i=l,...,n for each country. As can be seen from the plots, for all countries (except Switzerland), the points are scattered around a negatively sloping line. The slope

Chapter 3 Data Analysis:

OECD Countries

107

Table 3.20 Four sets of estimates for income flexibility in 23 OECD countries (x100) Income flexibility Country (1) 1. Australia 2. Austria 3. Belgium 4. Canada 5. Denmark 6. Finland 7. France 8. Germany 9. Greece 10. Iceland 11. Ireland 12. Italy 13. Japan 14. Luxembourg 15. Netherlands 16. Norway 17. New Zealand 18. Portugal 19. Spain 20. Sweden 21. Switzerland 22. UK

Unrestricted

Restricted

Divisia

Divisia Average

(2) -0.43 -0.57

(3) -0.54

(4) -0.34

-0.16 -0.10

-0.15 -0.11

(5) -0.24 -0.07

-0.50 -0.30 -0.05 -0.16 -0.25 -0.34 -0.37 -0.24 -0.14 -0.51 -0.37 -0.12

-0.53 -0.61 -0.13 -0.25 -0.34

-0.59 -0.38

-0.13 -0.49 -0.64

-0.31 -0.27 -0.60 -0.10 -0.47 -0.48 -0.32 -0.62 -0.20 -0.22 -0.50 -0.33 -0.17 -0.42 -0.43 -1.31 -0.17 -0.21 -0.24

-0.98 -0.09 -0.21

23. USA

-0.11 -0.48

-0.01 -0.06 -0.39

Mean

-0.39

-0.30

-0.50 -0.50 -0.33 -0.15 -0.49 -0.38 -0.27

-0.36 -0.39 -0.14 -0.24 -0.25 -0.34

-0.05 -0.50 -0.47 -0.05 -0.12 -0.13 -0.45 -0.40 -0.16 -0.06 -0.34 -0.33 -0.10 -0.21 -0.24 -0.19 -0.14 -0.19 -0.07 -0.12 -0.28 -0.21

International Consumption Comparisons

108

Austria

Australia

Relative price

Relative price

Canada

Belgium y = -0.1025x +0.316

• IP

•5 -;o

*o

-io

10*

20

S3

-aeRelative price

Relative price

Finland

Denmark

Relative price

Relative price

Relative quantity against relative price in OECD countries Figure 3.4

Chapter 3 Data Analysis: OECD Countries Germany

France

!5

-35

Relative quantity

y=-0.2492x + 0.1947

-tS

•

« 0

-20

20-

J 3

,!/ -10 •

-20-

y=-0,1614x +0.1877 -46Relative price

Relative price

Greece

Iceland

Relative quant ty

y « -0,371 x t 0.6643 •

80 40 • : -.•••

& * . * * • •

-'

0

**"5 -10

W--

W*

2° "

SD

-86Relative price

Relative price

Italy

Ireland

y = -0.1403x+ 0.4147

Relative quantity

y = -0.2414x + 0.3436 •20-

8 * •••" •

* 1R

• I s ' . 'IIS. "'—*

0

-1

•

-20-

Relative price

Relative price

Relative quantity against relative price in OECD countries Figure 3.4 (continued)

110

International Consumption Comparisons

y = -0.5084x +0.0788

*

# y=-0.369x

* •1

0

-10

9 SK>
23

•

• -1°-

3

•

•

Relative price

-20

-10

Norway

y = -0.1162X + 0.3152

* 1 ^• 0

• •

4k*> " *^&*

-19*

•

Relative price

Netherlands ae-,

+ 0.213

>•

Relative quantity

•10.

*

Luxembourg

10

20

3

•

89Relative price

Relative price

Portugal

New Zealand

y=-0.9768x +0.7961 Relative quant ty

Relative quantity

Japan

•

I0" - •

Relative price

40 -

0

-5

J "

«

•' W 9 U ? • 1I • . 5 •~~" 1 3

Relative price

Relative quantity against relative price in OECD countries Figure 3.4 (continued)

111

Chapter 3 Data Analysis: OECD Countries

Spain

Sweden

48_. y = -0.0944X + 0.5498

Relative quantity

•

20»• •

0

-40

-20

20

'

e)

40

-20 <

*

*

y = - 0 . 2 1 0 2 x + 0.1966

10»

0 •

-20

J^*fr**^^

jjj

•

«Relative price

Relative price

UK

Switzerland

y = - 0 . 0 6 4 x + 0.684

-5 «9RH <: -8 4

Re ative quantity

Relative quantity

•

o

e)

40

-10 -

3

•

ir ^f l '«Mi|.ViC«*t 0

-5

*4^ -10

13

^ •

y = 0 . 0 1 1 7 x - 0.0494

Relative price

Relative price

USA

„.

i

" • ^ , : ^

• -8 -

•

•

Relative price

Relative quantity against relative price in OECD countries Figure 3.4 (continued)

.

International Consumption Comparisons

112

of the regression lines can also be interpreted as estimates for <)). These restricted estimates of (j) for each country are presented in column 3 of Table 3.20. Even though the values of the estimates given in columns 2 and 3 of Table 3.20 vary widely, all these values have the correct (negative) sign. The overall average of the income flexibility estimates is about -.4 (column 2) and -.3 (column 3), which agrees with the income flexibility estimates found in most of the previous empirical studies (e.g., see Theil and Clements, 1987; Theil and Suhm, 1981; and Selvanathan, 1993). Now, we consider another method of obtaining an estimate for <)>. First, multiply both sides of (5.2) by wit{Dpit -DPt) and then take the sum over i=l,...,n to give

t wit[Dpu -DP,][Dqu -DQt] 1=1

= 4 ± wit[Dpit -DP,]2.

(5.3)

i=i

Using (2.10) and (2.11), we can simplify (5.3) as r,

=

<»nt,

=

^-,

t=i,...,T.

(5.4)

Therefore, (f

t=l,...,T.

(5.5)

Column 4 of Table 3.20 gives the value of <> | , based on (5.5) and Tables 3.8, 3.9 and 3.10, and are averaged over t=l,...,T for each country. As can be seen, the

113

Chapter 3 Data Analysis: OECD Countries

average estimate of (() for the 23 countries is -0.34, which is very close to the averages in columns 2 and 3 of the same table. An alternative method of obtaining an estimate for the income flexibility <j) is to sum both sides of (5.4) over t=l,.. .,T to give

r

=

4>n,

where T=(l/T) X , r t and TT=(1/T) £ , I I t . Therefore, 4

=

=.

(5.6)

n Column 5 of Table 3.20 gives the value of (|) for each country based on (5.6) and Table 3.11. As expected, all the estimates of <|) are negative with an average of -.21, which is somewhat lower than the (average) estimates of (|) in columns 2, 3 and 4. Instead of pooling the data across commodities and time, alternatively, one could pool them over countries and time. In order to achieve this, for equation (5.2), we add a country subscript c (=1,.. .,23), to get (Dqcu-DQf)

=

HDp
i=l,...,n.

(5.7)

Summing both sides over t=l,...,T and dividing by T for each country, c=l,...,23, we get (Dq[-DQC)

=

$(Dpf-DPc),

i=l,...,n.

(5.8)

114

International Consumption Comparisons

The values of (Dq~? - DQc) and (Dp^ - DPc) are relative consumption and relative prices presented in Tables 3.12 and 3.13, respectively. Now, for each commodity i (=1,.. .,9), if we plot (Dqf - DQc) against (Dpi - DPC), c=l,...,23, the resulting slope of the regression line (5.8) is also an estimate for 0. Figure 3.5 gives the plots for the 9 commodity groups. As can be seen, in all plots (except for education and miscellaneous), all the points are scattered around a negatively sloping straight line. In Table 3.21, we present the resulting estimate of <|) for each commodity group. As can be seen, the overall average over the 9 commodities is <> j - -.26 and (j> = -.42 with the two outliers excluded, which is not far away from the mean values presented in the last row of Table 3.20.

Table 3.21 Another set of estimates for <)> for OECD countries Commodity 1. 2. 3. 4. 5. 6. 7. 8. 9.

Food Clothing Housing Durables Medical Transport Recreation Education Miscellaneous

Mean (all goods) Mean (excluding education and miscellaneous)

Income flexibility -.39 -.73 -.09 -.67 -.51 -.33 -.24 .25 .34 -.26 -.42

115

Chapter 3 Data Analysis: OECD Countries

Clothing

Food

Relative consumption

-1.0

05

00 -0.5

-0.5 • «

\*

y=-0.388a<-1.4716

Relative consumption

0

5

1 •

J

-3

$1 •

£***S»J^»"H

)

1

-v •

•

•

y=-0.7254x-1.6022

• Relaive price

Housing

Durables

*1

y=-o.o9eac+a4sa2 •

43 2•

1

n >

•

-1

1 •

t

* Relative consumption

I

Relalte price

•

2

• ****«^> J

-2

-2

•

1

»*-1 •

•

••"*-"•

•

-2

y=-0.667k-0.6154

3 •

*-

• 1

^^t**N^f

*

Relative price

Relative price

Transport

Med cal care

4-, •

O

UO|)C

3-

1

••#•

3

F

.

•

O .2 . 5

' -4

-2

«#.• •

<)

••

d)

y=-0.5142x+1.3969

k

2

^4

^ ^ . 2

^ ^^ H'

7. IE

» •' • •*

y=-0.3a83x+1.233

-2-

* ••

—i

0-

•• •

-1

3Relative price

Relative price

Relative consumption vs relative prices for 9 commodity groups Figure 3.5

International Consumption Comparisons

116

Rrtiirfim

RscrGdJcn

3-

fc • •

i h

•

•

at vec

2

*-rr-r^r

»

, * * -1.5

-1.0

-0.5

*

•

" •

• 00

•»-3 IT

: • . '• 05

1.0

•

1

o> C5

*••

»

•

O

onsumptlon

pti

•

»

CO

•

V==-02412x+1.466*

*

J.5

20

•

25

30

£5

y=Q253c+Q.0575

1.5

FHattve price

feiative price

Mscellaneous

9<S

«

^

15

20

J5

ysQ3416y-a04» Flsiative price

Relative consumption vs relative prices for 9 commodity groups Figure 3.5 (continued)

3.6

Testing the Frisch's Conjecture

In the introduction to Section 3.5, we pointed out that one of the reasons for studying income flexibility is to test the famous Frish's (1959) conjecture,

Chapter 3 Data Analysis: OECD Countries

117

which states that the income elasticity of the marginal utility of income (l/(j>) decreases in absolute value as the consumer (or country) becomes more affluent. Alternatively, <> | should increase in absolute value as the consumer (or country) becomes more affluent. In this chapter, we verify whether or not Frisch's conjecture is supported by data from 23 OECD countries. To do this, we use the estimates of <) presented in Table 3.20 together with the real GDP per capita (in US dollars) presented in Table 1.2. We estimate a relationship of the form, <])c

=

X + \iyc + ec,

where X and \i are parameters to be estimated; the superscript c denotes country c; yc is per capita real GDP (in international dollars) of country c; and ec is an independent disturbance term with zero mean. The F-test statistic value for the null hypothesis that, H0: ji = 0 and the corresponding p-value with respect to columns 2-5 of Table 3.20 are (F = 1.44; p-value = 0.24), (F = 0.18; p-value = 0.67), (F = 1.83; p-value = 0.19), and (F = 0.39; p-value = 0.54). As for all columns, the level of significance a = 0.05 < p-value, we are unable to reject the null hypothesis, HQ: (X = 0. As none of the F-values are significant, we conclude that <j) is independent of real income. The finding that <j) is unrelated to real income is, of course, at variance with Frisch's (1959) conjecture. However, our rejection of Frisch's conjecture is well in agreement with a number of previous studies (e.g. Clements and Theil, 1996; Theil, 1980; Theil, 1987; and Selvanathan, 1993). We shall further analyse Frisch's conjecture in Chapter 4 (with LDC data).

International Consumption Comparisons

118

3.7

The Validity of Preference Independence

In Chapter 2 we pointed out that the assumption of preference independence leads to an attractive simplification of demand equations. There are two distinct justifications for this assumption (Clements, 1987; Clements and Selvanathan, 1994): (i) The economic justification in terms of preference independence being plausible when the commodities in question are broad aggregates; and (ii) the statistical justification that the assumption reduces the number of unknown coefficients to be estimated from the order of n2 to n. However, whether it is truly legitimate to invoke the assumption of preference independence is largely an empirical question. In this section and in Chapter 9, we discuss some empirical evidence on this topic. From Section 2.2, under preference independence, the finite-change version of (2.4) can be written as Dqit = TliDQt + riiifDp, -DP;),

i=l,...,«,

(7.1)

where Tlii

=

(hi,

(7.2)

with T|i being the income elasticity and Tin being the own-price elasticity of i. As (7.2) holds for i=l,...,ra, it is clear that, under preference independence, ownprice elasticities are proportional to income elasticities with 0 being the factor of proportionality. In other words, luxuries are more price elastic than necessities (Deaton, 1974; Pigou, 1910). To analyse the evidence on the proportionality relationship (7.2), we use the income and price elasticity estimates presented in Tables 3.18 and 3.19.

119

Chapter 3 Data Analysis: OECD Countries

Figure 3.6 plots each pair of the own-price elasticity (r^) against the income elasticity (r|j) and the solid line is the LS line. The points are scattered around a negatively sloping line and the location of the points give evidence that luxuries tend to be more price elastic. The estimate of the factor of proportionality is -.26 with standard error .03, which is not far from the estimates of (j) presented in Table 3.20. The significance of the factor of proportionality gives indirect evidence to the preference independence hypothesis. Even though our findings are in contrast to Deaton's (1974) findings, however, acceptance of preference independence was supported by a number of other previous studies (e.g., Clements et al, 1984; Selvanathan, 1993). We shall formally test the hypothesis of preference independence in Chapter 9.

*

Price elasticity

1' •** •»*'»", **fiV T r _Sjt_r

•

i

i

>

.

•

••

*

•

^

• -3 y = -0.2601 x

* Income elasticity

Own-price elasticity against income elasticity Figure 3.6

120

International Consumption Comparisons

References Aasness, I., and A. Rodseth (1983). 'Engel Curves and Systems of Demand Functions,' European Economic Review 20: 95-121. Adams, P.D., C.F. Chung and A.A. Powell (1988). 'Australian Estimates of Working's Law under Additive Preferences: Revised Estimates of a Consumer Demand System for use by CGE Modellers and other Applied Economists,' Impact Project Working Paper No.0-61, University of Melbourne, Victoria, Australia. Barten, A.P. (1993). 'Consumer Allocation Models: Choice of Functional Form,' Empirical Economics 18: 129-158. Blanciforti, L., and R. Green (1983). 'An Almost Ideal Demand System Incorporating Habits: An Analysis of Expenditures on Food and Aggregate Commodity Groups,' Review of Economics and Statistics 65: 511-515. Chen, D.L (2001). World Consumption Economics. Singapore, London: World Scientific. Chung, C.F., and E. Lopez (1988). 'A Regional Analysis of Food Consumption in Spain,' Economics Letters 26: 209-213. Clements, K.W. (1982). Divisia Moments of Australian Consumption,' Economics Letters 9: 43-48. Clements, K.W. (1983). 'The Demand for Energy Used in Transport,' Australian Journal of Management 8: 27-56. Clements, K.W. (1987). 'Alternative Approaches to Consumption Theory,' Chapter 1 in H. Theil and K.W. Clements, Applied Demand Analysis: Results from System-Wide Approaches. Cambridge, Mass.: Ballinger Publishing Company.

Chapter 3 Data Analysis: OECD Countries

121

Clements, K.W., S. Kappelle and EJ. Roberts (1984). 'Are Luxuries More Price Elastic than Necessities?' McKethan-Matherly Discussion Paper MM6, Graduate School of Business, University of Florida, Gainesville. Clements, K.W. and S. Selvanathan (1994). 'Understanding Consumption Patterns,' Empirical Economics 19: 69-110. Clements, K.W., and H. Theil (1996). 'A Cross-Country Analysis of Consumption Patterns,' Chapter 7 in H. Theil (ed.), Studies in Global Economics. Advanced Studies in Theoretical and Applied Econometrics. Boston: Kluwer Academic Publishers, pp.95-108. Chung, C-F., and E. Lopez (1988). 'A Regional Analysis of Food Consumption in Spain,' Economics Letters 26: 209-213. Deaton, A.S. (1974). 'The Analysis of Consumer Demand in the United Kingdom, 1900-1970,' Econometrica 42: 341-367. Deaton, A.S., and J. Muellbauer. (1980). 'An Almost Ideal Demand System,' American Economic Review 70: 312-326. Fiebig, D.G., J.L. Seale, Jr., and H. Theil (1988). 'Cross-Country Demand Analysis Based on Three Phases of the International Comparisons Project,' in J. Salazar-Carillo and D.S. Prasada Rao (eds.), International Comparisons of Purchasing Power and Real Income. Amsterdam: NorthHolland, pp.225-235. Finke, R., L.R. Flood and H. Theil. (1984). 'Maximum Likelihood and Instrumental Variable Estimation of a Consumer Demand System for Japan and Sweden,' Economics Letters 15: 13-19. Frisch, R. (1959). 'A Complete Scheme for Computing All Direct and Cross Demand Elasticities in a Model with Many Sectors,' Econometrica 27: 177-196. Imhoff, E.V. (1984). 'Estimation of Demand Systems using Both Time Series and Cross-Sectional Data,' De Economist 132: 419-439.

122

International Consumption Comparisons

Izan, H.Y., and K.W. Clements. (1979). 'A Cross-Cross-Section Analysis of Consumption Patterns,' Economics Letters 4: 83-86. Leser, C.E.V. (1963). 'Forms of Engel Functions,' Econometrica 31: 694-703. Meisner, J.F. (1979). 'Divisia Moments of U.S. Industry, 1947-1978,' Economics Letters 4: 239-242. Musgrove, P. (1985). 'Household Food Consumption in the Dominican Republic: Effects of Income, Price and Family Size,' Economic Development and Cultural Change 34: 83-101. Pigou, A.C. (1910). 'A Method of Determining the Numerical Values of Elasticities of Demand,' Economic Journal 20: 636-640. Rajapakse, M.H.S. (1992). An Analysis of Consumer Behaviour: A Case Study of Sri Lanka. Ph.D. Thesis, La Trobe University, Victoria. Selvanathan, E.A. (1987). Explorations in Consumer Demand. Ph.D. Thesis, Murdoch University, Western Australia. Selvanathan, E.A., and K.W. Clements (1995). Recent Developments in Applied Demand Analysis. London: Springer. Selvanathan, E.A., and S. Selvanathan (1993). 'A Cross-Country Analysis of Consumption Patterns,' Applied Economics 25: 1245-1259. Selvanathan, S. (1993| A System-wide Analysis of International Consumption Patterns. Advanced Studies in Theoretical and Applied Econometrics. Boston: Kluwer Academic Publishers. Selvanathan, S., and E.A. Selvanathan (1994). Regional Consumption Patterns. London: Avebury. Theil, H. (1980). The System-Wide Approach to Microeconomics. Chicago: University of Chicago Press. Theil, H. (1987). 'The Economics of Demand Systems,' Chapter 3 in H. Theil and K.W. Clements (eds.), Applied Demand Analysis: Results from

Chapter 3 Data Analysis: OECD Countries

123

System-wide Approaches. Ballinger Publishing Company, Cambridge, MA. Theil, H., and K.W. Clements (1987). Applied Demand Analysis: Results from System-Wide Approaches. Cambridge, Mass.: Ballinger Publishing Company. Theil, H., and R. Finke (1984). 'A Time-Series Analysis of a Demand System Based on Cross-Country Coefficient Estimates,' Economics Letters 15: 245-250. Theil, H., J.L. Seale, Jr. and C.-F. Chung (1987). 'A Regional Analysis of Food Consumption in China,' Empirical Economics 12: 129-135. Theil, H., and F.E. Suhm (1981). International Consumption Comparisons: A System-wide Approach. Amsterdam: North-Holland Publishing Company. Working, H. (1943). 'Statistical Laws of Family Expenditure,' Journal of the American Statistical Association 38: 43-56. Yang, W., K.W. Clements, D.L. Chen (2000). 'A User's Guide to DAP 2000,' Discussion Paper 00.02, Department of Economics, The University of Western Australia. Yuen, W.-C. (2001). 'Food Consumption in Rich Countries,' Chapter 6 in D.L. Chen (ed.), World Consumption Economics. Singapore, London: World Scientific.

This page is intentionally left blank

CHAPTER 4 Data Analysis: Less Developed Countries E.A. Selvanathan & S. Selvanathan

In this chapter, we provide a preliminary data analysis of the consumption patterns of consumers in less-developed countries (LDC). This chapter is structured the same as Chapter 3, so that a systematic comparison can be made between the OECD and LDC consumption patterns in Chapter 5. In Section 4.1, we present the details of the data source and its characteristics. In the following Section, we present a summary of the data in the form of Divisia indices. In Section 4.3, we verify the Engel's law for the LDC data. Section 4.4 presents preliminary estimates of income and price elasticities based on a double-log demand system. In Section 4.5, we derive preliminary estimates of the income flexibility. In Sections 4.6 and 4.7, we verify the famous Frisch's (1959) conjecture and the assumption of preference independence. Based on the results from Chapter 3 for OECD and this chapter for LDC, in Chapter 5, we present a comparison of the consumption patterns of consumers in the LD and the OECD countries. As with Chapter 3, the results presented in this chapter are obtained using the Demand Analysis Package, DAP2000 (see the Appendix of this book for further details).

International Consumption

126

4.1

Comparisons

Data Source

The basic data, consisting of annual consumption expenditures (in current and constant prices) and the population for the 23 LD countries considered in this book are compiled from the Yearbook of National Account Statistics (United Nations: New York, various issues) and International Financial Statistics Yearbook (various issues). Even though Mexico and Korea were admitted to the OECD recently (in 1994 and 1996, respectively), we have included them with the LD countries as most of the data for these two countries relate to their preOECD years. Consumption data prior to 1984 for 15 of the 23 countries considered in this book were considered by Brozdin (1988) and also reported in Chen (2001). We have cross-checked our updated data with Brozdin's data prior to 1984 and have used the revised data wherever appropriate. As with the OECD countries in Chapter 3, for most LD countries, goods and services are classified into 9 commodity groups, which are again listed in Table 4.1 with their description. Table 4.2 summarizes the general characteristics of the LDC database. Column 1 lists the 23 LD countries, column 2 gives the local currency unit of each country, column 3 gives the sample period for each country and column 4 presents the sample size. The number of commodity groups considered for each country is given in column 5 with some comments in column 6. It should be noted that only 6 of the 23 LD countries have data for all 9 commodity groups.

4.2

Summary Measures

In this section we present the summary measures defined in Section 3.2 of Chapter 3 for the LDC data.

127

Chapter 4 Data Analysis: LD countries Table 4.1 Details of the commodity groups Commodity 1. 2. 3. 4. 5. 6. 7. 8. 9.

Food Clothing Housing Durables Medical Transport Recreation Education Miscellaneous

Description Food, beverages and tobacco Clothing and footware Gross rent, fuel and power Furniture, furnishings and household equipment Medical care Transport and communications Recreation, entertainment and cultural services Education and research Miscellaneous goods and services

The budget shares (at sample means) for each commodity i (wt), defined in equation (2.2) of Chapter 3, are presented in Table 4.3 for the 23 LD countries. For each commodity, the last two rows of the table present the mean budget share of each commodity averaged over the 23 countries (^) and the corresponding standard deviation. As can be seen from the food column, among the LD countries, on average, the Hong Kong (as well as Singapore) consumers allocate only about one-fourth of their income on food while the Indian, Sri Lankan and Philippines consumers allocate more than half of their income on food. On average, the LDC consumers allocate about 38 percent of their income on food. The remaining income is spent on clothing (9 percent), housing (12 percent), durables (8 percent), medical (4 percent), transport (10 percent), recreation and education (combined 7 percent), and all other goods (12 percent). The standard deviations presented in the last row of the table reveal that there is more variation in the budget shares for food, housing and transport across the LD countries.

International Consumption

128

Comparisons

Table 4.2 Characteristics of the LDC database

Sample period

Sample Number of size commodities

Comments

Country

Currency

1.

(1) Colombia

(2) Pesos

(3) 1972-1992

(4) 21

(5) 9

2.

Cyprus

Pounds

1980-1994

15

9

3.

Ecuador

Sucres

1973-1993

21

7

Recreation and education are included in niscellaneous.

4.

Fiji

Dollars

1977-1991

15

8

Education is included in recreation.

5.

Honduras

Lempiras

1970-1982

13

8

Education is included in recreation.

6.

Hong Kong

Dollars

1970-1995

26

9

7.

Hungary

Forint

1983-1994

12

8

8.

India

Rupees

1980-1995

16

9

9.

Iran

Rupees

1983-1995

13

8

10. Israel

NewSheqels

1970-1995

26

9

11. Jamaica

Dollars

1974-1988

15

9

12. Korea

Won

1974-1996

23

8

Education is included in recreation.

13. Malta

Ponds

1974-1993

20

8

Education is included in recreation.

14. Mexico

Pesos

1970-1998

29

8

Education is included in recreation.

15. Philippines

Pesos

1983-1995

13

6

16. Puerto Rico

US Dollars

1963-1994

32

8

Durables is included in housing, recreation and education a included in niscellaneous. Education is included in recreation.

17. Singapore

Dollars

1963-1995

33

8

Education is included in recreation.

1960-1995

36

8

Education is included in recreation.

18. South Africa Rand

(6)

Education is included in recreation.

Education is included in recreation.

19. Sri Lanka

Rupees

1974-1995

22

8

Education is included in recreation.

20. Taiwan

Dollars

1962-1997

36

8

Education is included in recreation.

21. Thailand

Baht

1976-1995

20

8

Education is included in recreation.

22. Venezuela

Bdivares

1984-1995

12

8

Education is included in recreation.

23. Zimbabwe

Dollars

1975-1987

13

8

Education is included in recreation.

129

Chapter 4 Data Analysis: ID countries

Housing

Durables

Medical

Transport

Miscellaneous

Clothing

Education

Food

Recreation

Table 4.3 Budget shares of 9 commodities in 23 LD countries (Means x 100)

(2) 37.75

(3) 6.77

(4)

(5)

(8)

(9)

(10)

11.90

5.80

(6) 5.82

(7)

1. Colombia

14.06

3.99

1.58

12.34

2. Cyprus

27.19

10.01

7.88

11.03

2.86

16.81

6.50

1.13

3. Ecuador

38.34

10.40

8.28

7.07

4.01

11.16

4. Fiji

37.81

7.60

15.78

9.81

2.23

14.40

4.84

5. Honduras

46.25

10.22

20.58

7.90

6.93

3.10

2.47

6. Hong Kong

25.54

18.40

14.56

11.17

5.75

8.21

7.14

7. Hungary

43.41

8.42

12.04

8.67

1.18

12.02

6.81

8. India

54.53

10.90

11.18

4.32

2.68

9.10

1.44

9. Iran

41.95

10.79

25.85

6.29

4.23

5.78

1.88

10. Israel

27.32

6.54

21.93

11.56

5.10

4.00

2.69

9.45

11. Jamaica

41.87

3.70

11.92

5.86

2.18

11.41 12.87

3.25

0.25

18.09

12. Korea

39.77

6.38

10.62

5.97

5.13

10.52

10.27

11.34

13. Malta

34.66

8.36

6.30

10.07

14.84

6.60

15.48

14. Mexico

35.05

8.54

10.73

11.46

3.69 3.83

10.81

5.50

14.07

15. Philippines

58.60

3.70

3.80

13.42

16. Puerto Rico

29.00

9.33

14.60

8.38

5.70

14.46

6.36

12.17

17. Singapore

26.24

8.23

10.33

8.43

3.13

13.41

11.94

18.29

18. South Africa

33.93

8.73

11.31

12.31

3.90

15.17

5.67

8.99

19. Sri Lanka 20. Taiwan

61.69 42.32

6.84

5.08

4.41

1.62

12.94

3.74

3.67

5.09

16.85

4.69

5.19

7.21

11.46

7.18

21. Thailand

39.02

10.71

9.31

7.93

5.76

11.49

4.49

11.28

22. Venezuela

37.87

8.61

4.06

2.47

7.22

2.78

26.05

23. Zimbabwe

33.99

12.18

10.93 15.24

10.29

4.78

2.20

4.86

16.45

Mean

38.21

8.57

12.26

8.16

3.94

10.42

5.43

1.45

11.57

9.65

3.08

5.29

2.81

1.57

4.03

2.90

0.80

6.10

Country

(D

Standard deviation

16.59 20.75 7.53 2.56

1.38

7.86 7.45

1.81

4.05 3.22

4.65

15.82

130

International Consumption Comparisons

Columns 2-10 of Table 4.4 present the mean log-changes in per capita consumption Dqt (defined in equation (2.5) of Chapter 3) of each commodity for the 23 countries. The last row presents their averages over all countries. As can be seen, the average growth in per capita consumption of food varies between -7.19 percent (Zimbabwe) per annum and 4.0 percent per annum (Cyprus and Taiwan) with an average of 0.7 percent per annum among the LD countries. The average LDC annual growth in consumption of clothing is 1.6 percent, housing 2.7 percent, durables 2.9 percent, medical care 3.3 percent, transport 3.1 percent, recreation 3.8 percent and education 2.9 percent. Columns 2-10 of Table 4.5 present the annual mean log-changes in prices of each commodity {Dpt), defined in equation (2.6) of Chapter 3, for each of the 23 countries. The last row of the table presents the mean price log-changes averaged over all countries. As can be seen, in the LD countries, the average growth in the price of food varies between 2.9 percent (Singapore) to 42 percent (Israel) with an average of 13.6 percent per annum. The average LDC annual growth in the price of clothing is 12.8 percent, housing 13.1 percent, durables 13.2 percent, medical 14.5 percent, transport 13.8 percent, recreation 12.3 percent and education 15.3 percent. Table 4.6 presents the Divisia volume index (DQt) for each country, defined in equation (2.7) of Chapter 3, over the corresponding sample period. The last row of this table gives the average of the Divisia volume index (DQ) averaged over the whole sample period for each country. As can be seen from the last row of the table, overall consumption growth in the LD countries varies between -4.3 percent (Zimbabwe) and 6.2 percent (Taiwan). The overall average growth in consumption is 2.1 percent per annum for all LD countries. Table 4.7 presents the Divisia price index (DPt) for each country, defined in equation (2.8) of Chapter 3, over the corresponding sample period. The last row of this table gives the Divisia price index averaged over the whole sample

Chapter 4 Data Analysis: LD countries

131

Table 4.4 Per capita quantity consumed of 9 commodities in 23 LD countries

Education

(6)

(7)

(8)

2.76

1.69

(9) 1.25

(10)

1.47

2. Cyprus

3.98

4.71

6.06

5.94

9.74

3.37

6.51

10.83

7.32

Transport

(5) 1.62

Medical

(4) 1.74

Durables

(3) -0.12

Housing

(2) 1.38

Clothing

(D 1. Colombia

Country

Food

Recreation

Miscellaneous

(Mean log-changes x 100)

2.42

3. Ecuador

0.04

1.92

2.18

0.57

1.56

4.17

4. Fiji

-0.73

-0.28

-1.14

0.45

-1.50

2.83

-1.09

0.25

-3.03

3.63

2.22

0.59

-0.56

1.80

2.15 -1.08

5.60

9.01

6.24

4.94

6.10

-4.30

5.86 2.19

-0.52

-1.18

4.01

1.75

8. India

0.96

2.35

1.31

4.66

-0.33

6.72

6.05

9. Iran

-1.20

-0.91

2.60

-1.96

3.39

4.70

3.56 2.37

-1.23

1.87

5.69

4.23

5.43

3.76

0.55

2.55

-1.47

0.20

1.74

-0.70

3.23

0.98

3.01

-2.67

0.10

12. Korea

3.40

2.78

4.90

8.53

10.82

10.16

7.79

7.95

13. Malta

3.50

4.24

5.28

4.33

3.69

4.18

5.08

8.18

14. Mexico

1.06

-1.00

1.99

1.12

2.15

1.91

0.84

15. Philippines 16. Puerto Rico

0.75

0.38

1.67

0.69

5. Honduras 6. Hong Kong 7. Hungary

10. Israel 11. Jamaica

2.51 0.04 3.84 0.05

6.56

2.19

1.61 5.42 -0.97

1.24

0.92

0.22

-0.22

3.77

3.04

3.12

4.35

3.82

4.75

5.02

17. Singapore

1.56

3.38

5.20

3.36

5.31

5.19

7.74

5.51

18. South Africa 19. Sri Lanka

0.40

1.79

0.42

0.42

1.48

1.41

1.19

0.30

0.68

4.21

2.08

1.23

-0.93

6.63

4.28

0.21

20. Taiwan

3.99

8.17

6.94

8.17

7.94

11.93

8.26

6.15

21. Thailand

2.54

3.17

8.06

7.84

7.67

5.41

6.48

22. Venezuela

0.40

5.59 -2.17

0.29

0.16

3.11

-0.44

1.68

-0.88

23. Zimbabwe

-7.19

-6.04

-2.20

-1.00

-0.09

-15.30

0.50

-2.54

Mean

0.74

1.56

2.71

2.87

3.29

3.08

3.83

2.88

2.92

132

International Consumption Comparisons Table 4.5 Prices of 9 commodities in 23 LD countries

(D 1. Colombia

0)

(2)

(3)

(4)

(5)

(6)

(7)

(8)

21.56

20.56

20.79

21.62

22.61

23.47

21.10

22.35

4.94

4.05

Miscellaneous

Education

Recreation

Transport

Medical

Durables

Housing

Clothing

Country

Food

(Mean log-changes x 100)

(10) 23.48

2. Cyprus

5.37

5.59

3.77

4.19

6.26

3.91

3. Ecuador

27.53

25.86

23.17

27.11

26.83

26.19

4. Fiji

7.39

8.88

7.96

6.29

9.90

5.44

7.44

5. Honduras

7.29

7.80

8.22

8.10

7.90

8.13

6.12

9.52

7.45

8.88

8.31

5.39

7.64

8.33

7.75

11.57

9.38

14.09

15.68

19.60

14.23

25.44

15.09

15.07 9.06

16.93 7.22

6. Hong Kong 7. Hungary

5.86 26.64 8.65 7.65

8. India

8.46

7.90

6.57

7.41

8.45

9.23

5.39

9. Iran

19.93

21.02

17.04

20.70

19.13

22.02

21.95

10. Israel

42.03

38.75

43.95

38.74

43.23

41.23

42.72

46.84

42.96

11. Jamaica

13.65

15.24

19.39

15.44

14.91

13.20

14.85

14.81

13.67

7.17

12. Korea

8.82

8.75

12.77

8.12

8.34

7.89

10.47

13. Malta

3.79

1.28

1.65

2.85

3.65

5.32

11.13 3.33

14. Mexico

27.37

27.02

28.30

27.39

28.85

30.77

29.95

31.37

15. Philippines

11.38

11.03

11.98

12.19

16. Puerto Rico

5.45

1.94

4.39

2.85

5.55

3.79

2.96

4.16

17. Singapore

2.94

2.03

3.61

3.52

3.87

3.92

1.40

2.91

18. South Africa

9.70

7.34

9.17

8.15

10.20

9.84

9.09

9.42

11.40

9.79

9.82

14.56

15.68

10.59

9.36

14.46

20. Taiwan

5.02

2.83

5.00

5.15

4.90

5.15

6.25

5.43

21. Thailand

4.53

7.01

6.35

5.96

5.53

6.18

5.87

7.13

22. Venezuela

32.34

26.89

25.78

33.13

29.76

32.80

28.21

31.92

23. Zimbabwe

13.13

11.89

10.13

10.39

10.94

15.15

10.63

10.42

Mean

13.58

12.77

13.11

13.17

14.52

13.83

12.28

19. Sri Lanka

5.39

9.89

12.83

15.30

14.20

133

Chapter 4 Data Analysis: LD countries Table 46

(8)


C

(9)

(10)

(11)

t (12)

(13)

2 (14)

a) 2 (15)

0)

(16)

(17)

(18)

3 o (A (19)

w

Tai\

(6)

I

Slnj

(5)

Hon

(3)

o I (7)

Phil

(2)

3 UJ

(4)

Kon

(1) 1961

o

Fiji

Year

Cole

Divisia volute indces in 23 LD comtries (Means x 100)

(20)

(21)

CO .c 1-

(22)

c IS

>

(23)

E N (24)

-1.65 0.61

1962 1963

3.05

333

1964

573 4.44 4.53

9.59

1965

582

312 -3.30

631

1966

273

4.96

1.66

312

1967

4.62 4.63

1.60

649

1968

9.41

669

4.15

626

1969

542 673

3.55

510

1970

804 1Q51 3.97

573 674

1971

354

568

374

247

4.27 674

230

1972

-1.60 4.94

688

382

4.40 7.52

1.23

a 25

858 635

369

3.87

4.72 673

527

1012

1973

270

1974

asi

655

-295 -567

341

1.35

-326

378 276

280

1975

Q80

695

-004 -Q44

-1.66 -1.83 370 8C8

1.81

596

1.12 -0.02

-9.71 4.27

1976

4.56

518

274

355 -3.77 688 S22

1.10

536 4.12 0.25

200 522

1977

1.73

4.56

4.22 1Q94

244 -258

1.16

360 4.94 -274

9.48 4.96 604

-14.03

1978

594

285

245

a 83 14.29

598 -6.83 7.56 7.53 4.57

221

026 690 4.17

4.63

1979

211

270

3.86 -379

533

389 -5.01 631 1041 5.82

-Q43 7.83

1.40

829

7.92 364

9.29

1960

214

386 -11.47 282

563

-343 -5.58 -229

-327

699

624

504

355

280

-4.38

1961

0,76 -Q07

1.52

263 -5.50 522

270

7.16 -0.96

-1.27 605

4.02

204

1.74

0.X

1291

1962

-0.47 9.58 Q09

-4.76 -7.46 243

-302

7.11 0.98 4.93 -833 -328

1.87 256 -0.02

235

268

0.54

-655

1983

-1.75 1274 -517

260

-1.08 4.22 4.67

11.32

1984

Q63 4.74 -001

-1.33

374

1.31

1985

-Q14 321

Q27

Q17

265

129 Q63

694

212

610

535

554

1.93

1.22

571 -Q02

•4.65

1987

1.92

682 -0.14

-1.12

1968

1.89 1Q71 -0.33

7.X

7.65 -4.22 394

1969

1.20

9.42 Q16

252

273

226

231 1.82

1.66

1990

123 653 -011

204

4.41 -322

1991

Q 02 Q79 -Q47

-0.79

604 -660 -Q03

1992

243

1.74 -5.93 393

9.25 7.51 -214 -6.87

323 -8.39 647

315

-255

1.93

1.71 -1.04 1568

1.69

9.15 -065

1.55

7.81 -6.65

595 Q71 0.18 -216 4.02 223

-Q41 268 -1.27 4.94 662 0.71 -361 -872 7.59 a57

683 -0.41

7.47 7.14 -256

Q86 4.83 362 -295 1.56

335

7.25 1Q54 -0.95 365 -Q10 S43 7.08 4.80 255 S63 295

3.52

306 -380 -5.50 S72

1.62

1.88 293

Q61 554

3.55 299 -1.93 391

083

-364

045 -3.43

545 228

278

-3249

362 373 0.06 Q34

-9.45

272

-1.60

-Q56 641 272

232

9.54 7.55

355 11.42

ax

1.74 -1893 1.83

-062 11.26 891 -9.27

0.44 -1284

7.78 377 222 -1.31 207

691

-1.78

648 S99 -Q5B

-028 607 3.52 515

7.01 034

9.01

0.94 203

383

Q64 361

4.41 -4.18

691

7.53 672

Q47

671

1.27 273

•0.23 4.32

4.59 300 -Q45 Q50 314

615 -1.98

692

692

625 -267

Q51 568

620

259

1.22 249

1.54

643

7.32

5.64 -633

4.70

7.30

-7.25

1.38

569

-5.21

527

672

648

1993

-674

1994

378

1995

4.95 0.03 233 -4.04

363

1996 1997 1996 Mban

9.38 3.87

285 -1313 9.34 -1.35 7.85 326 4.3B

1966

11.14 521

363

500 1363

-393

618

233

1.15

-0,92 264

551

204 4.53 7.54 Q39

4.97 1.64 5 X

1.46 -0.04 Q78 513 0.04 205

043 322 -0.17 586 4.64 1.10 Q69 274 4.34 0.77

1.57 615 4.79 -011 -4.26

134

International Consumption Comparisons

(19)

Zimbabwe

(18)

Venezuela

( 17 )

Thailand

(16)

Sri Lanka

(14) (15)

Taiwan

South Africa

(13)

Singapore

(12)

Puerto Rico

(11)

Philippines

Korea

(10)

Mexico

Jamaica

(9)

Malta

Israel

I ) I8!

Iran

CB C

o X7

India

(6)

c o

Hungary

5 (4) ( I

Honduras

(3)

Fiji

Ecuador

1 (1961 ) PI

Cyprus

Year

Colombia

Table 4.7 Divisia price indices in 23 LD countries (Means x 100)

(20)

(21)

(22)

(23)

(24)

1.89

1962

1.53

1963

1.52

0.53 1.05

1964

1.61

1.15

232

1965

1.91

0.51

3.70

120

1966

4.89

1.93

3.79

0.87

1967

276

232

3.19

4.34

1968

4.28

1.36

253

6.39

1969

4.18 -0.14 343

379

1970

3.97

150

393

4.07 229

1971

0.49

325

11.55

652

4.23 3.37

7.54

1972

291

4.41

13.87

557

3.52

673

4.05

8.00 1864

18.13

11.90

11.61 14.74 6.75

11.02

33.10

20.95

1282 1278 11.09

3257

1973

17.72

260

1974 23.60

19.32

14.71 1503

1976 21.89

1352

7.0O 0.98

3375 14.39 24.50 4.25 1284

1891

10.14

4.14

355

24.65 9.55 1625

1.40 17.16

3.06

0.59

1977 24.03

11.91

5.62

4.73

30.09 11.21 14.28 6.97 24.12

4.86

2.15 10.61 609

7.90 6.64

1.10

4.99

4356 26.03 18.23 3.96 1551

560

281

9.49 1354

6.56 9.11

666

8.58 14.94 11.03

57.11 20.70 18.24 6.62 1621

10.97 3.67 11.90 1316 9.56 10.69

10.86

1976 1978

16.43

11.28 4.89 10.51

1979 23.08

6.43 276 1282 1279 5.64 8.66 222

1.60

9.55 11.00

13.24 18.53 7.68 2311 1981 2304 10.77 1574 10.49 13.94 11.21

8524 19.91 25.40 14.39 30.40

9.38

6.96 14.50 21.24 18.51 155B

14.51

9.12

7861 11.40 17.60 9.16 2350

5.79

527 14.99 1208 14.75 11.38

13.58

6.41 17.40 6.87 11.29 9.53

£55

77.38 8.22 4.60 5.19 44.33

273

1.67 13.31 1373 3.90 5.31

1283

4.13 37.78

888

92.45 1279 285 •0.75 64.60

1.31

0.32 13.55 17.45 2.27 396

11.24

1.71 10.12 1696 0.76 0.41

15.53

1980 2329

1982 21.91 1983

1843

3.90

8.67

1984

18.65 6.11 31.78 5.50

845

7.43

598

8.70 158.52 23.76

3.58 -0.48 50.55 41.94 1.52

1.55

279

6.37

553

5.90 135.76 2326

327

0.87 299 10.89 897

1986 2273

1.79 24.56 8.35

502

503

683 19.00

38.72 11.64

3.81 -1.26 4625 16.16 0.64 054 1365 1.70 1.00 59.72 999 0.99 -0.15 17.42

821

0.56 212 12.19 1207

1987 2360

2.58 29.25 4.59

4.84

7.83

7.64 22.57

18.24 5.13

3.19

3.20 2.21 13.77

350

1.47

3.13 24.85 1312

1988 2382

3.26 47.56 10.15

7.31 12.05 852 20.45

1539 6.72 5.47 -0.46 77.49 872

348 13.86 11.62

1.81

4.25 2321

1989 2206

3.63 55.15 4.22

7.12 14.55 7.02 18.09

17.73

5.23

1990 26.37

4.51 39.42 7.22

7.23 25.06

8.73

13.97

9.20 4.43 24.59 11.41 3.97

1991 2 M 2

4.11 3864

824 35.30 1285 16.87

16.48

863

4.31 2200 15.56

1.93

259 14.59 1580 4.03 5.63 28.12

1985 21.07

5.00 27.94

7.44

9.81

0.91 86.04 AZi 1.89 2218 10.14

3.85

3.50 4.38 14.11 11.57 4.35 4.98 56.49 350 14.51 3348

3.75 6.01 3451

1992 25.00 6.55 41.85

699 20.35

8.28 20.42

10.31

5.51

305 14.34 7.44

1.47

2.16 14.54 379

4.11

3.47 27.06

1993

4.48 36.28

584 19.31

897 20.19

10.31

4.64

6.00 1.42 6.68

1.50

3.56 9.67

568

3.45

3.18 31.44

1994

5.52

7.41 18.00 9.08 31.23

11.17

6.09

1566

7.81

2.25 4.14 833

7.68

381

5.06 47.82

5.51

4.57

29.41

7.73

1.25

827

3.52

5.55 4369

5.16

27.59

3.12

1997

14.76

1.41

1998

1844

7.67

1995

664 39.36

1996

Mean 2204

4.92 2666

7.31 7.65

7.92 15.57

an

19.29

42.05 14.62

9.49

3.72 2872 11.67 4.22

3.03

8.25

9.23 11.54

5.13 5.60 30.91 11.66

Chapter 4 Data Analysis: LD countries

135

period for each country. As can be seen from the last row of Table 4.7, the overall annual price growth in the LD countries varies between 3.0 percent (Singapore) and 42.1 percent (Israel). The overall average growth in prices is 13.5 percent per annum among all LD countries. Tables 4.8 and 4.9 present the second-order moments, the Divisia quantity variance (Kt) and the Divisia price variance (n t ), defined in equations (2.9) and (2.10) of Chapter 3, for the LD countries over the sample period. As before, the last row of the table gives the variances for each country averaged over the whole sample period. A comparison of these two variances reveals that the Divisia quantity variances systematically exceed the corresponding Divisia price variances. To confirm this relationship, in Figure 4.1, we plot ^Kct against yjn ct for t= 1,... ,T and c=1,..., 23. As can be seen, most of the points lie above the 45° line indicating that on average, ^jKf >-\/n,e- This pattern agrees well with the results of the OECD countries (Figure 3.1) and previous studies. The Divisia price-quantity correlations (defined in equation (2.11) of Chapter 3), which measure the co-movement of prices and quantities, for the LD countries over the whole sample period are presented in Table 4.10. The last row of the table presents the correlation for each country averaged over the whole sample period. As can be seen, about two-thirds of the correlations presented in the table are negative. The last row of the table shows that, on average, the correlations are negative for all LD countries (except for Cyprus). This reflects the tendency of the consumer to move away from those commodities having above average price increases. Table 4.11 presents the averages of the Divisia moments over the sample period for each country collected from the last row of Tables 4.6-4.10. Columns 2-6 of the table present the average quantity index, average price index, average quantity variance, average price variance and the average price-

International Consumption Comparisons

136

Table 4 8 • v i s a quantity variances in 23 LD oomtries ( x 10000)

Yar

,3

<5

S

if

x

i

I

2

=

S

(1)

(9

(3)

(4)

(5)

®

(7)

{8)

B

(10)

(11)

^ (12)

(13)

i

s (14)

S (15)

t (16)

1961

i

w

(17)

(18)

w (19)

A W

^ H

S B

R W

542

1982

246

1963

915

604

19B4

2841 11.56 1240

3831

1985

11.60 281 364

953

1986

8823 20.26 Q82

913

1967

11.72 3089 1.01

24.70

1963

4285 823 267

994

1989

17.61 2325 4.96

826

1971

29C9

1972 1973 1522

219

1Q10

1883

875

1570 529 606

806

7Z7.20

5819

19.70

376

34.73 1804 568

19.66

622

804

Q26 14884

1504

323

Q51

21.17

353B 47.17 519

ace

4357

920

7.02 4586

1978

2281

961 14.06

24.74

1975 1286 1977 1658

11.63 7.01 7.98 24.35 723 S59

14.00

1974 1564 1976

f M

1Q77

1985 5286 1Q41

21.82

2334 269

2S31 1276 606

6S23 297

27.37 4.11

21.72 211 7380

5896 351

721 147.54 1960 12341 337

2052 1291 1674

56.35 1129 1241

3306

14.92 1393 934 14721 19.54 1340

12352

965

Q32 133.76

27.89 7.47

77.87

27.93

Q97

94.53

1665

91.83 3041

3349 7.94

1979 1967

4.44 27.09

1258

47.76

4257 10258 2293

4971 7.59

17.46 1362 1.97

39.01 4691 597

44.34

1980

633 14258

016

9922

5381

2382 2722 131.06 309

6342 615 2582

94.46 424 9.82

36928

8554

060

1597

4.85

7.82 9.76

1573 652

2049 2278 609

83.81 332 1532

13996

1271 Q66 2668

056

874

11.80

89.03 21.X 5278

4532 3351

7.95 1Q70 7.10

4989 4.13 916

37.71

2550

1338

4306 11654 1994

4.05 31.86

39.78 11.31 659

5357 226 1293

231.68

8503 524 29.29

13349

673 1.42

1961

1.98 347.68 394

1962

879

1963

345 15666 51.64

874

16636

1934 14.17 41.92 7.61

1Q58

1550 S78 4.23

1934 20587

2357 3310

7.22 S51 1.18 2997 1324 1088

1965

6CB 14.06 544

4QX

586 509 1683

17.21 12926

39.14 41.48

71.28 893 Q92 1931 3808 2847

3Q91 1.97 2035 1019 22002

1965

1.49 2677 670

4022

14.00 823 17.25 124.00

8804

2516 7.51

5016 9.41 Q3S 2386 3910 1942

6Q46 14.49 7.50 369 249.69

1987

401

5303

37.00 1836 526 10284

2884

342 925

1969

241 29.54 537 179.82

3201 3880 626 144.65

1303

1836 7.11

4848 594 307 1Q63 2629 1Q45

17.55 3246 2527 Q85

1999

359 3Q14 332

1Q77

14.52 2558 1517

6591

20.39

1312

1941 319 Q72 1681 2485 282

8889 4923 1598 54.06

1990

1.57

14.56 402

3373

7.99 39.61 4.56

9329

890

1023

1981

242 2989 357

1831

5878 1282 1245 33270

1Q17

344

2816 1.59 027 2927 1Q17 390

1982

219

51.62 29.17

425

3563 1.44 Q71 3604 2204 990 10546 971 2269 1279

1853 357

2589 2329 1.17 1551 3652 1Q92 2529 2231 3889 20B 154.46

1824 Q99 Q85 1801 37.89 277 72283 19.63 27.18 1275 3559 27.07 576 17.71

17.80 271

44.48 610 4.27

1993

3336 Q27

2015 1690 514 114.86

1S56

523

2524 7.66 Q24 2358 1984 7.17

4233 317 14.92 2877

1994

1518

1887 11.20 1561

4673

11.80

4.76

675 Q05 3354 S32 641

1073 2421 333 3322

2508

2571

11.36

597

1995

7.63

1996

529 9.3B

571 27.06 4.34 263

531

646

1997

691

11.61

1993

1.82

f*m

7.32

5923 042

7.47 5670 983

5039

64.54

39.22 17.50 9.65

94.91

44.42

4949 1582

41.11 1004 Q83 2548 17.93 1Q15

89.59 15.14 1550 1571 15267

137

Chapter 4 Data Analysis: LD countries Tabe49 Ovisia price variances in 23 LD countries ( x 10000)

I I I II (1)

(2)

(3)

(4)

(5)

(6)

(7)

(8)

a

(10)

(11)

(12)

(13)

(14)

(15)

(16)

(17)

(18)

(19)

1951

067

1932

237

(20)

(21)

1953

203

1934

281 0.45 088

1.51

1966

227 1.09 319

1.35

1.32

1936

663 380 1.27

14.81

1967

4.45 7.04 1.14

1501

1968

4.48 120 338

558

1969

1.72 422 567

850

1970

1.76 251 380

2840

1971

19.06

3529

372

387

633 4.05 937

1.91

1972

028

4630

24.38

Q78

1.80 591 269

567

1973 2217

(22)

1088

8545

1508

4.93

2S99 4833 34.70

1508

986

1245

0.62

2673

1583

1681

24.37 1961 7.68

6377

1975 14.18

3000

0.78

2237

27.77

17.09 17.51 94.44

508

098 9.09 29.43

5950 876

1976 1093

7.08

024

860

2044

11.91 2063 2095

384

390 7.01 34.80

41.67 821

1977 17.17

653

0.55

1040

3682 117.10 1570 985

10.44

066 1.84 4.11

4338 688 282

3928

075 1.48 250

3312 4.55 361

201

1974

1978 3263

1282

1577 1.00

225

1979 1540

646

3967 1295

41.51

1960 1Q01

666 117.11 022 16010

555

9678 852 14.21

314

107.10 2505 1630 1Q41

542

1867 1.66 1387 10080 10.48 21.78

9.60

4247 1952 5959

5218

14.33 1963 1723 11814 2660 74.69

29.76

1211 34215

1981

261 11.84

2363

3092 Q80

630

353

204.90 2021 11.38 2546

870

341 1822 1317

29.69 1640 31.68

1982

4.41 324

335

6836 0.77

7.64

511

13519

1504 5240 67.23

1882

617 1507 263

6593 214 4.57

4.70

1983

549 a 96 18802

24.06

4.31

7.98

34.49

44.40 37.92 4.C6

3656

4.62 846 5283

3669 241 526

34.71

21.31

1984 1876 4.05

9594

618

677

4.67 520 277

71.60

2831 593 14.81

2218 385 205 420 211

17.35 695 1235

6583

1965

S97 270

5596

2684

a 33

819 1996 1285 107.72

2570 11.63 1672

691 394 7.29 4.44 2893

2690 638 14.04

11.99 5688

1966

802 540

2323

9987

11.35

1987 1268 1.43

3209

2510

4.88

1013 1.92 6Q73

1248

1938 11.31 1.95

2837 10360

501

61.02 9.14 97.78

1989 1370 264

3847

4015

7.87

19S0 2274 1.80

663

21.06

613

1565 11.37 2514 4Q72

9.45 570

1.20

1602

1991 2217

acs

1992

872 568

14.79

1993

376

1698

1994

084

11.36 697 672 353 607

833 322 605

362 29.97

67.24 076 366 388 4.03

1303 202 242

2899 4267

7.71

580 1.58 310 50980 536 608 1072 625

3804 385 390

17.88

10.96 SOS 31.04 3313

501 1211 12073 9.42 1349 387 7.59

646

1.62 333

4534 4.01

19.30

276 21.68

579 2515 1385 543 1362

64.95 665 258

17.09

367

14.16 263 4519

571

239 17.37

1250 855 9.18 329 2391

6919 543 4.39

4397

4.47

11.41 236 24.99

1552

095 667 27a06 563 7.37 4.49 464

5501 4.09 7.91

627

11.41

1237 830 5886

1851

7.88

287.59 333 884 11.27 7.06

7.3B 379 600

3044

459 8832 14287

233

2934 456

127 208

2356 0.39 521

4.64

1.94

3286

227

301

1.19

1997

3054

2065 1298 374 549 252 901.41 295 644

17.09

1996

Man 1360 4.46

61.38 361 690 16940

11.24 40323 11.08 3892

656

1995

4.91 11.43 6214 67.30 44.16 429 1537

21.96

5061 7.49 4573

6Q93

3575 11.71 2226

5588 7.52 7.16 758 1023

8650 863 11.72

3214 2877

138

International Consumption Comparisons Table 410 Divisia price-quantity correlations in 23 LD countries

Year (1)

o (2)

o (3)

i

i

(4)

i (5)

u

. (6)

i

i

(7)

i

£

(6)

£ (9)

«

-

(10)

? (11)

^

5

(12)

5 (13)

Q

.

(14)

Q (15)

.

c (16)

o

t

(17)

o (18)

o

) (19)

1961

0.18

1962

-0.56

K (20)

!

| (21)

1963

-0.76

0.77

1964

0.07 -0.41 -0.37

-0.44

1965

-0.13 -0.19 -0.79

-0.29

1963

-0.03 -0.71 -0.20

-0.51

1967

-0.14 -0.48 -0.28

-0.08

1968

-0.75 -0.71 -0.44

-0.42

1969

-0.44

0.38 -0.30

0.26

1970

-0.02

0.10 -0.65

-0.32

1971

-0.95

0.39

0.67

-0.06

-0.65 -0.27 -0.67

-056

1972

-0.42 -0.07

0.12

0.86

-0.53

-0.82

-0.17 -0.50

-0.08

-0.70

-0.55 -0.59 -0.04

-0.51

-0.80 -0.67

-0.44

-0.16

0.00 -0.63 -0.43

-0.82

0.63 -0.02

-

> (22)

i

v

(23)

l (24)

1973

-0.20

1974

-0.44

0.08

1975

0.34

-0.48

-0.89

0,61

-0.48 -0.47 -0.56 -0.03

1976

-0.3B

-0.05

-0.54

035

-0.21 -0.31 -0.62 -0.59 -0.23

-0.48 -0.33 -093 -0.50

0.64

-051

1977

-0.82

-0.21

-091 -0.73

-0.09 -0.93 -0.36 -0.26 -0.45

-0.52 -0.54 -0.02

0.01 -0.57

-0.92

0.23 -0.58 -0.72 -0.13 -046

-Q24

0.10

-0.58 -0.18 -0.63 -0.44 -0.51 0.25

1978

-0.09

0.39 -0.80 -Q99 -0.03

-0.03 -0.91 -0.69 -0.20 -010

-0.32

1979

-058

-0.78 -0.65 -1.00 -0.47

-0.49 -0.42 -0.17 -0.30

0.76

-0.85 -0.13 -0.58 -0.36

0.65 -0.55

-0.56

1980

-0.03

0.37 -0.89 -0.82 -0.61

-0.50 -0.80

0.10 -0.59 -0.25

0.47 -0.54 -0.13 -0.11

0.05

-0.42

0.74

1981

0.11 -0.62

0 2 2 -0.92 -0.98 -0.02

0.09

-0.60 -0.56 -0.28 -0.24 -0.74

-0.18 -0.69 -0.78 -0.35 -0.40 -0.66

-Q60

1982

-0.63 -0.06 -0.51 -0.69 -0.99 -0.05

-0.26

-0.92

-0.17 -0.65 -0.39 -0.63 -0.29

0.16

-0.68

1983

-0.43

0 3 0 -0.51 -0.82

-0.48

-0.38

0 4 6 -0.45

-0.78

1984

-0.76

0 2 2 -0.58 -0.69

-0.24 -0.80 -0.46

0.66

-0.40

1985

-0.58

0 2 3 -0.04 -0.92

0.22 -0.09 -0.33 -0.45 -0.78 -0.74 -0.45 -0.41 -040

0.05 -0.89

0.17 -0.27 -037 -0.64

-0.61 -0.27

0.15

0.08 -0.55

1986

-0.19 -0.31

1987

-0.07

1963

-006 -0.30 -0.56

0.71

-0.62 -0.08 -0.45 -0.72 -0.14 -0.46 -0.03 -0.80

1989

-0.78 -0.48 -035

0.40

-0.34 -0.39 -0.42 -0.62

0 4 0 -0.14 -0.63

-0.78 -0.71 -0.31 -0.48

0.24 -0.87 -0.43 -0.06 -0.63 -0.41 -0.67 -0.22 -0.04

Q26 -0.45

0.36 -0.63 -0.32 -0.88 0.64

0.48

0.18 -0.24 -0.77 -0.04

0.57 -0.47 -0.45 -0.45 -Q35 -0.73

0.11 -0.60 -0.49 -0.76 -072

0.43 -0.46

-0.49 -0.95 -0.06 -0.71 -0.32

0.32 -0.24 -0.37 -0.80

0.46

0.31 -0.70 -0.42 -0.70 -0.81

Q37 -0.70 -0.71

0.15 -0.65 -0.77 -0.24 -0.46

0.40

-0.29 -0.55 -0.58 -0.36 -0.44

0.59 -0.20 -0.44 -057 -0.35

0.14

0.62

0.43

0.09 -0.67 -0.30 -0.35 -Q04

1990

0.08

0 6 2 -0.25 -0.58

-0.14 -0.43

0.10 -0.18 -0.51

-0.19 -0.11 -0.49 -0.60 -0.77 -0.26 -0.24 -0.99

1991

0.CE

0.32 -0.50 -0.82

-0.81 -0.13

0.39 -0.52 -0.48

0.33 -0.87

1992

0.00

Q41 -0.56

-0.33 -0.35 -0.03 -0.75 -0.46

0.84 -0.21 -0.39 -0.60 -0.89

0.60 -0.78 -0.88 -0.56 -0.79

0 3 5 -0.57 -0.43 -0.76 -0.40

0.23 -0.42 -0.36 -0.57 -0.73

0.86 -0.47 -0.87 -0.23

1993

-0.40

1994

Q17

1995

0.39

-0.31 -0.32 -0.67 0.01 -0.75 0.07

-0.63

0.13 -0.09 -0.41

0.02 -0.33 -0.90 -011 -0.40 -0.44

-0.75 -0.41

007

-0.19

-0.10

1997

0.44

0.40

1998

-0.27

Maai

-0.27

0.01

0.07 -0.19

0.31 -0.50 -0.83 -0.09 -0.36 -0.03 -0.24 -0.50 -0.74

0.75

1996

0.41 -0.89 -0.22

0.15 -0.64 -0.57

0.06 -0.66

-0.53 -038

0.44 -0.05 -0.69

051

Q03 -0.20 -0.59 -0.79 -0.17 -Q42 -0.20 -0.48 -0.33 -0.46 -0.08 -0.39 -0.20 -0.52 -0.41 -0.15 -0.42 -0.38 -0.15 -0.31 -Q16 -0.49

Chapter 4 Data Analysis: LD countries

139

Quantity standard deviation vs price standard deviation in 23 LD countries Figure 4.1

quantity correlation, respectively, for each country. The last row of the table gives the grand mean, over all sample periods and over all countries. As can be seen, on average, consumption in the LD countries grew at a rate of 2.1 percent per annum, while prices grew at a rate of 13.5 percent per annum. Also, at sample means, the Divisia quantity variance exceeds the price variance. The average price-quantity correlation for the LD countries is -.3.

International Consumption Comparisons

140

Table 4.11 Divisia moments in 23 LD countries

Country

Divisia quantity index

Divisia price index

Divisia quantity variance

Divisia price variance

Divisia price-quantity correlation

DQ (2) 1.64

DP (3)

K (4)

n

(1) 1. Colombia

(5)

P (6)

22.04

7.47

13.60

2. Cyprus

5.30

4.92

56.70

4.46

0.03

3. Ecuador

1.46

26.66

9.83

30.54

-0.20

-0.04

7.31

50.39

45.34

-0.59

0.78

7.65

64.55

4.01

-0.79

4. Fiji 5. Honduras

-0.28

6. Hong Kong

5.13

7.92

39.22

21.96

-0.17

7. Hungary

0.04

15.57

17.50

50.61

-0.42

8. India

2.06

8.11

9.65

7.49

-0.20

9. Iran

0.43

19.29

94.91

45.73

-0.48

10. Israel

3.22

42.05

44.42

60.93

-0.33

11. Jamaica

-0.17

14.62

49.49

35.75

-0.46

12. Korea

5.86

9.49

15.82

11.71

-0.08

13. Malta

4.65

3.72

41.11

22.27

-0.39

14. Mexico

1.10

28.72

10.04

56.88

-0.20

15. Philippines

0.69

11.67

0.83

7.52

-0.52

16. Puerto Rico

2.74

4.22

25.48

7.16

-0.41

17. Singapore

4.34

3.03

17.98

7.58

-0.15

18. South Africa

0.77

9.23

10.15

10.23

-0.43

19. Sri Lanka

1.57

11.54

89.59

86.50

-0.38

20. Taiwan

6.15

5.13

15.14

8.63

-0.15

21. Thailand

4.79

5.60

15.50

11.72

-0.31

22. Venezuela

-0.11

30.91

16.71

32.14

-0.16

23. Zimbabwe

-4.25

11.66

152.67

28.77

-0.49

2.09

13.52

37.18

26.59

-0.33

Mean

Columns 2 and 3 are to be divided by 100, and columns 3 and 4 are to be divided by 10000.

Chapter 4 Data Analysis: LD countries

141

Tables 4.12 and 4.13 present the mean relative quantity log-changes ( Dqi - DQ ) and the mean relative price log-changes ( Dpt - DP ) for the 9 commodity groups for the 23 LD countries. The last row, of both tables, presents the average for each commodity group over the 23 countries. The per capita consumption growth in food and clothing are negative in most LD countries. As can be seen from the last row of the two tables, for most commodities, on average, the relative prices and the relative consumption have opposite signs. Table 4.14 presents a summary frequency distribution (in percentages) of joint signs of relative consumption and relative prices for the LDC data. The entries in the first quadrant of the table are the percentages of the total number of observations having a simultaneous increase in relative prices and consumption, disaggregated by commodity and country. The entries in the other quadrants have a similar interpretation. For example, for food in Colombia, relative prices and consumption move in the same direction for 5 + 30 = 35% of the time, while they move in the opposite directions 35 + 30 = 65% of the time. As can be seen, from the "all countries" rows and the "all goods" columns, overall, 31 + 3 1 = 62% of the pairs of relative prices and consumption have opposite signs, while 17 + 21 = 38% have the same sign. These results clearly support the law of demand, i.e. other things being equal, an increase in the relative price of a commodity causes its consumption to fall. Table 4.15 presents the summary results from Table 4.14.

4.3

Engel's Law

In this section, we investigate one of the most important empirical regularities in consumption economics, the Engel's law, that the budget share for food (wFt)

International Consumption Comparisons

142

Table 4.12 Relative quantity log-changes of 9 commodities

Durables

Medical

Transport

Recreation

Education

(6) -0.17

(7) 1.12

(8) 0.05

(9) -0.39

(10)

0.10

(5) -0.02

0.76

0.64

4.44

-1.93

1.20

5.52

2.01

0.46

0.72

-0.89

0.10

2.71

-0.69

-0.24

-1.10

-1.46

2.87

5. Honduras

-0.53

-3.81

2.84

0.49 1.44

-0.20

-1.35

1.02

6. Hong Kong

-2.98

0.46

0.72

3.87

1.11

-0.19

0.97

7. Hungary

-1.11

-4.34

2.16

-0.55

-1.21

3.98

1.72

8. India

-1.09

0.29

-0.75

2.61

-2.38

4.67

3.99

9. Iran

-1.63

-1.34

3.13

-1.66

2.18

-2.39

2.96

10. Israel

-1.35

1.48

-0.85

2.47

1.01

2.21

0.55

-2.67

-0.67

11. Jamaica

-1.31

0.37

1.91

-0.53

3.40

1.15

3.18

-2.50

0.27

12. Korea

-2.45

-3.08

-0.96

2.67

4.96

4.30

1.93

2.09

13. Malta

-1.14

-0.40

0.64

-0.31

-0.96

-0.47

0.43

3.53

14. Mexico

-0.04

-2.10

0.88

0.01

1.05

0.80

-0.27

15. Philippines

0.06

-0.31

0.98

0.00

16. Puerto Rico

-2.96

1.03

0.30

0.38

1.61

1.08

2.01

2.28

17. Singapore

-2.78

-0.96

0.86

-0.98

0.96

0.85

3.39

1.16

18. South Africa

-0.37

1.02

-0.35

-0.35

0.71

0.64

0.42

-0.47

19. Sri Lanka

-0.89

2.64

0.51

-0.33

-2.50

5.06

2.71

-1.36

20. Taiwan

-2.16

2.02

0.79

2.02

1.79

5.78

2.11

0.01

21. Thailand

-2.25

0.80

-1.61

3.27

3.06

2.88

0.62

1.70

22. Venezuela

0.51

-2.06

0.39

0.26

3.22

-0.33

1.78

-0.78

23. Zimbabwe

-2.94

-1.79

2.05

3.26

4.17

-11.05

4.75

1.71

Mean

-1.35

-0.53

0.61

0.77

1.13

0.98

1.64

Clothing

(4)

Food

Housing

Miscellaneous

in 23 LD countries (x 100)

1. Colombia

(2) -0.26

(3) -1.77

2. Cyprus

-1.32

-0.59

3. Ecuador

-1.42

4. Fiji

Country

(D

0.78 1.05

-1.05

0.08 3.06 -5.09

1.43 1.58

0.14

3.36 -1.39

0.14

0.23

-0.47

-0.83

0.92

143

Chapter 4 Data Analysis: LD countries Table 4.13 Relative price log-changes of 9 commodities

Country

Food

Clothing

Housing

Durables

Medical

Transport

Recreation

Education

Miscellaneous

in 23 LD countries (x 100)

(1) 1. Colombia

(2) -0.48

(3) -1.47

(4) -1.25

(5) -0.41

(6) 0.57

(7) 1.43

(8) -0.94

(9) 0.32

(10)

2. Cyprus

0.46

0.67

-1.14

-0.73

1.34

-1.01

0.02

-0.87

0.94

3. Ecuador

0.87

-0.81

-3.49

0.45

0.16

-0.47

4. Fiji

0.08

1.58

0.66

-1.01

2.60

-1.86

0.13

1.34

5. Honduras

-0.36

0.15

0.57

0.45

0.25

0.48

-1.53

1.87

6. Hong Kong

-0.47

0.96

0.39

-2.54

-0.28

0.40

-0.17

-0.49

-0.50

1.12

-2.73

7. Hungary 8. India

-1.48

0.10

4.03

-1.34

9.87

0.34

-0.21

-1.54

-0.71

0.33

1.45 -0.03

3.65

1.46

0.95

-0.89

1.36

0.63

1.72

-2.26

1.40

-0.16

2.72

2.66

-0.02

-3.30

1.89

-3.31

1.18

-0.83

0.67

4.79

0.90

0.82

0.29

-1.42

0.23

0.18

-0.95

-7.45

-0.97

0.62

12. Korea

-0.67

-0.74

3.28

-1.37

-1.15

-1.59

1.64

13. Malta

0.08

-2.44

-2.07

-0.86

-0.07

1.61

-0.38

1.68

14. Mexico

-1.35

-1.70

-0.42

-1.33

0.13

2.05

1.23

2.66

15. Philippines

-0.29

-0.63

0.31

0.52

16. Puerto Rico

1.23

-2.27

0.18

-1.36

-1.26

-0.05

-0.09

-1.00

0.57

0.49

0.83

0.89

-1.64

-0.12

0.47

-1.89

-0.06

-1.08

0.97

0.60

-0.14

0.19

19. Sri Lanka

-0.14

-1.75

-1.72

3.02

4.14

-0.95

-2.18

2.92

20. Taiwan

-0.11

-2.30

-0.13

0.02

-0.23

0.02

1.12

0.30

21. Thailand

-1.08

1.41

0.74

0.36

-0.07

0.58

0.27

1.53

-4.01

-5.12

2.23

-1.14

1.89

-2.69

1.01

23. Zimbabwe

1.43 1.47

0.23

-1.52

-1.27

-0.72

3.49

-1.03

-1.24

Mean

0.06

-0.76

-0.41

-0.35

0.91

0.30

-0.71

9. Iran 10. Israel 11. Jamaica

17. Singapore 18. South Africa

22. Venezuela

0.09

1.98

-1.78 1.33

-0.43

1.16

1.31

0.92

International Consumption Comparisons

144

Table 4.14 Frequency distributions of relative consumption and relative prices of 9 commodities in 23 LP countries (percentages) Positive relative consumpti

ton

Negative relativei consumption w

8

1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23.

Country

1

O

(1)

(2)

(3)

Colombia Cyprus Ecuador Fiji Honduras Hong Kong Hungary India Iran Israel Jamaica Korea Malta Mexico Philippines Puerto Rico Singapore South Africa Sri Lanka Taiwan Thailand Venezuela Zimbabwe

All countries

1. 2 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23.

Colombia Cyprus Ecuador Fiji Honduras Hong Kong Hungary India Iran Israel Jamaica Korea Malta Mexico Philippines Puerto Rico Singapore South Africa Sri Lanka Taiwan Thailand Venezuela Zimbabwe

All countries

1I

<•>

(5)

I I (6)

I (7)

5 7 40 7 42 8 9 53 25 8 21 0 11 14 17 26 13 20 14 0 11 18 8

25 14 10 7 50 40 27 20 17 20 21 27 11 25 17 13 16 11 10 14 16 18 0

5 14 5 29 0 4 9 7 25 4 14 5 16 7 8 6 16 11 0 0 0 18 8

25 14 35 29 8 16 18 20 0 16 29 27 11 18 8 13 6 17 29 20 21 9 17

29 19 14 29 14 5 27 25

30 7 15 21 33 40 9 40 17 28 7 18 16 25 0 26 38 20 10 40 21 45 0

16

19

9

18

16

22

30 21 0 7 8 16 9 7 25 12 14 18 11 21

35 14 15 43 42 16 55 13 33 12 29 9 16 14 42 19 13 17 24 0 21 27 25

40 14 45 36 33 48 27 33 33 48 29 41 58 46 42 65 41 57 43 80 11 18 50

15 29 40 21 8 4 27 7 42 16 29 0 53 25 33 26 6 26 33 6 0 18 42

40 29 40 36 33 40 55 40 50 68 21 68 47 39 17 58 16 54 33 43 53 36 17

19 16 17 29 26 21 27 25

30 57 25 36 50 32 55 20 25 44 43 32 32 43 58 42 25 37 29 57 58 18 42

23

41

22

41

24

39

40 7 30 36 33 16 36 7 33 16 29 18 26 29

§

1 1 8

() 20 0 14 0 12 18 7 0 20 0 0 21 29

.S

1

Ul (9) 20 43

0 13 20 7

10 13 17 14 6 11 9 25 12

25 14 36 50 24 27 47 33 40 86 14 32 29

17

25 43

12 20 16 50

48 53 26 29 26 32 45 33 36

C

28

i

£

1

1

I

5 79 20 21 8 36 27 7 25 12 14 23 37 39 33 16 31 40 14 43 11 45 17

18 22 18 17 19 19 16 19 17 16 14 15 16 22 14 17 19 19 15 17 12 24 13

30 57 30 43 0 48 36 7 33 36 21 27 37 21 33 48 31 34 38 51 21 45 50

25 57 20 43 17 12 36 20 33 8 36 18 21 14 17 6 9 11 33 0 58 9 33

25 36 30 36 42 40 27 20 17 68 21 77 21 39 33 45 44 40 38 54 53 9 33

15 14 5 7 33 4 9 20 42 12 29 0 32 18 58 10 47 17 24 14 26 45 33

20 57 45 57 42 48 45 47 25 44 36 18 37 32

26

17

34

23

37

Negative relative prices 30 30 10 20 24 7 21 14 32 30 15 25 34 29 7 14 17 17 33 0 24 28 0 20 36 0 9 9 24 27 27 27 34 25 8 17 31 44 16 24 39 29 14 36 24 64 9 14 26 36 37 11 11 29 50 14 8 33 8 25 36 6 13 16 27 47 44 34 20 32 29 20 29 31 24 14 35 43 49 6 11 26 47 16 18 26 9 55 17 50 35 17 23

31

I

.8

1

^

u. is (12) (13) (14) (15) (16) (17) (18) (19) (20) (21)

<m. Positive relt stive pric

(10)

I

27

17

48 34 49 33 31 47 9 25

30 14 25 14 17 12 18 27 50 16 29 27 53 32 25 16 25 29 24 0 16 18 58

23 9 26 24 63 37 9 25

22

38

25

31

55 21 25 14 50 52 36 67 17 12 36 18 11 29 25 23 34 23 29 40 47 55 17

20 43 20 29 25 40 18 20 8 4 21 5 11 25 17 19 31 11 14 23 0 9 33

10 14 25 0 17 20 9 40 17 28 21 45 26 18

30 36

3 31 20 10 29 26 36 25

10 21 35 29 0 16 18 13 8 12 21 23 0 0 17 16 13 14 38 3 5 18 0

19 25 31 33 6 21 36 17

32

19

21

14

22

25 50 36 33 32 36 20 67 20 7 55 21 29

14 17 32 18 27 0 20 7 32 26 14

60 7 40 36 50 28 55 20 17 44 36 45 26 39 42 39 6 23 38 11 42 27 33

29 33 28 34 29 34 33 26 35 33 27 34 31 28 35 29 26 29 32 28 38 22 36

42

33

31

25 7

15 7 10 14 25 16 9 47 33 28 14 23 11 11 17 32 16 17 19 3 37 9 0

23 21 22 15 19 24 15 31 14 20 20 28 16 20 18 17 29 21 23 20 25 28 16

18

21

30 7

SO 53 52 29

8 13 12 14

13

145

Chapter 4 Data Analysis: LD countries

Table 4.15 Frequencies of joint signs of relative consumption and relative price changes in 23 LD countries (in percentages) Positive consumption

Negative consumption

Positive price (2) 18

Negative price (3) 30

Positive price (4) 29

Negative price (5) 23

2. Cyprus

22

24

33

21

57

3. Ecuador 4. Fiji

18

32

28

22

60

17

34

34

15

68

5. Honduras

19

33

29

19

62

6. Hong Kong 7. Hungary

19

24

34

24

58

16

36

33

15

69

8. India

19

24

26

31

50

9. Iran

17

34

35

14

69

10. Israel

16

31

33

20

64

11. Jamaica

14

39

27

20

66

12. Korea

15

24

34

28

58

13. Malta

16

36

31

16

67

14. Mexico

22

29

28

20

57

15. Philippines

14

33

35

18

68

16. Puerto Rico

Country (1) 1. Colombia

Opposite signs (3)+(. (6) 59

17

36

29

17

65

17. Singapore

19

27

26

29

53

18. South Africa

19

32

29

21

61

19. Sri Lanka

15

31

32

23

63

20. Taiwan

17

35

28

20

63

21. Thailand

12

26

38

25

64

22. Venezuela

24

26

22

28

48

23. Zimbabwe

13

35

36

16

71

Mean

17

31

31

21

62

International Consumption Comparisons

146

falls with increasing income (Mt). This can be written in a linear regression framework as the Working's (1943) model (see equation (3.1) of Chapter 3), wFt = ocF + P F logM t

(3.1)

In Figure 4.2, we plot the of food budget share against the logarithmic of the per capita real consumption expenditure for the 23 LD countries. As can be seen, in all plots (except for Fiji, Hungary and Zimbabwe), the points are scattered around a negatively sloping straight line. Even though the slope for Honduras is negative, as can be seen from the plot, most of the points represent a constant budget share regardless of the income level, indicating that the published data may be unreliable. The overall conclusion of the graphs in Figure 4.2 is that Engel's law is well supported by the LDC data. Table 4.16 presents the estimates for the Working's model parameters ocF and PF for food in each country. As can be seen from column 3, for most countries, all the income coefficient estimates for food are negative and statistically significant. It can also be noted that the positive income coefficient estimates (Fiji, Hungary and Zimbabwe) are all insignificant. The cross-country average of the income coefficient for the LD countries is (3F = -.14 with a standard error of .04. Among the 23 values, Hungary can be considered as an outlier. The average income coefficient, excluding Hungary is -.17. This is very close to the average value of -.20 obtained in Table 3.16 for the OECD data and those from previous studies in Table 3.17. In Figure 4.3a, we pool the data across the 23 LD countries and plot the adjusted budget shares (wFtc - aFc) against the logarithm of income (log Mte) in one graph. However, the points corresponding to Hungary appear to be extreme among the 23 LD countries. In Figure 4.3b, we plot the same graph for 22 LD

147

Chapter 4 Data Analysis: LD countries

Cyprus

Colombia

**
*

0.4

y=-053x+25731 #=0.8176

y=--0.0399X+0.563* # =0.5811

a> Is 0.28 .e (A

"

^

^

•

? 0.26 m

0.36

• ••

nx> 9.4

9.5

6.8

9.6

7

7.2

7.4

7.6

7.8

Log(lncome)

LogQncome)

Ecuador

Fiji y=-0.197x+22256 #=0.6005

o

0.4

y=0.0502x+0.0599 #=0.0356 •

10

•S 0.38

O) "O 3 00

9.1

9.2

9.3

0.36

•

0.34 6.25

9.4

6.3

•

y=-0.1776x +1.9944 #=0.9833

y=-0219x+1.7689 #=0.4947

•

6.45

Hong Kong

Honduras 0.5

6.4

6.35 Log(lncome)

Logflntxme)

0.48 ?0.46 0.44 0.42 5.8

5.85

5.9

5.95 6 LogQncome)

6.05

6.1

9.1

9.3

9.5

9.7

9.9

10.1

10.3

10.5

LogOncome)

Food budget share against logarithm of per capita real consumption expenditure in LD countries

Figure 4.2

148

International Consumption Comparisons

India

Hungary

y=-0.1813x+2.9896 ff=0.8182

0.49 ^0.45 § 0.41 3

0.37

• ,

y=0.6231x-6.1691 rf=0.2409

** 10.54

10.68

10.62

10.66

13.4

13.5

Israel

Iran

y=-0.0988x+1.0016 Pp- 0.8461

" 0.42 Cl> OI •D

y=-0.3807x+1.3689 # = 0.7275

0.32 23

2.4

•

^ » %

2.5

S> 1

Budget shar

«

g

0.47

a 0.37

%u • ?*•

2.6

7.1

6.9

7.3

•

I

i

fe

•

*

•

6.46

7.9

6.56

r]

^ ^ » < #

y=-0£197x+3.4125 r f « 0.9514

#

•S 0.4

•

*

O 0.3 0.2

8

Budget share

*

y=-0.0734x+0,8Sj84 #=0.2001

7.7

Korea

Jamaica

•

7.5

Log(lncome)

Logglncome)

6.36

13.6

Lag(lncome)

Log(lncome)

6.66

13

Log(lncome)

13.5

14

14.5

Log(lncome)

Food budget share against logarithm of per capita real consumption expenditure in LD countries Figure 4.2 (continued)

149

Chapter 4 Data Analysis: LD countries

Mexico

Malta 0.4

1y=-0.1001x+0.6483 Fp=0.6122

y = -0.377x +1.1334

0.25

*

Pf = 0.4449 0.2

2.9

3.1

18

3.3

1.9

2

2.1

2.2

2.3

7.65

7.75

Log(lncome)

Logflncome)

Puerto Rico

Philippines 0.61

I"

y = -0.0959x+1.4513 Ff = 0.2449

•5 0.59 •

m 0.58 0.57

8.95

9

•

9.05

Log(lncome)

Singapore

South Africa

I 0.3

« 0.35

I03

y=-0.1332x+1.3428 R?=0.9376

y=-0.029x+0.5573 I f = 0.0451

0.25

7.2

7.6

8

8.4

8.8

7.25

7.35

7.45

7.55

Logflncome)

LogQncome)

Food budget share against logarithm of per capita real consumption expenditure in LD countries Figure 4.2 (continued)

International Consumption Comparisons

150

Taiwan

Sri Lanka 0.75 I

y = -0.1679x+2.2313 R2 = 0.9688

y = -0.35B8x +3.3603 ^=0.7612

0.7

I-

f" 0.55 0.57.3

7.4

7.5

7.6

7.7

7.8

10.1

7.9

10.6

Thailand

Venezuela y=-0.2877x+2.8429

/ • •

y = -0.3448x+3.6869

R ^ 0.8416

1

r

8.1

8.3

8.5

8.7

8.9

«• *

,

FT"=0.0941 * •

•

•

o

* ^ > v^*"*"<£* ^

m 0.3

11.6

0.45-1 Budget share o o o

• £ 0.5

11.1

Log(lncome)

Log(lncome)

0.3 J

9.1

9. 53

Logflncome)

9.57

9.61

9.65

Log(lncome)

Zimbabwe y = 0.0079)(+0.2903 R?=0.0029

5.4

•

5.6

5.8

Log(lncomB)

Food budget share against logarithm of per capita real consumption expenditure in LD countries Figure 4.2 (continued)

151

Chapter 4 Data Analysis: LD countries Table 4.16 Estimates of Working's model for 23 LD countries (Standard errors are in parentheses) Country

Intercept a x 1000

(D

(2)

1.

Colombia

2.

Cyprus

3. 4. 5. 6.

Ecuador Fiji Honduras Hong Kong

7. 8. 9.

Hungary India Iran

10. Israel 11. Jamaica 12. 13. 14. 15. 16.

Korea Malta Mexico Philippines Puerto Rico

17. Singapore 18. South Africa

2.573 (0.238) 0.563 (0.069) 2.226 (0.345) 0.060 (0.459) 1.769 (0.398) 1.994(0.046) -6.169 (3.706) 2.990 (0.308) 1.369 (0.175) 1.002 (0.063) 0.898 (0.266) 3.412 (0.149) 0.648 (0.057) 1.133(0.168) 1.451 (0.458) 1.290 (0.121) 1.343 0.557 3.360 2.231 2.843

(0.050) (0.172) (0.344) (0.056) (0.251)

Income coefficient P> (3) -0.230 (0.025) -0.040 (0.009) -0.197 (0.037) 0.050 (0.072) -0.219 (0.067) -0.178 (0.005) 0.623 (0.350) -0.181 (0.023) -0.381 (0.070) -0.099 -0.073 -0.220 -0.100 -0.377 -0.096 -0.142

(0.009) (0.041) (0.011) (0.019) (0.081) (0.051) (0.017)

-0.133 (0.006)

(4) 0.82 0.58 0.60 0.04 0.49 0.98 0.24 0.82 0.73 0.85 0.20 0.95 0.61 0.44 0.24 0.70 0.94

(0.023) (0.045) (0.005) (0.029)

0.84

23. Zimbabwe

3.687 (3.246) 0.290 (0.251)

-0.345 (0.338) 0.008 (0.044)

0.09 0.00

Mean

1.370 0.407

-0.138 (0.043)

0.56

19. 20. 21. 22.

Sri Lanka Taiwan Thailand Venezuela

-0.029 -0.359 -0.168 -0.288

R2

0.05 0.76 0.97

International Consumption Comparisons

152

y =-0.1482x +0.0722

I, -1 o £ -3

Log(lncome)

Food budget share vs Log(lncome) for pooled data from 23 LD countries Figure 4.3a

I 3 -3 y = -0.2155x +0.3956 -4

Log(lncome)

Adjusted food budget vs log(lncome) for pooled data from 22 LD countries (excluding Hungary) Figure 4.3b

153

Chapter 4 Data Analysis: LD Countries

countries (excluding Hungary). As can be seen, the points are scattered around a downward sloping straight line with slope |3F = -.22. This estimate is very close to the cross-country average (excluding Hungary) of (3F = -.17 discussed above.

4.4

Preliminary Estimates of Income and Price Elasticities

In this section, we use double-log demand equations to obtain preliminary estimates for the income and price elasticities for the LDC data. In Chapter 9, we use the differential demand systems, derived in Chapter 2, to obtain final estimates for the demand elasticities and then compare the two sets of estimates. We consider the double-log demand equation (2.4) given in Chapter 2 for commodity i in finite-change form Dqit = Oi + y], DQt+ydDpit-DPt]

+ek,

i=l,...,n,

(4.1)

where oc; is an autonomous trend term; r\\ is the income elasticity of commodity i; V; is the Slutsky own-price elasticity; and 6it is a disturbance term. It is worth noting that this double-log demand equation includes only the ownrelative price and not other prices. We estimate (4.1) by least squares (LS) for each country separately. Tables 4.17 and 4.18 present the estimates for the income elasticity (r|j) and own-price elasticity (y,), respectively, for each commodity for the 23 LD countries. The last row of the table presents the mean elasticities for each commodity averaged over the 23 countries. As can be seen from Table 4.17, all the income elasticites are positive. The elasticities in column 2 for food in all countries (except for Philippines and

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Chapter 4 Data Analysis: LD Countries

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156

International Consumption Comparisons

Zimbabwe) are less than one indicating that food is a necessity in the remaining 21 LD countries. The average value of the income elasticity for food in the LDC is .7. On average, the income elasticities for clothing, durables, transport, recreation and education are larger than one indicating that these commodities are luxuries in the LD countries, while the income elasticities for housing and medical care are less than one indicating that they are necessities. This result is in line with the known phenomenon that consumers in poor countries tend to spend most of their income on life's necessities for survival, food, shelter and health care. In Table 4.18, most of the own-price elasticities (170 out of 187) are negative as they should be. On average, all the price elasticities are negative and less than one in absolute value, indicating that demand for all 9 commodities in the LD countries are price inelastic.

4.5 Preliminary Estimates of the Income Flexibility In this section, we present five sets of estimates for the income flexibility. In Section 3.5, we derived the first four sets of estimates and presented the estimates for the OECD data. In Table 4.19, we present the estimates for the LDC data. The first set of estimates is based on the regression results from equation (5.2) of Chapter 3. For each country, we obtain the estimates of (> | for i=l,..,«, and calculate the average <j>, which we refer to as an unrestricted average estimate of the income flexibility. These estimates (<j)) for the 23 countries are reported in column 2 of Table 4.19. Figure 4.4 presents the plots for the pooled data for (Dqit - DQt) against (Dpit - DPt), t=l,...,T and i=l,...,n for each LD country. As can be

Chapter 4 Data Analysis: LD Countries

157

Table 4.19 Four sets of estimates for income flexibility in 23 LD countries (x100) Income flexibility Country (1) 1. Colombia 2. Cyprus 3. Ecuador 4. Fiji 5. Honduras 6. Hong Kong 7. Hungary 8. India 9. Iran 10. Israel 11. Jamaica 12. Korea 13. Malta 14. Mexico 15. Philippines 16. Puerto Rico 17. Singapore 18. South Africa 19. Sri Lanka 20. Taiwan 21. Thailand 22. Venezuela 23. Zimbabwe Mean

Unrestricted

Restricted

Divisia

Divisia Average

(2) -0.33

(3) -0.27

-0.59 -0.19 -0.59 -1.92

-0.88 -0.16 -0.68

(4) -0.25 -0.04 -0.13 -0.64

(5) -0.21 0.11 -0.11

-0.63 -0.33

-0.86 -0.44

-0.11

-0.51

-0.25

-0.43 -1.00 -0.41 -0.97 -0.22 -0.40 -0.10 -0.12 -0.65

-0.25 -0.67

-0.23 -0.69 -0.28 -0.54 -0.09

-0.23 -0.28 -0.17 -0.73 -0.38 -0.85 -0.22 -0.59 -0.14 -0.16 -0.66 -0.26 -0.51 -0.63

-0.25 -0.46 -0.65 -0.27

-0.29 -0.30 -0.23 -0.78

-0.29 -0.23 -1.32

-0.48

-0.38

-0.30 -0.54 -0.04 -0.69 -0.07 -0.22 -0.96 -0.20 -0.50 -0.44 -0.32 -0.60

-0.62 -3.17 -0.23

-0.53 -0.08 -0.17 -0.77 -0.23 -0.43 -0.39 -0.20 -0.36 -0.12

-0.23 -1.24

-1.13

-0.44

-0.47

International Consumption Comparisons

158

Colombia i

Cyprus |

ge-i

6^n

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-15 • -10 •

**SJ JO

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10

t •

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4

•

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F*^"*"^

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0

J*

«

g^j Relative price

Ecuador

•

6

•

Relative price

1

"

-201

*

y = -0.8835x+1.1599

•

y =-0.2712x- 0.085

•

•

•

0

40

* ^ • * * ' Til

-20

-40H

y=-0.6766x+0.1611 Relative price

Relative price

Hong Kong

Honduras -88-

•£ -:o -40 y=-0.6273x +0.4572

y = -0.3341x+0.159

8S-

-39Relative price

Relative price

Relative quantity against relative price in LD countries Figure 4.4

•

i J •

'

}

159

Chapter 4 Data Analysis: LD Countries

India

Hungary

y = -0.4Z76x+1.046

Relative price

Israel

Iran y=-1.0048x + 0.84

!)

Rel itive quant ty

30

y=-0.4076x + 0.3315

• •

^

« V»

-40

»' "JtlBt* 3 i i B K A *40'

^•w*Jk 0

•

ii. 60

n

-20

» Relative price

Relative price

Korea

Jamaica

a&_ • *

0

-10 •

•

15«k*\

K$~

JW

-%-

•

•

y = -0.2229x+1.1942 4 asRelative price

Relative price

Relative quantity against relative price in LD countries Figure 4.4 (continued)

:3

160

International Consumption Comparisons

Mexico

Malta _

30y=-0.1031x+0.0759

quaritity

4

•

a> | - 0

- m

*

"i ' ^ M i i 1 * -20 # • ^ » 5 * > 20

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11 ** ' D

•-10'

CC

39Relative price

Relative price

Puerto Rico

Philippines y = -0.1221x+0.0709

Relative price

Relative price

South Africa

Singapore

y = -0.463x+0.1032

•

2*

-8

•

*-4^BP

fry ?_ wrst/*-

2

Relat ve quant ty

Relative quantity

y=-0.253x+0.3116 20*

•

so l 20-

• ^ ^ 1 * * ' 5

-15

•J

Relative price

Relative price

Relative quantity against relative price in LD countries Figure 4.4 (cont.)

*

l . C T ' V ^

!5

161

Chapter 4 Data Analysis: LD Countries

Taiwan

Sri Lanka

46 y=-ft2742x+!5009

y=-0.$485x+1.0031

30

•40-

5 -!0

-25 is

:5

Relative price

Venezuela

Thailand .

2S_

•

Rekitive quantity

y=-0.2S05x+1.1942 20-

A •

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0

- * < ^ -10-

•

5

w

-17

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-20 y=-0.2274x+0.1909 • 89Relative price

Relative price

Zimbabwe y=-1.3186x-0.0758

SS

-BBRelative price

Relative quantity against relative price in LD countries Figure 4.4 (continued)

••

• :

4 •

International Consumption Comparisons

162

seen from the plots, the points are scattered around a negatively sloping line. The slope of the regression lines can also be interpreted as (|). These restricted estimates of <)| for each country are presented in column 3 of Table 4.19. Even though the values of the estimates given in columns 2 and 3 vary widely, all these values have the correct (negative) sign. The overall average value of the income flexibility estimate is about -.5 (column 2) and -.4 (column 3), which agrees with the income flexibility estimates found in most of previous empirical studies. Another method of obtaining an estimate for <>| is using the relationship (5.5) of Chapter 3,

* = v Column 4 of Table 4.19 gives the value of these (J) values averaged over t=l,...,T for each country. The income flexibilities are all negative with an average of -0.44. The last set of estimates for the income flexibility <() are calculated using the relationship derived in equation (5.6) of Chapter 3,

•

.

I. n

Column 5 of Table 4.19 gives these (j) values for each country. As expected, all the estimates of (j> (except for Cyprus) are negative. Apart from Honduras and Zimbabwe, the income flexibilities are close to the average value of -.47. The average values of the four sets of estimates presented in the last row of Table 4.19 are consistent with the OECD results in Section 3.5 and previous findings.

163

Chapter 4 Data Analysis: LD Countries

Clothing

Food

>

*

•

• °

-1

•

•_,

•

• i

#

1

2-

• •

—

•

•

• (f

>

•

-t-

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•

*

• »

•

y=-0.2257x-0.7022 6Relative Price

Housing •

Durables 4-

•

s

3- •

*

* 2 -

r*T^f*i« r 0

•

**~ -2 • • -4- •

••

• -3»y = -0.1357x-1.3443 Relative Price

-5

»•

• ^ '

y = -0.1042x +0.5708

'•

•

•

•

a

Relative consum

Relative consumption

. •

y =-0.5221 x + 0.5876

4*

»

3-

> • • t

-2 •

^

"^•^

•

. , ] . %

^

"

•

Relative price

Realtive price

Medical care

Transport

Relative price

Relative price

Relative consumption vs relative prices for 9 commodity groups Figure 4.5

^

•

International Consumption Comparisons

164 Recreation

Education •

8 |

*

y=J0.9492x+0.4134 4-

-4•

.^*»>«.' • •

1

_aJ Relative price

;

; — : — i —

Relative price

Miscellaneous

* •

y=*^.i952x+1.0968

3

•V".

2<

« •

i*

•

4*

»

•

2

3 •

Relative price

Relative consumption vs relative price for 9 commodity groups Figure 4.5 (continued)

Next, for each commodity i (=1,...,9), we plot the relative consumption (Dq[ -DQC) against the relative price (Dp- -DPC), c=l,...,23, using the relative consumption and relative price values from Tables 4.12 and 4.13. Figure 4.5 gives the plots for the 9 commodity groups. The resulting slope of the regression line is an estimate for <> | . As can be seen, in all plots, all the points are scattered around a downward sloping straight line. In Table 4.20, we present

165

Chapter 4 Data Analysis: LD Countries

Table 4.20 Another set of estimates of $ for the LD countries Commodity 1. 2. 3. 4. 5. 6. 7. 8. 9.

Food Clothing Housing Durables Medical care Transport Recreation Education Miscellaneous

Mean

Income flexibility -.14 -.23 -.10 -.52 -.46 -1.39 -.27 -.95 -.20 -.47

the resulting estimate of <> | for each commodity group. As can be seen, the overall average for the 9 commodity groups is

4.6

Testing the Frisch 's Conjecture

In Section 3.6, we used the data from the affluent countries, like the OECD countries, to test the validity of Frisch's conjecture. In this section, we use data from the poorer countries, like the LDC, to verify whether Frisch's conjecture is supported by the data. In a nutshell, Frisch (1959) states that the income flexibility (> | increases in absolute values as the consumer (or country) becomes more affluent.

International Consumption Comparisons

166

As in Section 3.6, we use the estimates of <>| presented in Table 4.20 together with the real GDP per capita (in US dollars) presented in Table 1.2. We estimate a relationship of the form, df

=

X + \iyc + ec,

where A, and n are parameters to be estimated; the superscript c denotes country c; yc is per capita real GDP (in international dollars) of country c; and ec is an independent disturbance term with zero mean. The F-test statistic value for the null hypothesis that, H0: u, = 0 and the corresponding p-value with respect to columns 2-5 of Table 4.19 are (F = 2.34; p-value = .14), (F = .64; p-value = .43), (F = 1.33; p-value = 0.26) and (F = 2.75; p-value = .11), respectively. As, for all columns, the level of significance a = 0.05 < p-value, we are unable to reject the null hypothesis, H<,: \i = 0. As none of the F-values are significant, we conclude thattyis independent of real income. The finding that <j) is unrelated to real income is, of course, at variance with Frisch's (1959) conjecture. However, our rejection of Frisch's conjecture is well in agreement with a number of previous studies (e.g. Clements and Theil, 1996; Selvanathan, 1993; Theil, 1980; andTheil, 1987).

4.7

The Validity of Preference Independence

In Chapter 2, we showed that the assumption of preference independence leads to an attractive simplification of demand equations and that under preference independence, own-price elasticities (riu) are proportional to income elasticities (r|i) with <j) being the factor of proportionality. In Chapter 3, we also used the OECD data to provide evidence of this proportionality relationship. In this

167

Chapter 4 Data Analysis: LD Countries

section, we use the LDC data to provide more evidence on the proportionality relationship of the two elasticities. To analyse the evidence on the proportionality relationship, r^ = (pr|i, we use the income and price elasticity estimates presented in Tables 4.17 and 4.18. Figure 4.6 plots the own-price elasticities (r|ii) against the corresponding income elasticities (r|i) and the solid line on the plot is the least-squares line. The points are scattered around a negatively sloping line and the location of the points give evidence that luxuries tend to be more price elastic. The estimate of the factor of proportionality is -.35, which is not far from the estimates of (j) presented in Table 4.19. The significance of the factor of proportionality provides indirect evidence to the preference independence hypothesis. This finding is in agreement with that for the OECD data in Section 3.7. We shall come back to formally testing the hypothesis of preference independence in Chapter 9.

y = -0.3494X

*

Price elasticity

1 •

•

.5

•

*

*

•

'

.

2S

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-2

.

• *

• • * • * . * • • • »

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•

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3 5

• * ^ ^ ~ * " ~ « .

« • • Income elasticity

Own-price elasticity against income elasticity Figure 4.6

168

International Consumption Comparisons

References Brozdin, R. (1988). 'LDC's Consumption: A Database Update,' Unpublished manuscript, Department of Economics, The University of Western Australia. Chen, D.L (2001). World Consumption Economics. Singapore, London: World Scientific. Clements, K.W., and H. Theil (1996). 'A Cross-Country Analysis of Consumption Patterns,' Chapter 7 in H. Theil (ed.), Studies in Global Economics. Advanced Studies in Theoretical and Applied Econometrics. Boston: Kluwer Academic Publishers, pp.95-108. Frisch, R. (1959). 'A Complete Scheme for Computing All Direct and Cross Demand Elasticities in a Model with Many Sectors,' Econometrica 27: 177-196. Theil, H. (1980). The System-Wide Approach to Microeconomics. Chicago: University of Chicago Press. Theil, H. (1987). The Economics of Demand Systems,' Chapter 3 in H. Theil and K.W. Clements (eds.), Applied Demand Analysis: Results from System-wide Approaches. Cambridge, MA.: Ballinger Publishing Company. Selvanathan, S. (1993). A System-wide Analysis of International Consumption Patterns. Advanced Studies in Theoretical and Applied Econometrics. Boston: Kluwer Academic Publishers. Working, H. (1943). 'Statistical Laws of Family Expenditure,' Journal of the American Statistical Association 38: 43-56.

CHAPTER 5 A Comparison of Consumption Patterns in the OECD and LD Countries E.A.. Selvanathan & S. Selvanathan

In Chapters 3 and 4, we presented preliminary data analysis of the two groups of countries, the OECD and LDC, individually. In this chapter, we present a comparison of the results. The OECD consumers are from high-income, highly industrialized countries and the LD consumers are from low-income, developing countries. Therefore, a comparison of the results from the OECD data in Chapter 3 with those from the LDC data in Chapter 4 would be able to capture the similarity and contrast in the consumption patterns among the high-income and low-income consumers of the various commodity groups. The combined data consists of 46 countries with varying income levels, the results presented in this chapter will be applicable to the consumption patterns of a typical 'world' consumer. In Section 5.1, we present various summary measures for the OECD and LD countries individually as well as all 46 countries combined representing the world consumers. In Section 5.2, we revisit the empirical regularities in consumption patterns, such as the law of demand, Engel's law, preference independence etc using the combined 'world' consumption data. Finally, in Section 5.3, we present our concluding comments.

170

5.1

International Consumption Comparisons

Summary Measures

In Table 3.3 and Table 4.3, we presented the average budget shares of the 9 commodity groups for the 23 OECD and 23 LD countries, respectively. In columns 2 and 3 of Table 5.1, we reproduce the average budget shares of the 9 commodity groups (averaged over the OECD and LD countries, respectively) and the corresponding standard deviations from the last row of Tables 3.3 and 4.3, respectively. Column 3 gives the budget shares for all 46 countries combined (we label this column as 'World'). In Figure 5.1, we present these budget shares in a bar-graph form. As can be seen, the LDC consumers allocate about one and a half times that of the allocation of OECD consumers of their income on food. This observation on food budget share supports the Engel's law discussed in Sections 3.3 and 4.3 that the budget share for food is lower for the higher income group compared to the lower income group. Furthermore, the variability of food budget share among the LD countries is almost twice that of the OECD countries, reflecting the higher variability on the food consumption patterns among the LD countries compared to the OECD countries. Both OECD and LDC consumers allocate about the same proportion of their income on clothing and durables. OECD consumers allocate more of their income on goods such as housing, medical, transport and recreation than the LDC consumers. On average, the world consumers allocate about one-third of their income on food; 8 percent of their income on clothing, 15 percent of their income on housing, 8 percent on durables, 5 percent on medical, 12 percent on transport, 7 percent on recreation, 1 percent on education and the remaining 12 percent on all other things. Comparing the standard deviations across commodities, one could observe more variability among the food budget shares than any other commodity groups.

Chapter 5 A Comparison of Consumption Patterns

171

Table 5.1

8

1

38.21 (9.65)

8.07(1.49)

8.57 (3.08)

Durables Medical Transport Recreation Education

17.21 (3.48) 8.51 (1.68) 5.00 (3.02)

12.26(5.29) 8.16(2.81) 3.94(1.57)

13.63(2.01) 7.45(1.69) 1.11 (0.88)

10.42(4.03) 5.43 (2.90)

Miscellaneous

12.44(3.00)

32 7 3 ( 9 98) 8 3 7 ( 2 42) 14 8 9 ( 5 05) 8 3 7 ( 2 29) 4 6 8 ( 2 49) 12 15(3 52) 6 5 2 ( 2 51) 1 2 7 ( 0 85) 12 15(4 77)

1.45(0.80) 11.57(6.10)

HOBCD HLDC

"O

O)

LL

IE o

o

X

o o

O)

cs o

•t?

C3

0)

CO

Z5

«>

(/) Q

o c

2?

Com rnociity

c .2 CD Q

0)

c •S

15 o

w

iscella neou

8 7

m

27.08 (5.64)

Edu

3 4 5

Food Clothing Housing

Dusin

1 2

Average budget shares ©f 9 commodities: OECD and LD countries (at sample means x 100) Country OECD countries LD countries World (!) (2)

2:

Average budget shares of 9 commodities, OECD vs LDC Figure 5.1

172

International Consumption Comparisons

Columns 2 and 3 of Table 5.2 reproduces the average consumption growth for the OECD and LDC from Tables 3.4 and 4.4. As can be seen, the consumption of food, medical care and transport grew at a faster rate in the OECD compared to the LD countries. In contrast, the consumption of clothing, durables and education grew at a slower rate in the OECD countries compared to the LD countries. The growth in consumption of housing and recreation is very similar across the OECD and LD countries. Column 4 of Table 5.2 presents the average growth in consumption for all countries. As can be seen, in all countries, on average, the consumption growth is higher for medical care, transport (which includes communications) and recreation. In columns 2 and 3 of Table 5.3 we reproduce the average growth in prices from Tables 3.5 and 4.5 for the OECD and LDC, respectively, and in column 4 we present the corresponding growth in prices for all 46 countries combined. A comparison of the price increases in columns 2 and 3 reveals that the prices for all commodity groups in the LD countries grew at a rate twice that of the OECD countries. Figures 5.2 and 5.3 present these summary statistics for the growth rates in consumption and prices, respectively, for the OECD and LD countries. In Table 5.4, we reproduce the mean Divisia measures presented in the last row of Tables 3.11 and 4.11 for the OECD and LDC, respectively, and present the corresponding values for all 46 'world' countries combined. As indicated by rows 1 and 2, while overall consumption, on average, grew at a slightly higher rate in the OECD compared to the LD countries, prices in the LD countries grew at a faster rate (almost twice) than those in the OECD countries. The overall world consumption grew at a rate of 2.2 percent per annum and the overall world prices grew at a rate of 10 percent per annum. As observed with the individual countries and over time, the Divisia quantity variance exceeds that of the price variance for OECD, LDC and the world as a whole. The Divisia price-quantity correlation is also negative for both the OECD and the LDC with

173

Chapter 5 A Comparison of Consumption Patterns Table 5.2 Average per capita quantity consumed of 9 commodities in OECD and LD countries (Mean log-changes x 100) Country 1. 2. 3. 4. 5. 6. 7. 8. 9.

(1) Food Clothing Housing Durables Medical Transport Recreation Education Miscellaneous

OECD countries (2) 1.07 1.21 2.71 2.27 3.41 3.63 3.89 2.64 2.59

LD countries (3) 0.74 1.56 2.71 2.87 3.29 3.08 3.83 2.88 2.92

World (4) 0.90 1.39 2.71 2.57 3.35 3.36 3.86 2.73 2.76

Table 5.3 Average prices of 9 commodities in OECD and LD countries (Mean log-changes x 100) Country

(D

OECD countries

LD countries

World (4) 10.00

1. 2.

Food Clothing

(2) 6.43 6.29

(3) 13.58 12.77

3. 4.

Housing Durables

7.90 6.12

13.11 13.17

5. 6. 7. 8. 9.

Medical Transport Recreation Education Miscellaneous

7.57

14.52

6.76 6.59 9.67 7.81

13.83 12.28 15.30 14.20

9.53 10.51 9.64 10.97 10.29 9.31 11.92 11.01

a world average of -.3, reflecting the tendency of the consumer to move away from those commodities having above-average price increases.

International Consumption Comparisons

S &

5

£

4

£ 3 -f ~

| 2\

-^ •»-mm™~mmt~~mm—-^—

•«-,•-. i ^ Q B D I

^ ^ » B-H-JH~m4B IK

ULDC

I 1 1 S o

~Q

O)

O)

CO

_

*

„

a. -S

Commodity

Average quantity log-changes in OECD and LD countries Figure 5.2

I OECD 1LDC

Commodity

Average price log-changes In OECD and LD countries Figure 5.3

175

Chapter 5 A Comparison of Consumption Patterns Table 5.4 Divisia moments in OECD and LD countries (at sample means) Country

Divisia quantity index

Divisia price index

Divisia quantity variance

Divisia price variance

Divisia price-quantity correlation

DQ

DP

K

n

P

(2)

(3)

(4)

(5)

(6)

1. OECD countries

2.34

6.94

12.09

10.08

-0.18

2. LD countries

2.09

13.52

37.18

26.59

-0.33

3. World

2.22

10.23

24.64

18.33

-0.26

(1)

All entries in columns 2 and 3 are to be divided by 100 and columns 4 and 5 by 10000.

5.2

Empirical Regularities

In Chapters 3 and 4, we observed a number of empirical regularities in the consumption patterns using the OECD and LDC data individually. In this section, we investigate them by combining the OECD and LDC databases, giving 46 countries of the world with varying income levels. Price and Quantity Variances

In Figure 5.4, we plot the quantity standard deviation, yJKf, against the price standard deviation,-y/n^, for t=l,...,T and c=l,...,46. As can be seen, most of the points lie above the 45° line indicating that, on average, ^Kct >-y!I(c. This shows that the Divisia quantity variances generally exceed the Divisia price variances.

176

International Consumption Comparisons

Quantity vs price standard deviations, 46 countries Figure 5.4

Law of Demand

Table 5.5 summarizes the frequency distribution of the joint signs of relative prices and consumption. Both in the OECD and LDC, relative prices and consumption move in the opposite directions about 60 percent of the time. We investigate further, the movement of relative consumption (Dqf - DQc) and relative prices (Dpf - DPc), by plotting these two variables for each commodity group across the OECD and LD countries combined. In Figure 5.5, we plot the relative consumption (Dqf - DQc) against the relative price (Dpf -DPC) for each commodity i (=1,...,9), by pooling the data from the 46 (OECD and LDC) countries. As can be seen, in all plots, the points are scattered around a negatively sloping straight line. This clearly supports the law of demand. Furthermore, the slope of the regression line in each plot can be interpreted as an estimate for the own-price elasticity of that

111

Chapter 5 A Comparison of Consumption Patterns Table 5.5 Average frequencies of joint signs of relative consumption and relative price changes in OECD and LP countries (in percentages) Country

Positive consumption

Negative consumption

Opposite signs

Positive price Negative price

Positive price Negative price

(3)+(4)

_£D

m

(3)

(4)

(5)

(6)

1. OECD countries

19

31

29

20

60

2. LD countries

17

31

31

21

62

3. World

18

31

30

21

61

Relative consumption vs relative price in 46 countries Figure 5.5

International Consumption Comparisons

178

Transport

*

y = -0.4732x + 1.4659 Pt on

Relative consumption

Medical care

•

^ ^ ^ »

(A C

• i

-2

• -2-

i

O

•2. TVe

to

«4-

^^^^^•r * «3 •f

E

-2

•

Education

1

*~

y=-G.606x + 0.9661

•

* ••

4

4 •

•' 7,

Relative consumption

•

Relative price

y = -0.2644x+1.4562

-3

• 2 * " > ^

-8 y = -1.1058x + 1.2068

Recreation

-6

•

1 •

> O

Relative price

J

•

-4-

CC

•

», |

I1

* 1

• ' ''

(I

•

•

'

2

•>

•

-4-

•

3

• nj

:

Relative price

Relative price

Miscellaneous

*

y = -0»0777x + 0.6559

•

3-

*

• 2 -,

•

• ••*%.• .5

-0.5 • «.5 *#>* 1.5 -1 -

•

• 2.5

3

n Relative price

Relative consumption vs relative price in 46 countries Figure 5.5 (continued)

». •

••

Chapter 5 A Comparison of Consumption

Patterns

179

commodity group or as an estimate of income flexibility under the assumption of preference independence and unitary income elasticity. Table 5.6 presents the estimates of income flexibility for the pooled data based on the plots in Figure 5.5. As can be seen, the overall average for the 9 commodity groups is 0 = -.40, which very close to the values obtained in a number of previous studies as well as those obtained in Chapters 3 and 4. Engel's Law

One of the empirical regularities considered in Chapters 3 and 4 is the Engel's law, which states that the budget share for food falls with increasing income. In Figure 5.6, we plot the budget share for food (wFt) against the logarithmic of the per capita real consumption expenditure (log Mt) for 22 OECD and 22 LD countries. (As Iceland and Hungary were found to be outliers, we have excluded these countries.) As before, the points are scattered around a negatively sloping straight line. The slope of the least-squares regression line is -.248, which is very close to the individual group values of -.245 for OECD (Figure 3.3b) and -.216 for LDC (Figure 4.3b). Clearly, the overall conclusion of Figure 5.6 is that Engel's law is well supported by the data from the 44 countries.

Validity of Preference Independence

In Tables 5.7 and 5.8, we reproduce the average income and own-price elasticities from Chapters 3 and 4 obtained using a double-log demand system. In all countries, food, housing, medical care and education are necessities (that is, income elasticity less than one) while clothing, durables, transport and recreation are luxuries (that is, income elasticity greater than one). On average, all the own-price elasticities are negative as they should be and all of them are

International Consumption Comparisons

180

Table 5.6 Estimates for <> j for the 9 commodities in 46 countries Income flexibility

Commodity 1. 2. 3. 4. 5. 6. 7. 8. 9.

Food Clothing Housing Durables Medical care Transport Recreation Education Miscellaneous

-.20 -.34 -.11 -.44 -.47 -1.06 -.26 -.61 -.08

Mean

-.40

H!

-1

qpoo

O) •o 3

-2

1

-3

= V

-4

to y = -0.2475x +0.5214 -5

Log(lncome) Adjusted food budget share vs the logarithm of income Pooled data from 44 countries Figure 5.6

181

Chapter 5 A Comparison of Consumption Patterns

Table 5.7 Average income elasticities of 9 commodities in OECD and LD countries* LD countries OECD countries (3) (2) 0.72 0.60 1. Food 2. Clothing 1.41 1.51 0.62 3. Housing 0.50 4. Durables 1.59 1.44 0.77 5. Medical 0.67 1.90 1.43 6. Transport 7. Recreation 1.16 0.99 0.57 8. Education 1.01 9. Miscellaneous 1.36 1.15 * Based on double-log demand equation with no constant. Country

(D

World (4) 0.66 1.46 0.56 1.52 0.72 1.66 1.08 0.79 1.25

Table 5.8 Average own-price elasticities of 9 commodities in OECD and LD countries* Country

LD countries OECD countries (2) (3) (D -0.22 1. Food -0.36 2. Clothing -0.43 -0.79 -0.17 -0.35 3. Housing 4. Durables -0.24 -0.43 -0.27 5. Medical -0.40 -0.39 -0.41 6. Transport 7. Recreation -0.44 -0.65 -0.23 -0.64 8. Education -0.40 -0.31 9. Miscellaneous * Based on double-log demand equation with no constant.

World (4) -0.29 -0.61 -0.26 -0.33 -0.33 -0.40 -0.54 -0.43 -0.36

International Consumption Comparisons

182

also less than one in absolute value for both OECD and LD countries. This indicates that in all countries, demand for all consumer goods is price-inelastic. In Figures 5.7 and 5.8, we plot the income elasticities and price elasticities for the 9 commodities using the average OECD vs LDC estimates, respectively. As can be seen, the points are scattered very close to the 45° line for income elasticities with correlation coefficient r = 0.86, and the points are mostly away from the 45° line for own-price elasticities with correlation coefficient r = 0.44. This shows that the income elasticities in OECD and LDC are highly positively correlated while the own-price elasticities in OECD and LDC are also positively correlated but less strongly. In Chapters 3 and 4, we discussed an informal method of testing the validity of the preference independence of the utility structure using the plot of the income elasticities against the own-price elasticities. If preference independence holds, then the own-price elasticities will be proportional to the income elasticities, with the income flexibility <>| being the factor of proportionality. In Figure 5.9, we plot each pair of the income elasticities (r|j) against the own-price elasticities (r|ij) for the 46 countries combined from Tables 3.18, 3.19, 4.17 and 4.18 and the solid line is the least-squares line. The points are scattered around a negatively sloping line giving support to the validity of preference independence for the world consumption data. The estimate of the factor of proportionality <]) is -.31, which is very close to the previous estimates presented in Chapters 3 and 4.

5.3

Conclusion

In this chapter, we presented a comparison of the results of the preliminary data analysis presented in Chapters 3 and 4 for the OECD and LD countries,

Chapter 5 A Comparison of Consumption Patterns

183

1.6

g

1.2

^

^

•

y=x

•

0.8 •

0 4-

0.4

1.4

0.9 0 E C D

1.9 Correlation = 0.86

Income elasticities of 9 commodities: OECD vs LDC Figure 5.7

-( .5

-0.4

-0.3

-( '.1

-0^—

-0.3 -

•

LDC

y =x

•

•

•

• -0.5 -

•

•

-0.7 -

« OECD

Correlation = 0.44

Own-price elasticities of 9 commodities: OECD vs LDC Figure 5.8

International Consumption Comparisons

•price elasticities

184

% o

1

y = -0.3054x

•

•

.

-1 " ^ f ^ ^ ^ - ' •. •

-2 •

*

r

• •*

•

•i

Income elasticities Income elasticities vs own-price elasticities for 9 commodities in 46 countries Figure 5.9

respectively. A comparison between the results of Chapters 3 and 4 showed that, while some differences exist between the consumption patterns of the OECD and the LDC consumers, there are more similarities in the consumption patterns of the two groups of consumers. In terms of income allocation, compared to the LDC consumers, OECD consumers allocate a lesser proportion of their income on food and more on housing, medical care, transport and recreation. The higher allocation of income on food of the low-income LD consumers compared to the high-income OECD consumers supports the Engel's law. Overall prices of consumer goods in the LD countries have increased at a rate almost twice that of their OECD counterparts. A number of empirical regularities also emerge from the data analysis of the two groups of countries; namely,

Chapter 5 A Comparison of Consumption Patterns (i) (ii) (iii) (iv) (v)

(vi)

185

Consumption patterns of both groups of countries support the Law of Demand; Quantity variance systematically exceeds the price variance; Budget share for food decreases when the consumer becomes more affluent; Consumer behaviour in both groups of countries gives tentative support for a preference independent utility structure, Food, housing, medical care and education appear to be necessities, while clothing, durables, transport and recreation are luxuries in both groups of countries, The demand for all consumer goods is price inelastic in both OECD and LD countries.

This page is intentionally left blank

CHAPTER 6 Stochastic Price and Quantity Index Numbers E.A. Selvanathan & S. Selvanathan

In the previous chapters, we have concentrated on utility-based demand analysis. As is well-known, the utility function can also serve as the basis for true-cost-of-living indices. This is known as the functional approach to index number theory, whereby the form of the index is related to the underlying utility function (see Diewert, 1981, for a survey). An alternative to the functional approach is the stochastic approach, whereby the proportionate change in each individual price is taken to be equal to the underlying rate of inflation plus other components, which are random and non-random. If we have n prices, then the rate of inflation can be estimated by taking some form of average of the n price changes. The stochastic approach can be viewed as a signal extraction problem. To illustrate, consider the simplest case whereby each of the n proportionate price changes is the sum of the underlying rate of inflation and an independent random component. Here each observed price change is a reading on the rate of inflation 'contaminated' by the random term. The averaging of the price changes serves to eliminate as much as possible of the contamination and leaves an estimate of the underlying signal, the rate of inflation. Although the stochastic approach is less well known than the functional approach, it has a long history going back to Edgeworth (see Frisch, 1936, for

188

International Consumption Comparisons

references). In addition, this approach has recently attracted renewed attention (Balk, 1980; Clements and Izan, 1981, 1987; Crompton, 2000; Diewert, 1995; Rao and Selvanathan, 1991, 1992, 1996; Rao, Doran and Selvanathan, 2002; Rao, Selvanathan and Pilat, 1995; Selvanathan, 1989, 1991, 1993, 2002; Selvanathan and Rao, 1992a, 1992b, 1994; Selvanathan and Selvanathan, 2003; and Theil et al, 1981). The attraction of the stochastic approach is that it provides standard errors for the price indices. These standard errors increase with the degree of relative price variability. This agrees with the intuitive notion that when the individual prices move very disproportionately, the overall rate of inflation is less well defined. The availability of the standard errors allows us to construct confidence intervals for the true rate of inflation. These interval estimates can be used in practical situations (e.g., wage negotiations). Many of the results in this chapter are derived exclusively with prices. However, the methodology could equally well be applied to quantities and be used for the measurement of real income, total factor productivity, and so on. The framework could also be used to test the purchasing power parity hypothesis (see Miller, 1984) and to extend the analysis of Divisia monetary aggregates (Barnett, 1981, Section 7.11). In this chapter, we apply the stochastic index numbers to measure the price and quantity movements in the OECD and LD countries. The organisation of this chapter is as follows. In Section 6.1, we develop unweighted indices and in the following four sections, we develop weighted indices using the stochastic approach. In Section 6.6, we present an extension together with an empirical application. Then, in Section 6.7, we apply the stochastic approach to price and quantity data for the OECD and LD countries to measure the price and quantity movements in these countries. Finally, in Section 6.8, we present the concluding comments.

189

Chapter 6 Stochastic Index Numbers

6.1

An Unweighted Average of Prices

The material in this and the subsequent four sections are from Clements and Izan (1987). Let/?it be the price of commodity i (i=l,...,n) in period t (t=l,...,T) and Dpit = log /?it - log p-A.\ be the price log-change. For each period, let each price log-change be made up of a systematic part a, and a zero-mean random component eit; that is, Dplt =

oct+ eit,

i=l,...,n; t=l,...,T.

(1.1)

As E[Dpit] = oct, we interpret oc, as the common trend in all prices. The random term eit is assumed to be independent over commodities and have a common variance o\; that is, Cov[eit, ejt]

=

ofby,

i,j=l,...,n,

(1.2)

where 5y is the Kronecker delta. From (1.1) we can see that eit = Dpn - GCt is the change in the i* price deflated by the common trend in all prices; i.e., eit is the change in the i* relative price. Hence (1.2) is interpreted as saying that the relative prices are independent and have a common variance. Furthermore, the assumption that E[ejt] = 0 means that all relative price changes have an expected value of zero. Under these assumptions, the best linear unbiased estimator of a t is af =

1« - I DPil, n (=i

International Consumption Comparisons

190

which is just the unweighted average of the n price log-changes. Also we have var a, = — a2.

(1.3)

n The variance a^ can be estimated unbiasedly by

&?

= -^—i(DPil-at)2.

(1.4)

n - 1 i=i

From (1.3) and (1.4) we see that when there is substantial variation in relative prices, the sampling variance of d, will be higher. This agrees with the intuitive notion that the meaning of the overall rate of inflation becomes less well defined when there are large changes in relative prices. Given the above interpretations, assumption (1.2), together with E[eit] = 0, is obviously very stringent. We now extend the model to relax these assumptions.

6.2

A Budget-Share-Weighted Average of Prices

We continue to take the relative price changes as having expectation zero and being independent, but we now replace (1.2) with

Cov[eit)Ejt]

=

X2 r=-Sti,

i,j=l.-,«,

(2.1)

191

Chapter 6 Stochastic Index Numbers

where A] is a constant with respect to commodities; and wu is the arithmetic average of the budget share of i during the two periods t and t-1. That is, wit l

/2(wit + wit_i). Under this assumption, the variance of the change in the relative

price of i is inversely proportional to wit. This means that the variability of a relative price falls as the commodity becomes more important in the consumer's budget. We write (1.1) in vector form as Dpt

=

otti+ et,

t=l,...,T,

(2.2)

where Dpt = [Dpit\; I = [1 ... 1]'; and e t = [eit]. Under (2.1), the n x n covariance matrix of et is

Vare,

=

A] W~\

(2.3)

where Wt = diag[vv ]( ... wnt]. Application of GLS to (2.2) under (2.3) gives

a, =

Since i'Wti

a, =

(l'Wti)-li'WtDpt

= Z"=iWl7 = 1 and

I "it Dp it1=1

.

i'WtDpt

= Zf=i^~'itDP'it >

tms

simplifies to

192

International Consumption Comparisons

This expression is identical to the finite-change form of the Divisia price index, DPt, defined in equation (2.8) of Section 3.2. The sampling variance of 5 , is X2t(i'Wti)~1 = Xzt; that is, Var at = %

(2.4)

This variance can be estimated unbiasedly by 1 ,„ ~ .,.—,~. 1 A -_ ~, (Dpt - a, i)'Wt (DPt -ati) = - 1 w, {DPit-at2)\ n -1 n - 1 i=i so that I] = -!-iwit(Dpit-at)i. rc - 1 i=i

(2.5)

We write (2.5) as

I] = -^-nt,

(2.6)

n-\ where n t = £"=1 vv,7 /Dp,-, - DPt ]2 is the finite-change form of the Divisia variance of relative price changes defined in equation (2.10) of Section 3.2. This IT measures the degree to which prices move disproportionately; n = 0 only if all prices change proportionately, that is, if there are no changes in relative prices. From (2.4) and (2.6) again we see that the sampling variance of the estimator of inflation will be higher the larger the relative price movements.

193

Chapter 6 Stochastic Index Numbers

6.3

The Extended Model

We now write Dp,t as the sum of the common trend in all prices oct, a commodity-specific component Pi and a zero-mean random component £;t» Dpit = Ot + Pi + Cit.

i=l,...,n;t=l,...,T,

(3.1)

where T is the number of observations. We assume that the £it's are independent over commodities and time, and that their variances are inversely proportional to the corresponding arithmetic averages of the budget shares,

Covt^Cjt]

=

^ - 5 ^ ,

(3.2)

where rjt is a constant with respect to commodities. Rearranging equation (3.1) and taking the mathematical expectation, we obtain Pi = E[Dpn - otj. Thus Pi is interpreted as the expectation of the change in the i* relative price. Model (3.1) is not identified. This can be seen by noting that an increase in a t for each t by any number k and lowering of Pi for each i by the same k does not affect the right-hand side of (3.1). To identify the model we impose the constraint

twfit=0,

(3.3)

194 where

International Consumption Comparisons wi

is the sample mean of wit.

interpretation

that

a

Equation (3.3) has the simple

budget-share-weighted-average

of

the

systematic

components of the relative price changes is zero.

6.4

A Two-Step Estimation Procedure: Step 1

We now develop a procedure to estimate (3.1) in two steps. In the first step we ignore the time dependence of the variance given by (3.2) and obtain the leastsquares residuals. These residuals are then used in the second step to adjust for heteroscedasticity in obtaining the final estimators. For i = j and t = s, we obtain from (3.2)

VarCu = ^ - -

(4.1)

In the first step we replace this with the specification

Var^it = ^ ,

(4.2)

W:

where rf is a constant. Multiplying both sides of (3.1) by •yjw^, we obtain yit

= OtX i + (3iXi + £it,

(4.3)

Chapter 6 Stochastic Index Numbers

195

where yit = ^j^Dpit; x ; = ^ T ; and £it = V^TCir I{ follows from (4.2) that var [£it] = wt var [£it] = if, a constant, so that least squares can be applied to (4.3). It can be shown that the LS estimators of (4.3), constrained by (3.3), are a* = twtDpu, /=i

P* = ^-i(DPit-at).

(4.4)

T t=\

The only difference between a* and the Divisia price index DPt is that the former uses constant weights (w t ), while the weights of the latter vary with time (wit). In fact, this difference will have little practical importance as budget shares tend to change slowly over time. The estimator of Pi defined in (4.4) is the sample mean of the change in the i* relative price. Now we use the estimators defined in (4.4) together with price logchanges Dpit and the sample means of the budget shares w, to obtain an estimate of the variance of £it in (3.1). This estimate will be used in the second step. As the budget shares are fairly stable over time, as an approximation we replace wit in (4.1) with w; to give

VarCi, = ^ - -

(4.5)

w

i

It is to be noted that this variance is time-dependent because of the t subscript of r\f. By contrast, the variance defined in (4.2) is constant over time. Substituting the estimators of cct and Pi in (4.3), the residual from that model is

196

International Consumption Comparisons

£ = J^lDpu- a?-P?] =

V^Ti(Dpu- OL*)- {Dpl

-a*)],

where the second step is based on the second equation in (4.4); Dpi ={\IT)jJt=xDpit is the sample mean of Dpu and cc* = ( l / r > l L a t is the mean of a*. Thus the sum over i=l,...,n of squared residuals is 6? = 1 [&1 2 = X Wi(Dpu -a*? i=i

i=i

+ I w^Dpi - a * ) 2 i=i

-2iw,.(%-fl;)(Dprat). i=i

The first term on the far right of this equation is the Divisia price variance Il t with wit replaced by wt. This measures the variability of relative prices within period t. The second term measures the variability of relative prices over the whole period. The last term, minus twice a weighted covariance, measures the degree to which relative price changes in period t coincide with price changes over the whole period. It can be easily shown that Qj /(n -1) is an asymptotically unbiased estimator of r\j.

6.5

A Two-Step Estimation Procedure: Step 2

We divide both sides of (4.3) by 9t to give Pit

=

a x

t it

+

P i * i t + Cit.

(5.1)

197

Chapter 6 Stochastic Index Numbers

As where yit = Jw^Dph/et; xit = J^/Qt; and Cit = yf^^it/et2 9 /(« -1) is an asymptotically unbiased estimator of r\j, it follows from (4.5) that

VarC lt = - |2v a r C i t 9

^2 6 wt

' («-l)

a constant, so that least squares can now be applied to (5.1). It can be shown that the LS estimators, constrained by (3.3), are a?* = ±WiDpu,

pr = ^ £ f t ( 0 p a - a O ,

i=i

(5-2)

T «=i

where <j)t = (1 / 0 2 ) / 1 [ = 1 (1 / 9?). As can be seen, the estimator a** is identical to a* defined in (4.4). The reason is that the new weighting factor in (5.1), l/9t, is the same for all i within the period t. The estimator P** of the systematic component of the change in the i* relative price is now a weighted average of (Dpn - a**) over all T periods. By contrast, P*, defined in (4.4), is an unweighted average. The weights in (5.2), 0i, ..., (Jh-, are inversely proportional to Qj, which in turn is proportional to the error variance in period t; thus, less weight is accorded to those observations with a higher error variance. We can also show that the sampling variances of the estimators defined in (5.2) are 92 Var < * = —'—, n l ~

Var p** =

1 i (n-l)Z(l/e2) t=l

-1-1 W;

(5.3)

International Consumption Comparisons

198

As can be seen, the sampling variance of a** increases with 9 2 , which in turn rises with relative price variability. Therefore, the same general result as before emerges here: the sampling variance of the estimator of inflation will be higher the larger the relative price movements. The sampling variance of (3** is proportional to the difference between (l/vv ; ) and a constant term, so that this variance increases as wt falls. It can also be shown that

Cov [a**, or" ] = 0 for t *s;

Cov[P**, P** ] =

^ (n-l)S(l/9?)

for i * j ;

(5.4)

t=i

and C o v [ a p , P J * ] = 0,

t=l,...,T;i=l,...,n.

(5.5)

From (5.3) and (5.4), we obtain Corr[P**,P**] = -j^=,

fori*j,

where w* = ( 1 / wt) - 1 . This shows that the correlation between the i* and the j * systematic components of relative prices is always negative and it falls (in absolute value) with declining budget shares of both i and j . Finally, we define the mean of a** over all T periods as a** = (1/T) J^^a**•

Var a "

= - ^ £ Vara?* = - ^ - j l *l T 2 i=i ( n - l ) T 2 (=i

Hence we have

(5.6)

Chapter 6 Stochastic Index Numbers

199

where we have used (5.3) and (5.4). It is to be noted that all the sampling variances defined in this section have only an asymptotic justification. The reason is that they all involve Qf /(n -1) which is an asymptotically unbiased estimator of f]f.

6.6

An Extension

Under the error variance structure (4.1), it was assumed that the variance of the i* error term Qt is inversely proportional to the corresponding i* budget share, wjt. Clements and Izan (1987) used this assumption in their estimation of the rate of inflation and empirically analysed this assumption and concluded that, "the variances are not inversely proportional to the budget shares as required by the assumption" (see page 345, Clements and Izan, 1987). Selvanathan (1987) relaxed this assumption on the error terms by allowing the errors to be correlated over commodities and derived a new estimator for the rate of inflation. Diewert (1995) and Crompton (2000) both correctly criticised the assumption made in Clements and Izan (1987) and proposed an alternative specification for the error variance structure. Under this variance structure, Crompton showed that the new variance estimator of the rate of inflation is robust to unknown forms of heteroscedasticity. Under this specification, while the estimator of the rate of inflation oct remains as the budget share weighted sum of the n price changes as given in (4.4), the robust variance estimator is now a budget share weighted sum of the squared relative price changes instead of the variance given in (5.3). In this section we shall present the details of Crompton's work. Crompton (2000) replaced the specific variance structure given by (4.1) with an unknown form of heteroscedastic variance structure,

International Consumption Comparisons

200

Var^i,

=

4-

(6-1)

This differs from the variance structure given in (4.1) in the sense that now the error variance is an unknown form of heteroscedasticity. As in Clements and Izan (1987), to obtain an estimator for the rate of inflation as a budget-shareweighted average of the individual price changes, we multiply both sides of equation (4.1) by ^/w,- to give yit

= a t x; +piXi+ £it,

(6.2)

where yit = ^Dpit; Xj = ^ ; and £it = V^~Cir Under (6.1), we have Var (^t) = X2jt wt. Since heteroscedasticity in the error term does not effect the rate of inflation estimator, we can estimate (6.2) directly by using LS and correct for heteroscedasticity in £it using White (1980) heteroscedasticity - consistent covariance matrix estimator. As Crompton (2000) points out, the advantage of this approach is that we do not need to concern ourselves over the nature of the error variance. Crompton (2000) showed that the constrained LS estimators of equation (6.2) for the rate of inflation and its variance can be written in scalar form as 6c, = twiDpit, !=1

Var 6c, = £ w,|? r ,

(6.3)

1=1

where \it = ytt - 6c, x t - (3, xt are the LS residuals. Comparing the results given in (6.3) with the results of 6c, in (5.2) and (5.3), we see that the point estimates of the rate of inflation, 6c,, are identical. However, the variance of the estimate of inflation in (6.3) is now a weighted

Chapter 6 Stochastic Index Numbers

201

average of the sum of squared residuals over the n commodities for any given period. As an illustrative application, first we reproduce the application presented in Selvanathan (2003). In this application, we use the Australian quarterly price and CPI data for the period September 1972 to June 1996. There are eight subcomponents (n=8) to the CPI, namely, food, tobacco and alcohol, clothing, housing, durables, health care, transport and miscellaneous. The data were obtained from the Australian Bureau of Statistics and the same data were used in Crompton (2000). The estimate for the rate of inflation, the two sets of standard errors based on Clements and Izan (1987) and Crompton (2000) obtained by using equations (5.2), (5.3) and (6.3) are presented in Table 6.1. In column 2 of the table, we present the estimates of inflation for Australia. In column 3, we present the CPI log-change. Comparing the CPI log-changes in column 3 with the inflation estimates in column 2, we see that the inflation estimates are very close to the CPI log-change. As can also be seen from the last row of Table 6.1, the mean quarterly rate of inflation is estimated to be 1.78%, with a standard error of .52%. This mean point estimate is also close to the mean CPI log-change of 1.89% as expected. Column 4 presents Clements and Izan's (C&I) standard errors and column 5 presents the Crompton's robust standard errors. As expected, the robust standard errors are generally smaller than the C&I standard errors (in actual terms, more than 75% of the times column 5 standard errors are lower than those in column 6). We illustrate this in Figure 6.1. Figure 6.1 plots the C&I standard errors against the robust standard errors presented in Table 6.1. As can be seen, most of the points fall above the 45o line indicating that, in general, the robust standard errors are smaller than C&I standard errors. Clearly, the conclusion from Table 6.1 and Figure 6.1 is that

International Consumption Comparisons

202

Table 6.1 Estimates of price inflation and standard errors for Australia (December 1972-June 1996) Standard errors

Standard errors

Rate of inflation

CPI log-change

C&l

Crompton

Dec Mar

(2) 1.00

(3) 1.00

(4) 0.19

(5) 0.18

1.59

1.97

0.50

0.55

(1) 1984 Dec 1985 Mar

Jun Sep

2.45 2.88

3.36

0.59

0.61

Jun

3.25

0.68

0.64

Dec

3.06

3.59

0.46

Mar

2.18

2.61

Jun

3.46

Sep

Rate of Inflation

CPI log-change

(2) 1.32

(3)

1.42

Sep

0.41

0.37

4.20

4.71

Dec Mar

Year

C&l

Crompton

1.50

(4) 0.16

(5) 0.14

1.33

0.27

0.24

2.37 2.18

2.32

0.41

0.40

2.27

0.24

0.21

Dec

2.03

1.94

0.35

0.35

0.33

1986 Mar

2.25

2.31

0.31

0.28

0.57

0.48

Jun

1.63

1.60

0.65

4.82

0.82

0.82

Sep

2.55

2.61

0.47

0.61 0.46

3.54

3.47

0.91

0.92

2.80

0.54

3.72

0.97

0.78

Dec 1987 Mar

2.77

3.33

1.97

1.99

0.41

0.49 0.38

Jun

3.03

3.58

0.50

0.45

Jun

1.54

1.46

0.35

0.36

Sep

0.51

0.70

2.85

2.09

Sep

1.62

1.68

0.22

0.18

1.77

1.81

1.74

0.22 0.49

0.20

0.48

Dec 1988 Mar

1.69

Jun

2.26

2.61 2.55

1.88 0.47

1.41

Mar

4.78 2.62

5.44

0.61

0.58

Jun

1.74

1.71

0.45

0.45

Sep

1.99

2.48

0.38

0.34

Sep

1.92

6.37

5.66

5.50

3.97

Dec

2.08

1.90 1.98

0.41

Dec

0.39 0.74

2.29 2.24

0.31

0.29

1989 Mar

0.98

0.97

0.27

Jun

2.44

2.45

0.51 0.52

0.45

0.32

1.92 2.42

0.40 0.29

0.42 0.25

Sep Dec

2.25 1.84

2.28 1.83

0.52 0.44

0.51 0.44

Dec

Mar

1.93

Jun

2.08

Sep Dec

1.77 2.08

0.75

0.42

0.52

Mar

1.03

1.32

0.14

0.14

1990 Mar

1.71

1.70

0.40

0.39

Jun

1.97

2.07

0.49

0.40

Jun

1.60

1.57

0.26

0.27

Sep

1.70

1.78

0.31

0.28

Sep

0.76

0.78

0.32

0.34

Dec

1.51

2.24

2.77

1.97

2.61

2.58

0.73

0.77

Mar

Dec 1991 Mar

-0.17

-0.19

0.90

0.92 0.24

1.47

1.71

0.37

0.35

Jun

2.23

2.63

0.50

0.53

Jun

0.17

0.19

0.28

Sep

2.10

2.33

0.37

0.36

Sep

0.58

0.56

0.50

0.51

Dec

2.82

2.95

1.05

0.75

0.87

0.93

0.40

0.35

Mar

1.86

2.21

0.47

0.50

Dec 1992 Mar

0.01

0.00

0.57

0.50

Jun

2.48

2.80

0.40

0.39

Jun

-0.39

-0.28

0.56

0.48

Sep

1.78

1.69

0.42

0.45

Sep

0.11

0.09

0.51

0.49

Dec

1.92

2.07

0.28

Dec

0.49

0.46

0.34

0.31

Mar

2.15

2.43

0.30

0.24 0.28

1993 Mar

0.84

0.92

0.39

0.40

Jun

1.92

2.18

0.37

Jun

0.28

0.30

1.94

Sep

0.46

0.18

0.18

0.27 0.38

0.23

Dec

1.81 3.94

0.41 0.40

0.37

Sep

0.38 0.46

Mar Jun

1.56 2.43

0.36

2.32

Jun

0.38 0.65

0.28 0.27

0.23 0.28 0.17

Sep

4.14

1.86

0.48 1.36

1.82

0.29 0.26

0.30 0.28

Dec 1994 Mar

0.72

0.36

3.45

3.47

Sep

0.63

2.91

2.86

0.41

0.39

Dec

0.84

0.63 0.80

0.16

Dec

0.39

0.38

Mar

2.11

2.13

0.47

0.40

1995 Mar

1.68

1.67

0.65

0.66

Jun

1.99

2.09

0.54

0.57

Jun

1.22

1.30

0.27

0.24

Sep

1.69

1.73

0.34

0.33

Sep

1.20

1.20

0.35

0.30

Dec Mar

2.32 -0.32

2.32

0.42 2.22

Dec 1996 Mar

0.70 0.39

0.23 0.32

0.12

1.51

1.09

Jun

0.66

0.76 0.42 0.67

0.25 0.35

Jun

-0.46 0.31

0.36 1.60

0.14

0.12

Sep

1.32

1.22

0.26

0.23 1.78

1.89

0.59

0.52

0.47

0.42

Wean

Chapter 6 Stochastic Index Numbers

203

0.70

I

I

0.50

0.30

u n m 0.10

0.30

0.50

0.70

Robust standard errors

Standard errors of the inflation estimates Australia, December 1972-June 1996 Figure 6.1

the robust standard errors should be used when determining the precision oi ine rate of inflation estimates. In Table 6.2 we present the estimates and their standard errors for the commodity specific component (3j. As can be seen, the coefficients for food, clothing, housing and durables are statistically insignificant indicating that the relative prices of food, clothing and housing remain almost a constant during the sample period. The relative price of tobacco and alcohol, health care and transport are significant; the estimated relative price of these three commodities increased by .35%, .38% and .21% per quarter, respectively. Figure 6.2 presents a scatter plot of the standard error of the estimate of inflation V(var at ) against the estimate of inflation (dt ) and the solid line is the LS regression line. As can be seen, the slope of the LS regression line is less than 1, indicating that the estimate of inflation increases faster than the standard

International Consumption

204

Comparisons

Table 6.2 Estimates of relative price changes: Australia December 1972 - June 1996 Estimate of relative price change

Commodity

/?,. X100 1. 2. 3. 4. 5. 6. 7. 8.

.06 (.07) .35 (.12) -.13 (.14) .08 (.08) -.07 (.07) .38 (.13) .21 (.08) -.82 (.10)

Food Tobacco and Alcohol Clothing Housing Durables Health care Transport Miscellaneous

Note: Standard errors are in parentheses.

•

•

y = 0.1733x +0.2089

1.7 •

(X1

o

*

(A O

•

1.2•

h.

•

"g Stand

0.7• '•

1

m (i

•

•j^-*"*

• -^•"""•""""^ *

•

1

2

3

4

Inflation rates (x100)

Estimated inflation rates vs their standard errors Australia, December 1972-June 1996 Figure 6.2

Chapter 6 Stochastic Index Numbers

205

error. To investigate this further, in Figure 6.3, we plot the t-values against the estimated inflation rates (at) (again the solid line is the LS regression line). There is a distinct positive relationship between these two variables, which confirms the tendency for the standard error to increase less rapidly than inflation. Consequently, in a relative sense, higher inflation tends to be estimated more precisely. In Figure 6.4 we plot against time the estimated inflation and the 95% confidence bands constructed as & ± 1.96V(vara). The jump in inflation and the increase in the width of the confidence band in the mid 1970s is to be noted.

6.7 Application of Stochastic Index Numbers to OECD and LDC In this section we use the methodology we described in the previous sections to estimate the growth in prices (i.e. rate of inflation) and the growth in consumption (i.e. quantity index) in the OECD and LD countries. The material presented in this section draws on Selvanathan and Selvanathan (2003). Tables 6.3 and 6.4 present the rate of inflation and their standard errors for the 23 OECD and 23 LD countries, respectively. Tables 6.5 and 6.6 present the estimated relative price changes |3* for the OECD and LD countries, respectively. For each country, the first column presents the point estimates and the second column presents the standard errors. As can be seen, most of the point estimates are estimated precisely. A clear distinction between the two sets of tables is that the estimates for the rate of inflation in all OECD countries are in single-digit figures while they are in double-digit figures for most of the LD countries. It is also worth noting that the estimates for the inflation rates in Tables 6.3 and 6.4 are very close to the Divisia price indices presented in Tables 3.7 and 4.7, respectively, of Chapters 3 and 4. The reason for this

International Consumption Comparisons

206

44

1

~

*

g

*•

75

y=1.0189x + 2.5697 •

.•*.

^ •

^ X ^

• • **2.*~+>^ •

•

**&0^

31 >

I

fc

.f • " 0 f

A

2

4

6

g_

I

1 Inflation rates (x100)

Estimated inflation rates vs their t-values Australia, December 1972-June 1996 Figure 6.3

• Upper D friflation • Lower

Estimated inflation rates and their 95% confidence intervals Australia, December 1972-June 1996 Figure 6.4

207

Chapter 6 Stochastic Index Numbers

Belgium

Canada

Denmark

Finland

France

Germany

Greece

Iceland

Ireland

(1) 1953

Austria

Year

Australia

Table 6.3 Rate of inflation estimates and their standard errors in 23 OECD countries

s

(2)

(3)

(4)

(5)

(6)

(7)

(8)

(9)

(10)

(11)

(12)

(13)

1954 1955 1956 1957 1958 1959 1960 0.85 1.00

3.25 1.61

0.72 0.27

1.78 0.31

1962 2.15 1.13

0.63 1.25

-0.73 1.39

3.28 0.45

3.09 0.57

1.48 0.71

1963

0.49 1.10

4.03 1.10

3.39 1.76

5.27 0.56

3.15 0.35

2.99 0.75

1964

3.18 0.42

4.20 0.51

1.29 0.45

7.32 1.64

2.51 0.25

2.06 0.33

1965

3.29 0.45

4.24 0.73

4.53 1.54

1.95 0.45

3.32 1.26

2.89 0.50

3.13 0.44

4.30 0.87

1966

3.13 0.31

2.90 0.33

4.39 0.73

3.24 0.64

2.87 0.61

3.33 0.45

3.92 0.32

3.26 0.50

2.90 0.29

1967

3.58 0.33

4.27 0.65

2.58 0.29

3.60 0.69

6.68 0.86

4.70 089

3.44 0.64

2.00 0.48

1.77 0.51

3.10 0.37

1968

3.35 0.54

2.83 0.45

2.76 0.46

4.01 0.31

7.14 0.48

10.00 2.44

5.25 0.54

2.01 0.89

0.63 0.76

1.59 0.29

1969

3.10 1.03

3.37 0.48

2.96 0.53

3.83 0.43

4.52 0.64

1.97 0.34

7.01 0.46

1.97 0.56

2.95 0.51

2.75 0.55

1970

1961

3.47 0.64

5.63 0.81

3.89 0.43

2.54 0.95

3.56 0.74

7.00 0.57

3.54 5.52

4.93 0.30

3.75 0.24

3.36 0.79

4.96 0.22

1971 6.57 0.74

4.93 0.50

5.05 0.70

2.48 0.65

6.96 0.73

6.64 0.54

5.46 0.26

5.44 0.52

2.90 0.90

5.46 0.30

1972

7.60 1.32

6.11 0.37

5.27 1.08

4.01 0.49

7.56 1.20

8.08 0.30

5.65 0.65

5.38 0.47

3.63 0.27

614 0.61

1973

8.68 1.70

7.19 0.65

6.71 1.63

8.24 1.65

9.34 1.51

11.29 0.90

6.56 0.66

6.57 4.53

14.01 2.03

11.73 0.84

1974 16.24 1.42

10.11 1.02

12.06 1.05

10.03 0.65

14.34 1.27

17.48 1.90

12.56 0.81

6.69 0.77

21.43 1.33

14.62 1.56

1975 14.42 0.87

7.97 0.35

12.29 0.88

10.05 0.42

9.67 0.43

15.30 2.53

10.79 0.61

5.97 0.24

12.14 0.82

20.63 1.36

16.40 0.96

1976 11.12 0.72

6.65 0.53

7.75 1.10

7.50 1.33

9.40 0.60

12.62 1.79

9.42 0.51

4.23 039

12.76 0.56

18.13 2.22

16.55 1.06

1977

9.23 0.46

5.68 0.39

7.05 0.61

7.06 0.72

10.21 1.04

11.03 1.21

8.68 0.72

3.62 0.72

11.32 0.48

14.18 2.01

16.72 0.67

1978

8.81 0.98

4.12 0.47

4.10 0.39

7.23 0.85

9.13 0.50

7.27 0.71

8.48 0.41

2.71 0.47

11.63 0.49

35.87 1.13

7.56 1.94

12.18 0.68

1979

9.92 0.52

4.04 0.52

3.91 0.89

8.31 0.57

9.74 1.75

7.62 0.44

10.01 0.37

4.34 0.88

16.19 0.74

37.86 2.16

14.11 1.46

13.86 057

1980 9.24 0.29

6.33 0.49

6.07 1.14

9.60 0.58

9.72 1.01

10.92 0.73

12.31 0.82

4.87 0.54

19.91 0.94

44.20 0.64

17.67 1.06

18.43 1.02

1981

17.64 0.43

19.26 1.09

9.13 0.56

6.90 0.77

7.73 1.17

10.81 0.83

11.44 056

10.63 0.67

11.84 0.45

5.74 0.53

20.76 0.70

41.64 1.17

19.03 1.03

1982 10.47 0.74

5.63 0.51

7.15 1.17

9.94 0.73

9.25 0.39

9.66 1.60

11.29 0.60

4.72 0.67

19.02 1.02

41.47 1.12

14.93 0.78

15.79 0.62

1983

3.75 2.64

5.69 4.16

5.35 0.61

665 0.59

8.34 2.26

4.85 5.78

1.95 0.59

16.15 1.49

63.45 3.08

10.06 0.68

27.55 4.73

7.48 0.54

1984

7.84 3.06

5.24 0.58

614 0.78

3.91 0.46

617 0.95

6.69 063

7.37 0.35

2.75 0.57

17.02 0.99

27.65 1.23

7.45 0.50

11.23 0.86

1985

6.00 0.89

3.06 0.28

4.82 0.32

3.66 018

4.32 0.44

552 0.76

5.50 0.40

1.21 0.36

16.81 0.62

27.92 1.20

7.50 2.62

8.81 0.55

1986

8.40 0.40

1.78 0.89

1.64 1.27

3.90 0.63

3.20 0.17

3.13 0.82

2.81 0.84

-0.39 1.15

19.81 1.07

19.10 2.97

14.29 2.49

6.01 0.40

1967

7.61 0.57

0.99 0.49

1.48 0.58

4.01 0.33

4.40 0.78

3.42 0.79

3.06 0.38

-1.43 1.69

14.71 1.50

15.81 1.11

2.46 0.45

5.18 0.22

1968

7.27 0.53

1.49 0.42

1.48 0.27

3.96 0.31

3.79 0.46

4.27 0.29

2.65 0.43

3.00 1.90

12.91 1.01

21.87 2.12

3.99 2.97

5.47 0.39

1989 6.24 0.40

2.29 0.49

3.03 0.33

4.89 0.08

3.91 030

4.75 0.29

3.42 0.27

2.66 0.38

14.06 1.13

19.72 1.92

3.82 0.50

639 0.32

1990

4.80 0.19

3.02 0.38

3.29 0.29

4.23 0.23

2.64 0.37

5.60 0.18

2.93 0.33

2.53 033

18.05 0.62

15.49 0.96

1.89 0.26

6.11 0.47

1991

2.47 0.22

2.98 0.71

3.05 0.28

4.90 0.65

1.97 0.43

5.21 0.69

3.11 0.22

3.47 0.40

17.63 1.01

6.79 0.81

2.73 0.30

6.63 0.66

1992

1.87 0.36

3.85 0.27

2.31 0.69

1.05 0.33

2.26 0.45

3.29 0.54

2.32 0.45

3.81 0.25

13.9B 1.11

4.39 0.91

2.53 0.69

5.43 0.42

1993

1.53 0.47

3.17 0.32

2.37 0.78

1.38 0.33

0.21 0.30

3.53 1.11

2.10 0.30

3.38 0.28

12.64 1.07

4.03 0.86

1.78 0.33

4.57 0.47

1994

1.33 0.53

3.34 0.33

2.59 0.23

0.30 0.99

1.90 0.29

1.40 0.16

2.01 0.33

2.55 0.20

10.14 0.68

1.58 0.64

2.82 0.98

4.44 0.46

1995

2.65 0.57

1.26 0.60

1.39 0.18

1.55 0.43

2.47 0.63

-0.28 1.49

1.52 0.40

1.61 0.38

2.05 0.89

5.65 0.67

1996

1.59 0.39

2.07 0.48

1.91 0.26

0.89 0.56

1.77 0.30

2.18 0.61

1.41 0.81

4.18 0.45

8.81 0.79

Table 6.3 ccntinued'on nextpage

208

International Consumption

Comparisons

0.12 0.52

1954

4.21 1.13

1955

1.60 0.58

1956

1.58 0.82

1957

6.18 0.38

1958

2.09 0.69

1959

0.64 0.75

1960

2.06 0.78

1961

1.68 0.53

Switzerland

=3

(18)

(19)

(20)

(21)

(22)

(23)

USA

1953

(17)

Sweden

(16)

Spain

(15)

Portugal

(14)

Norway

Netherlands

(1)

Luxembourg

Year

Japan

Table 6.3 (continued) Rate of inflation estimates and their standard errors in 23 OECD countries

(24)

1.55 0.28

1962

1.76 0.56

4.89 0.49

4.26 0.36

1963

2.04 0.68

3.66 0.31

1.75 0.98

1.48 0.28

1964

6.22 1.20

4.16 0.18

3.54 0.34

1.51 0.32

1965

3.29 0.77

4.20 0.60

8.26 1.64

5.11 0.46

4.15 0.61

5.08 0.28

1.67 0.28

1966

5.93 0.80

3.38 0.47

6.63 0.87

6.30 0.17

4.83 0.31

3.89 0.43

2.73 0.50

1967

3.41 0.89

4.40 0.51

6.14 0.79

4.27 0.72

4.66 0.76

2.65 0.46

2.68 0.51

1968

4.08 3.51

3.15 0.41

4.63 1.19

1.30 0.43

2.84 0.65

4.51 0.49

4.01 0.45

1969

4.64 0.73

3.44 0.53

3.62 0.62

3.46 0.50

2.89 0.41

5.46 0.35

4.47 0.39

1970

4.32 0.42

9.50 0.53

6.42 0.84

5.74 0.43

4.00 0.50

5.77 0.58

4.47 0.25

3.31 0.56

1971

5.62 0.61

4.56 0.53

8.24 0.87

6.16 0.58

7.62 0.78

7.01 1.34

6.96 0.29

8.29 0.28

4.39 0.41

1972

5.17 0.77

4.61 0.37

8.49 0.68

6.47 0.49

7.81 1.16

5.32 1.63

7.48 0.65

5.81 0.91

3.45 0.31

1973

8.68 1.55

6.29 1.26

8.71 0.38

5.32 1.85

10.52 1.12 11.21 3.22

9.05 0.87

6.98 2.29

7.89 1.80

1974 18.63 2.36

9.47 0.62

9.63 0.91

9.11 0.63

16.33 1.06

9.52 1.31

9.64 0.65 15.53 0.85

9.74 0.79

1975 11.10 0.93

9.89 0.68 10.02 0.67

10.95 1.25

14.54 0.71

10.21 0.84

6.36 0.39 21.47 0.81

7.80 0.41

1976

8.76 0.49

9.13 0.97

8.46 0.76

8.18 0.50

15.68 1.01

10.34 0.25

2.34 1.02 14.37 0.42

5.84 0.75

1977

7.18 0.72

5.58 0.50 11.53 3.09

7.91 0.36

21.84 1.31

10.08 1.18

1.09 0.19 14.06 0.75

6.46 0.67

1978

4.73 0.88

3.54 0.63

4.18 0.56

7.47 0.36

17.56 0.68

10.79 0.65

1.23 1.08

8.69 1.03

6.79 0.48

1979

3.51 0.61

5.00 0.83

3.76 0.49

4.48 0.43

15.55 1.25

7.68 0.95

4.04 1.03 12.74 1.01

8.69 0.67

1980

6.71 0.73

7.14 1.43

6.51 0.67

9.40 0.60

14.75 9.18 11.80 0.28

4.13 0.80 15.32 1.00 10.31 1.11

1981

4.25 0.44

8.25 0.42

5.80 0.68

12.79 1.30

13.35 0.57

10.77 0.68

6.19 0.95 10.86 1.18

8.83 0.57

1982

2.49 0.47

10.02 0.94

4.96 0.56

10.55 0.92

13.72 0.66

9.42 0.82

5.47 0.54

8.34 0.65

5.96 0.68

1983

3.06 1.15

7.78 0.36

2.39 0.32

12.88 6.56

11.83 0.73

11.26 1.97

2.61 0.28

6.68 8.43

3.71 0.93

1984

2.55 0.42

6.41 0.39

2.57 0.91 10.10 0.80

5.94 0.35

11.38 0.85

7.26 0.78

3.00 0.29

4.95 0.83

3.85 0.32

1985

2.19 0.63

4.11 0.23

4.43 4.31

14.21 2.20

5.58 0.42

7.20 0.68

6.74 0.50

3.44 0.17

5.32 0.31

3.51 0.38

1986

0.84 0.32

1.58 1.67

0.21 0.65 13.07 0.89

6.77 0.94

9.06 1.15

4.67 0.73

0.53 1.31

3.92 0.70

2.46 0.78

1987

0.51 0.34

1.59 0.40

0.15 1.07 10.72 1.01

7.52 0.63

9.32 0.74

5.55 0.50

5.08 0.20

1.42 0.46

4.36 0.57

3.82 0.18

1988

0.55 0.14

2.65 0.40

0.27 0.45

6.54 1.64

5.88 0.28

9.99 0.89

4.81 0.29

5.76 0.38

2.01 0.36

5.03 0.41

4.02 0.39

1989

1.86 0.17

3.64 0.44

1.01 0.48

6.50 1.28

4.57 0.43 12.11 0.94

6.42 0.63

6.51 0.33

3.08 0.41

5.70 0.33

4.38 0.30

1990

2.41 0.34

3.60 0.22

2.05 0.46

5.43 0.71

4.47 0.53 11.46 0.57

6.16 0.40

9.19 0.90

5.33 0.49

5.40 1.44

5.14 0.53

1991

2.60 0.46

3.09 0.31

2.92 0.53

1.89 0.91

3.62 0.52 11.03 0.91

5.81 0.54

9.54 2.67

5.47 0.22

6.18 0.92

3.85 0.20 2.82 0.25

1992

1.84 0.41

2.81 0.41

1.07 1.06

2.75 0.50

8.87 0.39

5.90 0.34

1.49 1.77

3.74 0.57

5.51 0.95

1993

1.27 0.24

1.87 0.31

1.02 0.68

1.94 0.52

6.69 0.76

4.94 0.72

4.48 0.82

3.11 0.71

3.12 0.37

2.48 0.27

1994

0.72 0.37

2.22 0.46

2.28 1.10

1.24 0.56

5.40 0.44

4.69 0.78

2.78 0.49

1.18 0.29

2.58 0.46

2.18 0.17

1995 -0.60 0.50

1.00 0.45

2.79 0.93

2.29 0.38

4.09 0.39

4.65 0.65

2.46 0.32

2.82 0.26

2.15 0.26

1996 -0.15 0.45

0.97 0.53

3.34 0.48

0.54 1.28

2.62 0.27

2.14 0.38

1.15 0.55

209

Chapter 6 Stochastic Index Numbers

(6)

(7)

a* o

Korea

(5)

Jamaica

Honduras

(4)

Israel

Fiji

(3)

Iran

Ecuador

(2)

India

Cyprus

(1) 19a

Colombia

Yaar

c

2

Hungary

Table &4 Rate of inflation estimates and their standard e r a s in 23 I D cartries

(8)

(9)

(10)

(U)

(12)

(13)

1962 1963 1964 1965 1966 1967 1968 1969 1970 1971

L12 231

131 L63

1L71158

1972

291021

4.55 272

14.19 208

7.98 0.96 18.47 l a

1973

17.25 260

1974

21421.62

19.08 L34

14.73132

1975

22.191.50

11101-82

1976

19.130.91

10.09L35

1977

2196 L80

U73184

1978

16.612.61

1L45L28

4.84 L33

1979

2106 L53

10.49 a 7 0

860220

1980

23.32 0.93

1108 L57

18.644.05

1931

2106 0.68

9.97 L19

1582 L68

1932

2L93L13

6.16 (M0

17.50 0.60

1983

18.400.43

198127

33.23 635

1984

18721.03

5.710.45

1985

2L15 1.06

1986 1987

18.20 L17

14.83 L98

3293 L32

699027

L09L76

3186 247

14.54 L53

4.14 128

137 L47

2501222

9.60 L55

1601 L62

5H116

4.30 L67

3122101

1169229

14.44 L06

L06a41

4.99 0.51

4147 L37

2626122

1&35194

14.89156

10.99 212

57.16168

2163 L65

1&91L37

7.69132

2159452

85.41612

19.83 292

2599 L75

10.581.29

1194 026

1115130

9.22152

78504.89

1L45L44

17.18 L71

655292

1L27126

954 064

6.62176

77.51128

816 L75

4.67 204

1771.78

870172

884163

9248 L33

1282 242

123 253

3210113

545178

8480.74

7.20 L38

604189

875 L09

15867110

73.61 L10

155160

4.65 141

27.82 265

LSI 1.96

268 L05

6.59169

5.53 LOO

5.81 L66

13540115

2295 L64

3.70183

22.700.72

L67146

24.51 L6S

8853.33

4.89 132

4.96186

6.90163

18.78 228

3857119

1L763.00

L59171

2154 L l l

239131

28.88245

4.73 L99

4.97 084

7.66 L88

7.66123

2298 225

18.20 L19

4.96179

112149

655159

24.13 L32

1938

73.61 LIS

103 0.30

47.27 L53

9.62 276

7.38182

L236L68

852157

2193142

1544160

1969

21.83 0.98

137 a 4 5

55.13 258

4.79 LS9

7.37 0.95

14.48 L35

7.03164

17.97 275

17.86 L77

523165

1990

25.961.34

4.14 037

3930176

7.44216

7.180.60

24.99251

9.75156

873L91

13.82 237

9.14162

1991

24.851.30

4.01 L17

3858023

7.60 L31

S47L05

3187 7.93

1275 L20

17.13 213

1620 L35

assaa

1992

24.55 a 6 6

6.00 a59

41.72 1.28

7.07 052

2104157

816140

2169 L92

1122186

527147

1993

425 tt77

36.15L89

580141

19.43 L65

9.08153

2136 L17

9.83 L49

4.57144

1934

504131

7.11 L15

18.15 L79

9.19192

3L57 264

1196 L27

657 L87

663165

39.66191

594 273

4.19154

1995 1996

7.75171

550164

4.91149

1937 1998

TaUe&4ai1nEdn3t[Bge

International Consumption Comparisons

210

Table 6.4 (continued)

Zimbabwe

(18)

Venezuela

(17)

Thailand

(16)

Taiwan

Singapore

(15)

Sri Lanka

Puerto Rico

(14)

South Africa

Philippines

(1) 1961

Mexico

Year

Malta

Rate of inflation estimates and their standard errors in 23 LD countries

(19)

(20)

(21)

(22)

(23)

(24)

1.88 0.34 1.59 0.63

1962

1.45 0.60

0.49 0.57

1964

1.72 0.60

1.02 0.35

2.90 0.27

0.54 0.68

1965

1.98 0.83

0.46 0.30

3.74 0.41

1.04 0.50

1966

4.77 0.86

1.86 0.62

3.88 0.32

0.37 1.34

1967

2.70 0.72

2.110.80

3.21 0.21

4.23 1.11

1968

4.23 0.64

1.25 0.44

2.58 0.62

6.18 0.78

1969

4.19 0.51

0.02 0.72

3.48 1.04

4.18 1.01

1963

1970 1971

669 0.98

3.99 0.30

1.27 0.51

3.95 0.68

5.45 2.39

4.20 0.63

3.43 0.74

7.59 0.91

2.33 0.60

1972

565 0.44

3.57 0.51

2.64 0.92

6.66 0.58

3.69 1.24

1973

11.55 1.51

11.40 2.16

14.15 2.82

7.09 1.95

10.52 1.17

20.73 2.12

12.78 1.42

12.67 1.66

11.08 0.90

1975

6.16 3.57

13.19 0.48

650 0.62

2.79 0.90

12.95 1.43

11.02 3.87

5.57 0.96

1976

1.43 1.32

17.32 0.60

3.20 1.17

0.76 1.16

&701.70

1.31 2.29

2.13 1.42

1977

7.10 1.34

24.22 1.35

4.84 0.31

2.08 0.54

10.63 0.61

6.02 1.53

7.99 0.71

1978

4.19 1.01

15.52 0.76

5.53 0.25

2.83 0.59

9.51 0.67

12.54 3.13

6.54 0.71

8.83 1.03

6.63 0.64

1979

6.61 1.26

1635 0.78

10.73 1.61

3.65 0.53

11.77 1.12

13.35 2.96

9.69 1.44

11.31 1.67

10.94 1.67

1980

14.67 2.99

30.36 2.59

9.27 1.73

6.92 1.43

14.49 1.06

21.94 4.31

ia53 2.12

13.72 3.22

14.36 2.05

1981

9.06 1.34

23.76 1.13

5.74 0.43

5.16 1.72

15.23 1.32

11.94 1.99

14.79 0.96

11.67 1.99

13.52 1.24

1982

5.50 2.94

44.44 1.42

2.73 0.83

1.79 1.21

13.29 0.50

13.89 3.05

3.85 0.39

5.39 0.64

12.90 1.30

1983

-0.77 0.45

64.47 1.76

1.35 0.66

0.39 0.75

13.68 2.73

17.40 1.95

2.21 0.43

3.91 085

11.20 L71

1984

-0.37 1.28

50.32 2.61 41.911.02

1.53 0.67

1.74 0.62

10.15 0.57

16.86 1.77

0.53 1.22

0.51 1.22

1985

-1.31 1.23

46.05 1.47

16.18 0.50

0.63 0.83

0.21 0.72

13.43 1.91

3.28 1.96

0.55 0.99

2.98 1.35

11.37 1.21

8.92 2.73

1986

1.03 1.48

59.63 1.14

2.23 0.94

0.98 0.75

-0.27 0.87

17.56 1.08

8.24 0.63

0.60 0.62

2.04 0.58

12.38 0.64

12.15 1.87

1987

0.89 0.76

8525 2.96

4.20 0.33

3.07 0.65

2.19 0.69

13.86 0.86

3.43 1.04

1.57 0.40

3.16 1.04

25.12 1.11

13.55 Z23

1988

-0.39 0.98

77.02 522

8.71 1.23

3.69 0.85

3.46 1.06

13.75 0.91

12.08 2.27

1.79 0.44

4.44 1.46

23.30 1.04

1974

31.06 3.96 9.52 0.60 6.71 0.62

10.82 2.34

14.89 3.11

1989

1.63 1.28

22.53 3.77

10.07 1.39

3.39 1.00

4.09 0.72

13.97 0.92

12.00 3.37

4.62 0.55

4.83 0.70

56.28 5.34

1990

4.36 0.63

24.36 1.46

11.50 1.12

4.13 0.46

3.37 0.73

14.38 0.39

31.89 11.96

3.59 0.38

5.66 0.68

34.15 0.99

1991

3.91 1.36

21.75 0.75

15.52 1.80

1.96 0.91

2.45 0.54

14.39 1.48

1613 4.14

3.38 1.11

5.77 1.15

2527 1.57

1992

2.77 1.36

13.82 0.88

7.48 0.88

1.48 1.03

2.00 0.42

14.19 2.26

3.41 2.26

4.58 0.82

3.44 0.77

2697 2.49

1993

5.64 0.92

2.62 6.08

6.65 0.64

1.64 0.92

3.11 0.82

9.53 0.69

5.84 2.58

3.39 0.44

2.64 0.95

31.42 1.56

1994

13.56 5.56

7.79 0.41

2.32 0.85

3.66 1.00

8.12 1.08

7.87 0.85

4.18 0.70

5.16 0.94

47.48 1.82

1995

29.47 1.82

7.68 0.57

1.32 0.56

a 16 0.35

7.83 2.02

3.59 0.20

5.79 1.06

43.55 1.27

1996

27.44 2.66

3.18 0.40

1997

14.30 0.27

1.05 0.48

1998

17.50 0.91

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Chapter 6 Stochastic Index Numbers

213

observation is that the estimate for the rate of inflation derived in (5.2) is also a weighted sum with the weights being the mean budget shares (w(), whereas the Divisia indices use the time-varying budget shares (wit). In Figure 6.5, we present a scatter plot of the standard error of inflation against the estimated rate of inflation for all 23 OECD countries combined. As can be seen, most of the time, the standard error increases along with the inflation but at a slower rate. In Figure 6.6, we plot the estimated inflation rates against the corresponding t-values. There is a distinct positive relationship between these two variables, which confirms the tendency of the standard error to rise less rapidly than inflation. Figures 6.7-6.8 present the same plots for all the LD countries combined. As we pointed out in the introduction to this chapter, most of the results derived in the previous sections are exclusively with prices and they could well be applied to quantities. The results, applied to the quantity data of the 23 OECD countries and the 23 LD countries, are presented in Tables 6.7 and 6.8, respectively. For each country, the two columns present the quantity index estimates and their standard errors (in adjacent columns). As can be seen, most of the point estimates are estimated precisely. As for the prices, the quantity index estimates obtained in Tables 6.7 and 6.8 are very close to the Divisia quantity indices presented in Tables 3.6 and 4.6, respectively, of Chapters 3 and 4. The reason for this observation is the same as that pointed out for prices in the last paragraph. Tables 6.9 and 6.10 present the estimates of relative quantity changes for the OECD and LD countries, respectively. In Figures 6.9 and 6.10, we present the scatter plots of the estimates of the quantity index against the corresponding standard errors and the estimates of the quantity index against the corresponding t-values for all 23 OECD countries combined. There is a distinct positive relationship between the quantity index

International Consumption Comparisons

214

* o o ,x. *-

8 -

I

6-

y = 0.041 x + 0.5261

• • •*

p i_ o •s ro •B

• V

4

•

Star

• • * 2."

-20

• •

^ - - — *

;&sj-^~~^^

0

20

40

60

80

Inflation rates (x100)

OECD inflation rate estimates vs their standard errors Figure 6.5

y = 0.7277X + 5.3671

* Inflation rates (x100)

OECD inflation rate estimates vs their t-values Figure 6.6

215

Chapter 6 Stochastic Index Numbers

40-

| i

20

J.

d M E M t / * ?

•

•'

y = 6.1749x + 4.3894

0 -

()

1

2

3

4

5

6

Inflation rates (x100)

LDC inflation rate estimates vs their standard errors Figure 6.7

• #

at o 3

.

•

•

y = 0.3988x + 5.7119

40

~•

CD

:> *"

20 -

0

20

40

60

80

Inflation rates (x100)

LDC inflation rate estimates vs their t-values Figure 6.8

216

International Consumption Comparisons

0.90 1.63

0.14 1.65

7.38 1.40

1962

3.26 1.59

3.67 0.42

5.31 1.53

1963 5.82 1.80

3.69 0.68

1.56 1.84

1964 2.86 0.62

1.77 1.15

Italy

1961 0.81 0.85

Ireland

(7)

Iceland

Finland

(6)

Greece

Denmark

(5)

(2)

Germany

Canada

(4)

(1)

France

Belgium

(3)

Year

Australia

Austria

Table 6.7 Quantity index estimates and their standard errors in 23 OECD countries

(8)

(9)

(10)

(11)

(12)

(13)

5.90 1.21

4.08 1.00

4.22 1.20

3.47 1.10

1.77 0.71

5.53 0.59

3.99 0.60

5.46 2.36

4.31 0.99

8.07 1.65

1953 1954 1955 1956 1957 1958 1959 1960

1.11 0.52

4.40 0.92

3.62 0.51

4.22 0.73

5.55 2.09

3.52 0.39

5.46 1.03

7.27 0.91

3.10 0.70

1966 3.20 0.62

3.14 0.90

2.50 0.71

3.50 056

2.19 1.18

4.34 0.42

1.93 0.22

6.88 0.36

6.62 0.72

1967 4.35 0.68

2.09 0.69

2.26 0.91

4.13 0.57

3.86 0.51

1.80 1.15

4.34 0.30

0.84 0.98

4.65 0.86

6.60 1.01

1968 4.35 0.68

3.63 0.41

5.32 0.83

2.20 0.61

2.46 1.24

0.50 1.07

3.09 0.65

4.26 0.62

6.58 1.42

4.41 0.28

1969 4.58 1.12

2.84 0.91

4.75 0.62

2.86 0.56

6.11 1.30

9.80 2 0 8

5.72 0.54

7.21 1.44

6.16 0.78

6.14 0.67

1970 2.73 0.63

6.26 1.21

4.40 0.59

0.88 1.69

2.88 1.03

7.42 0.89

3.85 0.51

609 0.89

7.92 2.57

6.61 0.66

1971 0.76 0.67

7.23 1.70

4.09 0.8B

637 1.67

0.30 1.22

2.13 1.27

5.24 0.75

3.79 0.60

6.07 1.24

2.42 0.44

1972

1.42 1.35

6.40 1.56

5.82 0.89

6.11 1.12

1.72 1.28

7.60 0.98

5.28 0.72

3.15 0.72

6.31 1.10

2.89 0.60

1973 6.80 2.45

3.74 1.11

6.30 1.93

5.44 1.50

5.77 1.18

5.55 1.71

4.79 0.58

1.39 0.91

8.03 1.44

1.60 0.82

0.56 1.22

2.47 1.42

4.01 0.50

-3.25 2.24

1.42 1.79

2 2 4 1.25

0.60 1.33

-1.03 1.59

-0.16 211

1.97 1.11

1975 2.03 0.84

2.70 0.47

0.23 1.51

2.75 0.63

3.11 1.44

2.00 1.59

2 6 4 0.51

3.52 a s s

5.01 1.16

-5.46 2 1 6

-1.91 0.91

1965

1974

5.06 0.97

1.34 0.83

3.53 0.78

4.56 0.84

4.35 0.51

7.08 1.12

0.51 1.82

5.28 0.87

4.30 tt47

4.70 0.92

1.52 2 2 6

2.99 0.36

1977 027 0.98

4.02 1.36

2.28 1.05

2.01 0.55

0.36 0.60

-1.37 1.00

2.53 0.54

4.01 0.76

3.40 1.32

5.50 0.90

1.95 0.67

1978 Z06 0.76

-0.29 2.04

2.39 0.70

2.65 0.48

0.16 0.84

289 0.85

4.18 0.46

3.82 a 4 2

5.01 0.76

8.12 2.65

6691.22

2.62 0.35

1.31 0.62

4.51 0.89

4.23 1.08

2.44 0.32

0.60 0.68

5.10 0.68

2.88 0.18

268 a77

1.46 1.03

-1.58 2 4 3

1.92 1.25

5.02 0.66

1980 2.09 0.78

2.01 0.61

1.69 1.45

0.74 0.74

-3.71 2.02

1.52 0.72

0.90 0.61

1.63 1.35

-1.76 1.87

3.24 1.31

-0.98 0.80

4.03 0.50 0.32 0.69

1976

1979

1981 2.27 0.47

0.51 1.00

a n 0.57

0.97 0.50

-1.38 1.13

1.34 1.00

1.60 0.38

-0.20 1.05

1.33 1.08

5.89 2 4 9

-0.11 1.43

1982 -0.11 0.84

1.06 0.65

2 0 2 1.12

-3.13 2.01

1.65 0.72

1.85 1.00

2.08 0.81

-1.10 0.64

1.02 1.52

5.94 1.72

-9.10 3.69

0.15 0.78

1983 0.80 0.71

4.15 0.84

-0.90 0.76

1.73 0.48

3.07 1.81

1.75 0.94

0.43 0.81

2.16 0.52

-0.89 1.57

-9.53 3.32

-2.43 1.20

-0.85 1.21

1984 2.59 0.40

-0.85 0.99

0.64 0.71

3.91 0.81

3.34 1.19

262 0.55

0.85 0.86

2.46 0.40

1.59 0.64

3.16 1.80

-1.14 1.14

1.91 0.47

1985 3.72 0.60

1.40 0.37

1.22 0.50

4.39 0.93

4.06 1.20

2.65 1.37

2.00 0.48

1.82 0.48

3.41 1.11

4.79 1.42

4.07 1.52

2.58 0.47

1986 -0.55 1.02

0.74 0.62

1.72 0.53

3.62 0.74

3.90 1.02

3.22 0.42

2.71 0.20

282 0.67

0.62 0.97

5.88 4.27

-0.43 1.48

3.07 0.44

1987 2.10 0.70

1.92 0.60

2.51 0.33

2.53 0.52

-1.94 1.28

4.57 0 6 6

2.23 0.43

4.71 1.75

1.50 1.55

8.88 3.01

3.60 0.87

3.46 0.71

1988 2.01 0.92

3.50 1.53

2.72 0.57

-0.99 049

-1.02 1.65

4.28 0.83

2.64 0.56

0.43 1.74

2.34 0.56

-2.62 3.28

4.33 1.36

3.63 0.65

1989 2.10 0.47

4.22 0.79

2.27 0.51

5.06 0.59

-0.28 0.67

3.54 0.42

2.67 0.53

1.37 0.63

2.01 0.66

-2.76 4.65

7.73 0.90

2.80 0.48

1990 -0.56 0.68

3.08 0.42

3.13 0.56

-1.07 0.75

-0.16 0.32

-1.25 1.21

2.02 0.39

5.27 0.79

0.89 0.42

-0.27 1.42

2 1 8 1.14

1.80 0.48

1991

1.46 0.38

2.01 0.61

2.28 0.42

-7.70 1.30

1.96 0.62

-3.73 241

0.64 0.68

4.29 0.67

0.86 0.64

0.05 1.23

1.97 0.70

3.91 0.55

1992 2.33 0.30

0.70 0.81

1.17 0.41

-0.21 0.30

1.07 0.76

-4.95 207

0.75 0.23

-0.23 0.59

1.08 0.97

4.60 1.88

253 055

0.70 0.36

1993 2.62 0.45

0.52 0.78

-2.00 1.06

0.59 0.41

1.28 0.42

-2.66 1.44

-0.40 0.82

-1.58 1.25

0.38 1.49

-4.30 1.45

234 0.41

-2.57 l.SS

-0.74 0.71

1.60 1.48

-1.35 1.21

4.84 1.12

1.04 0.37

0.18 1.09

4.% 1.48

3.44 1.06

1.27 0.42

5.60 1.41

5.63 1.73

0.37 0.58

1994 4.23 0.53

-2.87 0.65

1.13 0.56

2.55 0.56

5.92 2.76

1.62 0.44

0.77 0.52

1995 2.81 0.55

-6.59 1.05

0.56 0.47

0.36 0.57

0.62 0.52

3.55 0.74

0.85 0.47

1996 0.43 0.53

5.19 0.71

2.35 1.56

3.26 0.84

-1.17 0.43

Table 6.7 continued on next page

111

Chapter 6 Stochastic Index Numbers

Switzerland

*:

(18)

(19)

(20)

(21)

(22)

(23)

1.78 0.66 3.13 0.41 1.59 1.10 2.79 0.72 7.21 1.83 0.06 2.12 4.40 0.98 2.06 0.44 4.17 1.99 2.61 0.60 4.20 0.75 5.28 1.23 5.91 1.23 -2.02 2.11 3.71 0.62 2.20 0.84 0.00 0.92 0.26 0.87 0.79 0.45 2.92 0.57 8.92 2.08 3.96 0.95 -1.45 2.10 6.48 1.42 -2.40 1.98 8.28 5.08 -1.46 1.57 3.35 1.15 0.99 0.82 5.84 1.24 1.43 1.38 4.09 1.15 1.21 0.56 3.60 0.70 1.82 0.70 -0.54 1.04 3.92 0.88 2.02 0.89 2.16 0.58 1.28 0.47 3.98 1.48

6.60 1.14 7.31 2.32 5.29 0.58 5.75 1.07 6.27 0.66 3.42 0.36 4.08 0.49 7.48 1.61 6.78 1.09 3.94 1.28 1.62 0.72 3.76 0.36 1.46 0.29 0.49 0.63 0.24 1.22 -0.52 1.55 -0.69 0.85 -0.21 0.50 -1.49 2.00 -0.20 0.95 2.60 1.21 3.13 0.66 4.52 0.96 3.78 0.64 3.86 0.54 2.60 0.88 2.40 0.79 1.87 0.40 -1.80 1.58 1.24 0.19 1.46 0.71 1.75 0.39

4.32 0.95 3.41 0.83 0.98 1.16 1.79 0.83 3.95 1.12 3.45 0.59 0.72 0.52 -1.61 1.07 1.94 0.50 1.87 0.50 3.42 1.62 2.41 0.39 3.65 0.62 -1.43 0.97 -0.86 0.92 2.21 0.62 -1.23 0.68 -0.73 0.53 2.00 0.70 -1.11 0.51 1.52 0.21 2.36 0.65 4.14 1.39 3.98 1.48 1.76 0.90 0.56 1.02 -1.38 1.07 0.03 0.75 -2.19 1.39 -2.24 1.25 0.86 0.65 0.46 0.43 0.67 0.47

3

USA

Sweden

(15)

Spain

3

(16) (17) 5.81 1.59 6.54 1.57 5.74 1.43 6.68 1.33 -1.10 1.29 -1.62 1.57 4.77 1.07 5.64 1.21 4.95 0.82 5.58 0.62 7.92 0.57 4.44 1.97 6.89 1.27 1.45 1.62 3.75 1.04 5.10 1.11 7.40 1.61 6.33 1.41 5.20 0.43 4.37 1.13 2.17 0.45 7.85 0.95 4.24 0.87 2.61 1.46 7.67 1.02 3.62 0.57 3.00 0.81 -0.91 1.82 4.14 1.02 1.48 0.68 3.16 1.45 5.18 0.92 2.01 1.60 2.49 1.05 3.82 1.19 4.18 0.37 3.12 0.65 3.09 0.95 3.71 0.59 4.17 1.11 2.84 1.25 2.83 0.47 5.31 1.12 2.43 1.03 2.36 0.89 0.85 1.25 2.93 0.96 -0.88 1.11 0.52 0.67 -1.04 0.85 -3.03 1.52 3.64 0.91 1.68 1.80 -1.92 0.91 2.41 0.37 1.48 1.37 0.36 0.59 1.% 0.62 0.71 1.25 -1.05 0.67 2.70 0.48 2.66 0.96 2.62 0.75 1.03 0.54 3.12 2.36 2.68 0.91 2.00 0.78 1.97 0.38 3.20 1.00 3.44 0.61 4.16 1.12 1.79 0.58 1.74 1.09 4.11 0.84 3.16 0.45 0.26 0.72 0.17 1.22 3.92 0.78 1.30 0.90 2.89 0.41 0.34 1.02 3.86 0.86 3.69 1.15 3.64 0.67 -1.55 1.51 2.07 0.60 3.29 1.10 2.25 0.85 -3.18 1.18 1.57 0.72 1.60 0.53 0.15 0.96 -0.12 0.54 3.88 0.90 0.52 0.51 1.35 0.45 5.02 1.26 1.40 0.54 1.16 0.47 3.04 1.10 1.34 0.79 2.31 0.29 1.86 1.00 (14)

Portugal

(1) 1953 1954 1955 1956 1957 1958 1959 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 1970 1971 1972 1973 1974 1975 1976 1977 1978 1979 1980 1981 1982 1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 1996

E

Norway

Year

Japan

2

Netherlands

Table 6.7 (continued) Quantity index estimates and their standard errors in 23 OECD countries

(24)

3.71 0.73 2.51 0.39 2.89 1.10 2.20 0.73 2.08 0.47 1.83 0.31 2.58 0.28 4.09 0.50 4.26 0.43 3.72 0.52 2.71 0.38 1.91 0.90 -0.56 0.82 -2.36 1.06 1.69 0.70 3.17 0.55 1.09 0.75 0.86 0.50 3.10 0.42 0.17 0.57 -0.89 0.16 1.10 0.40 1.16 0.36 0.86 0.33 2.28 0.34 1.07 0.20 1.27 0.39 1.35 0.40 0.61 0.25 0.25 0.59 -1.52 0.45 -2.09 0.71 -0.96 0.42

1.18 1.04 4.21 0.96 2.58 0.90 0.73 0.61 1.54 0.67 2.10 0.45 2.97 0.40 0.28 0.65 2.60 0.42 2.89 0.94 5.83 0.91 4.94 1.01 -1.01 1.61 -0.50 0.36 1.12 0.70 0.18 0.73 4.67 0.73 4.00 0.42 -1.88 0.71 -0.80 0.65 0.73 0.25 3.87 0.46 1.86 0.60 3.52 0.45 5.80 1.05 4.56 0.73 6.10 1.74 2.58 0.89 0.16 0.66 -1.61 1.01 -1.46 1.30 2.43 0.38 2.30 0.55 1.14 0.72 3.08 0.53

3.46 0.69 2.72 0.48 4.17 0.47 4.32 0.61 3.96 0.42 1.88 0.50 4.30 0.67 2.67 0.67 1.15 1.01 2.44 0.97 4.90 0.67 4.05 0.68 -1.58 1.29 1.23 0.70 4.38 0.77 3.29 0.57 3.03 0.72 1.26 0.71 -1.26 1.60 0.65 0.59 -0.21 0.58 3.75 0.96 3.98 0.86 3.38 0.58 2.96 0.46 1.71 0.55 2.95 0.25 1.55 0.31 0.46 0.60 -1.90 1.26 1.80 0.46 1.80 0.47 2.12 0.52 1.44 0.35 2.01 0.68

International Consumption

218

Comparisons

Ecuador

Fiji

Honduras

Hong Kong

Hungary

India

Iran

Israel

Jamaica

Korea

(1) 1961 1962

Cyprus

Year

Colombia

Table &8 Quantity index estimates and their standard errors in 23 I D oouitries

(2)

(3)

(4)

(5)

(6)

(7)

(8)

(9)

(10)

(11)

(12)

(13)

1963 1964 1965 1966 1967 1968 1969 1970 1971

284165

616 1.67

4.24 1.34

1972

-1.52 087

519 1.46

7.04096

1973 287 1.13 1974 4.11 1.19 1975 0.93 1.14 1976 4.67 0.91 1977 1.73 1.25

146 1.21

664 O90 7.15056 543 076 4.77 267

1060 1065 7.25 225 -297069 -6.35 562

1978

298143

1979 1980 1981 1982 1983 1984

606 Q65 220 1.14

1451.25 -185272 150 1.41

-002 083 -0421.89 274 076 6961.75 4.23 087 1293 516

260109 593 099

264150 aw aso 14.77196 3.99133 -175094 547 202

-1.77 1.68

4.25 039 7.32 087

4.02 1.20 -215177 -6.86103 4.93118

270045 173183 3.82 078 ###345 282 078 559 3.89 216 029 -162 253 -569144 297 041 074 036 -1.16 656 1.50073 250 220 -551073 519 090 7.73 4.19 -097 Q82 -053 076 9.07 1.00 005051 455177 -7.44083 2391.57 -275 1.11 694235 0911.36 553 1.19 -1.78 073 13.21 4.24 -556199 270110 5551.03 162193 9.56277 068 084 4.47 286 -012 103 -1.39088 168 073 1.68035 207 071 3.27102 -880 554 648121 1985 -017 090 110 082 036 064 023 202 257 082 1.45 Q80 082 1.05 -014105 111 3.17 -109 210 1986 1.21041 535 1.51 0.05 075 4.95 205 6741.06 228 065 100 097 ### 120 9.57 285 -155198 1987 1.85 068 6.201.24 -O11O70 -132 250 10441.76 546 138 169 030 4.22156 7.23153 a43100 1988 1.91 044 9.95 204 -034 095 669166 7.10 1.66 -3.91 188 193 057 -3.06 3.89 2001.24 1.77 1.50 235 1.17 236099 222 Q61 1.98 3.51 -1.14187 1989 1.31089 a58200 018 041 260 076 1990 1.20 045 5781.00 -010 031 1.92 221 4.52 1.40 -3.19 204 174 032 1627 291 1.82 076 1991 -0.15 051 103 213 -032 062 -OS 158 535 209 -6.54 209 -014146 aC8 8.81 -060086 7.73 202 091069 191029 147 233 592163 1992 246 059 6,291.05 024 072 6111.41 Q84119 263055 -035 278 4.56 1.35 1993 -6.53193 043 075 1994 S4S195 -0311.03 207 077 060 210 5701.08 3.21083 1995 1996 1997

-3.80 199

3.45058 4.14 111

4.77 093

6.02 1.16 a391.30 6731.34 -2.12 1.92 1.90 088 5.79 1.53 7.85065 614136 4.90146 7.84 081 7.30 048 695031 a00O44 a i£ 0 4 1 7.46047 507 066 4.13 078 564 032 6.71046 5.05 067

1998 TiUe6.8aTtin£dnetpag2

219

Chapter 6 Stochastic Index Numbers Table 6.8 (continued)

Zimbabwe

(18)

Venezuela

(17)

Thailand

(16)

Taiwan

Singapore

(15)

Sri Lanka

Puerto Rico

(14)

South Africa

Philippines

(1) 1961

Mexico

Year

Malta

Quantity index esJinubas and their standard errors in 23 LD countries

(19)

(20)

(21)

(22)

(23)

(24)

-1.83 1.27

1962

0.74 0.43 3.27 1.09

4.08 0.54

1964

635 1.80

-4.11 1.27

4.69 1.33

11.68 266

1965

5.96 1.27

3.21 0.97

-3.39 0.60

7.56 1.07

1966

3.09 3.18

5091.75

1.70 0.29

3.68 1.00

1967

4.75 1.57

5.08 1.61

1.65 0.26

a291.70

1968

9.29 1.83

6.97 0.71

4.13 0.58

7.19 0.66

1969

5.65 117

7.54 1.25

3.53 0.64

5.47 0.69

1970

a 17 1.75 10.82 0.72

3.96 0.74

5.90 1.17

4.10 1.49

6.96 0.84

213 1.07

7.111.25

1963

1971

233 0.92

1972

4.31 1.37

4.54 0.96

7.67 0.58

1.09 1.06

a89 0.47

1973

4.08 0.65

-4.45 202

7.09 1.10

5.16 0.79

10.98 121

1.72 1.04

-3.37 210

4.17 2.25

285 1.33

1975

8.13 1.71

1.85 0.45

5.61 289

1.08 1.38

-0.06 0.64

-a80 280

4.52 0.42

1976

7.59 Z30

1.22 0.59

5.52 1.57

4.111.28

0.26 237

3.84 298

5.49 0.42

1977 15.24 4.90

0.96 0.72

3.81 1.27

5.12 1.30

-259 1.83 10.01 1.85

5.41 0.51

1974

3.71 127 -1.92 3.01 670 0.97

-13.97 1.53 4.46 4.14

7.74 2.46

4.85 1.12

2.20 1.12

691 0.82

-0.46 105

268 5.39

7.21 0.82

5.20 0.85

1979 10.52 1.77

5.88 1.19

-0.33 209

7.75 0.96

145 0.68

834 1.66

828 207

3.69 1.43

a79 3.69

9.26 4.55

3.97 0.47

-281 269

6.91 0.97

601200

5.48 3.51

3.56 0.62

3.39 0.72

-3.79 637

1981 -5.92 2.00

3.89 1.09

-100 1.75

603 1.41

3.89 1.02

2061.84

1.72 0.74

0.55 1.49

1283 4.22

1962 -8.54 260

-3.03 2,07

1.88 1.20

261 0.82

0.04 1.02

214 1.82

264 0.90

0.78 0.74

-644 291

1983 -217 1.28

-6.76 202

3.04 206

7.76 0.68

-6.76 0.91

-1.00 3.08

4.15 0.67

4.96 0.69

1132 4.91

1984

0.74 0.78

0.32 1.04

-217 0.35

3.86 1.98

2281.48

3.44133

-4.04 3.41

673 0.77

3.02 129

1985

6.46 296

0.75 111

-3.61 0.36

3.18127

-3.84 2.67

-5.47 219

3.55 1.56

3.69 0.86

-0.04 1.49

0.09 1.90

-a78a44

1966

3.42 242

-4.32 1.06

0.86 0.27

4.86 1.54

3.31 1.52

-3.09 203

-0.57 1.64

600 0.70

225 0.56

275 107

-1.64 4.23

1967

7.01 1.29

-235 1.31

1.57 0.43

3.03 0.86

a411.89

153 1.18

287 1.87

a81 0.82

7.26 1.82

1.80 0.47 -20.59 3.35

1988 10.20 273

-0.90 0.85

3.65 0.46

-0.10 1.10

1.42 1.28

3.09 135

3.27 0.83

10.28 1.38

828105

1.90 0.29

7.05 1.49

4.62 0.53

255 0.27

0.50 1.07

4.91 1.49

0.90 0.72

-0.74 260

9.82 1.81

a74 0.86

-9.29 235

1990

3.20 1.82

3.48 0.43

296 0.44

-247 1.02

2941.89

0.44 0.62

# # # 1163 634 109

a70 1.31

-0.411.26

1991

4.15 232

207 0.53

-1.31 0.19

1.49 1.38

0.72 2.05

-3.46 0.54

-0.48 211

589 1.45

3.34 0.76

5211.41

1992

1.92 1.90

225 0.43

0.65 0.38

3.25 210

3.96 1.59

-4.09 1.24

7.14 261

670 0.67

642 1.28

5.42 0.99

1993 1994

3.23 206

-0.61 0.89

2.34 1.43 1.92 1.94

5.38 1.35

-1.84 0.76

685 294

647 0.53

5.84 0.96

-296 201

0.75 0.82

1.04 0.62

634 1.34

7.10 1.42

560 1.05

-6.31 1.85

-144 0.76

259 1.04

1.98 0.92

4.28 1.61

7.20 0.51

0.28 0.58

1978 I960

1989

229 0.65

0.50 0.14 1.22 0.08

1995

-7.80 266

1.36 0.28

1996

-4.83 0.85

5.25 109

1997

6541.03

632 1.17

1996

5.02 0.50

-3269 261

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Chapter 6 Stochastic Index Numbers

.a n

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222

Standard errors (x100)

International Consumption

y= -0.0054X + 0.9469 *

•

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•

*

3.5-

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Quantity index estimates (x100)

OECD quantity index estimates vs their standard errors Figure 6.9

y=0.9279x +1.0852 15

-46Quantity index estimates (x100)

OECD quantity index estimates vs their t-values Figure 6.10

Comparisons

223

Chapter 6 Stochastic Index Numbers

y = -0.027x +1.5899 o

y

12

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&

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Quantity index estimates (x100)

LDC quantity index estimates vs their standard errors Figure 6.11

y = 0.6403x +1.1833

23

X -so

-eeQuantity index estimates (x100)

LDC quantity index estimates vs their t-values Figure 6.12

224

International Consumption Comparisons

estimates and the corresponding t-values (with a slope coefficient of .59, which is less than one), which confirms the tendency of the standard error to rise less rapidly than the quantity index. Figures 6.11-6.12 present the same plots for all the LD countries combined.

6.8 Conclusion In this chapter, we introduced the recent developments in index number measurements based on the stochastic approach. We showed how this renewed approach can be used to measure the movement in prices and consumption growth in the OECD and LD countries. The main attraction of the stochastic approach is that it provides the point estimates of growth as well as the corresponding standard errors.

References Balk, B.M. (1980). 'A Method for Constructing Price Indices for Seasonal Commodities,' Journal of the Royal Statistical Society, Series A, 142, Part I: 68-75. Clements, K.W. and H.Y Izan (1981). 'A Note on Estimating Divisia Index Numbers,' International Economic Review 22: 745-747. Clements, K.W., and H.Y Izan (1987). 'The Measurement of Inflation: A Stochastic Approach,' Journal of Business and Economic Statistics 5: 339-350. Crompton, P. (2000). 'Extending the Stochastic Approach to Index Numbers,' Applied Economics Letters 7: 367-371.

225

Chapter 6 Stochastic Index Numbers

Diewert, W.E. (1981). 'The Economic Theory of Index Numbers: A Survey,' in A Deaton (ed.), Essays in the Theory of Consumer Behaviour. Cambridge: Cambridge University Press. Diewert, W.E. (1995). 'On the Stochastic Approach to Index Numbers,' Discussion Paper No. 95-31, Department of Economics, University of British Columbia. Frisch, R. (1936). 'Annual Survey of General Theory: The Problem of Index Numbers,' Econometrica 4: 1-38. Rao, D.S.P., T. Doran and E.A. Selvanathan (2002). 'Estimation of General and Commodity-Specific

Inflation

Rates

Using

Linear

Time-Varying

Constraints,' Journal of Agricultural and Applied Economics 34: 61-1 A. Rao, D.S.P., and E.A. Selvanathan (1991). 'A Log-Change Index Number Formula for Multilateral Comparisons,' Economics Letters 35: 297-300. Rao, D.S.P., and E.A. Selvanathan (1992). 'Uniformly Minimum Variance Unbiased Estimators of Theil-Tornqvist Index Numbers,'

Economics

Letters 39: 123-127. Rao, D.S.P., and E.A. Selvanathan (1996). 'On the Stochastic Approach to International Comparisons of Prices, GDP and Productivity,' in D.S.P. Rao and J. Salazar-Carrillo (eds.), International Comparison of Prices, Output and Productivity. Elsevier North-Holland Publishing Company, pp. 195-216. Rao, D.S.P., E.A. Selvanathan and D. Pilat (1995). 'Generalized Theil-Tornqvist Indices with Applications to International Comparisons of Prices and Real Output,' Review of Economics and Statistics LXXVII: 352-360. Selvanathan, E.A. (1989). 'A Note on the Stochastic Approach to Index Numbers,' Journal of Business and Economic Statistics 7: 471-474. Selvanathan, E.A. (1991). 'Standard Errors for Laspeyres and Paasche Index Numbers,' Economics Letters 35: 35-38.

226

International Consumption Comparisons

Selvanathan, E.A. (1993). 'More on Laspeyres Index Numbers,'

Economics

Letters 43: 157-162. Selvanathan, E.A. (2002). 'Extending the Stochastic Index Numbers,' Applied Economics Letters, forthcomig. Selvanathan, E.A., and D.S.P. Rao (1992a). 'Computation of Standard Errors for Geary-Khamis Parities and International Prices,' Journal of Business and Economics Statistics 10(1): 109-115. Selvanathan, E.A., and D.S.P. Rao (1992b). 'An Econometrics Approach to the Construction of Generalized Theil-Tornqvist Indices for Multilateral Comparisons,' Journal of Econometrics 54: 335-346. Selvanathan, E.A,. and D.S.P. Rao (1994). Index Numbers: A

Stochastic

Approach. London: Macmillan Publishers. Selvanathan, E.A., and S. Selvanathan (2003). 'Modelling the Commodity Prices in the OECD Countries: A Stochastic Approach,'

Economic

Modelling, forthcoming. Theil, H., F.E. Suhm, and J.F. Meisner (1981). International

Consumption

Comparisons: A System-Wide Analysis. Amsterdam: North-Holland.

CHAPTER 7

Testing Demand Theory Hypotheses: O E C D and LD Countries S. Selvanathan &E.A. Selvanathan

In Chapter 2, we pointed out that estimating a system of demand equations in an unrestricted fashion requires the estimation of an impossibly large number of coefficients. In many demand analysis applications, a priori restrictions such as demand homogeneity and Slutsky symmetry are imposed, thus reducing the number of unknown parameters. In a review article on systems of consumer demand functions, Barten (1977) summarizes the results from various empirical applications, which test the validity of the hypotheses of homogeneity and symmetry. These results show that homogeneity is generally not acceptable, while symmetry is a bit more acceptable. Barten concludes that one reason for these negative results is that since the test procedures are usually based on the asymptotic distribution of the test statistic without correction for small-sample bias, the results are biased towards rejection. Simulations by Bera et al (1981), Bewley (1983). Laitinen (1978) and Meisner (1979) have confirmed this conclusion. In view of these difficulties, Laitinen (1978) developed a finitesample test for testing homogeneity and Theil (1987) developed alternative distribution-free testing procedures for testing homogeneity and symmetry. Various aspects of testing demand theory hypotheses have also been researched in recent times by many researchers (for example, see Attfield, 1997, 1998; Buse, 1988; Cribari and Zarkos, 1997; Deschamps, 2000; Karagiannis and Mergos,

International Consumption Comparisons

228

2002; Keuzenkamp, 2000; Keuzenkamp and Barten, 1995; Muellbauer and Peshardes, 1992; Ng, 1995; and Pollak and Wales, 1992). In Chapter 2, we presented the theoretical framework of consumer demand and, in Chapters 3 and 4, we presented preliminary data analysis for the OECD and LDC data based on some of the theoretical results presented in Chapter 2 and the data-analytic techniques introduced in Selvanathan (1995). In this chapter, we present a detailed account of the conventional tests used for testing the demand theory hypotheses, homogeneity and symmetry, and illustrate their application using the OECD and LDC data. In Chapter 8, we test these hypotheses using alternative demand systems such as the AIDS, CBS and NBR introduced in Chapter 2. In Chapter 9, we test the hypothesis of preference independent structures among goods. The organisation of this chapter is as follows. In Section 7.1, we present the demand model and in Sections 7.2 and 7.3, we discuss the conventional tests for the demand theory hypotheses, homogeneity and symmetry. In Section 7.4, we present the summary results and our concluding comments.

7.1

The Demand Model

For commodity i (=[,...,n, the number of goods) and period t (=1,...,T, the sample size after lagging), the absolute price version of the Rotterdam model (3.21) from Section 2.3 with an error term added can be written as wit Dq« = Gi DQt + £ KijDpjt + eit.

(1.1)

where 0j is the i* marginal share satisfying Z"=i0/ = 1; TCy is the (ij)* Slutsky coefficient satisfying Zf=17ty =0; and all other notations are as defined in

229

Chapter 7 Testing Demand Theory Hypotheses

Chapter 2. The error terms are assumed to be normally distributed with zero mean and are independent over time. Equation (1.1) for i=l,...,n is a fairly general demand system in the sense that it can be considered as a first-order approximation to the true demand equations. If we sum both sides of (1.1) over i=l,...,n, we get Z"=ie,i = 0 f° r t=l,...,T. Therefore, the eit's are linearly dependent and one of the equations is redundant and can be deleted (Barten, 1969). We delete the n-th equation. It can be shown that the best linear unbiased estimators of the parameters for the system of equations (1.1) for i=l,...,n are the same as those obtained by estimating each equation separately by least squares (LS). See Theil (1971) for details. Let 2 be the (n-l)x(n-l) contemporaneous covariance matrix of the disturbance term eit of (1.1) for i=l,...,n-l. In general, S is unknown. For estimation and hypothesis testing, it is common practice to approximate this matrix by its unbiased estimator S, the matrix of mean squares and cross products of the LS residuals. Denoting yit = wit Dqit, yi = [8j nn ... nm]' and xt = [DQt Dph ... Dpnt]', and deleting the n* equation, (1.1) can be written for t=l,...,T as y,

= Xyi + Ei,

i=l,...,n,

(1.2)

where jj = \ylt] is a T-vector; X is a T x (n+1) matrix whose t* row is x't; and Ei = [Eit] is a T-vector. We write (1.2) for i=l,...,«-l as y

=

( I „ . , ® X ) Y + E,

(1.3)

where I„_i is the identity matrix of order («-l); y = [VJ], y = fy] and E = [E(] are vectors consisting of (n-1) subvectors; and ® is the Kronecker product.

International Consumption Comparisons

230

7.2

Demand Homogeneity

Here we reproduce the demand homogeneity restriction (3.17) introduced in Section 2.3:

171, = 0,

i=l,...,n.

(2.1)

Let a = [0 1 ... 1]' be a (w+l)-vector. Then, demand homogeneity, (2.1), can be written in vector form as a'Yi= 0,

i=l,...,/i.

For i=l, ...,n-l, this can be expressed as RY = 0,

(2.2)

where R = I„_i ® a'.

The Asymptotic Test of Homogeneity

The test statistic for testing the homogeneity restriction (2.2) is

trZ - 1 S

(2.3)

Chapter 7 Testing Demand Theory Hypotheses

231

where y 1S the LS estimator of y, 2 is the error covariance matrix; and S is the LS residual moment matrix, an unbiased estimator of 2 (Theil, 1971). When E is known, under the null hypothesis, (2.3) is distributed as F with (n-l) and (n-l)(T-n-2) degrees of freedom. Usually, the error covariance matrix S is unknown and is replaced by its estimator S. The test statistic for homogeneity then becomes

(Ryys-(RV) H

a'CX'Xr'a

Under the null hypothesis, it can be easily shown that, T H has an asymptotic x2 distribution with (n-l) degrees of freedom. It is worth noting that as (2.4) involves S"\ S must be non-singular. The necessary condition for S to be non-singular is that T- 2ra > 1 (Laitinen, 1978). Laitinen's Exact Test for Homogeneity

Laitinen (1978) derived the exact finite-sample distribution of ^ H in (2.4) under the null hypothesis of demand homogeneity restriction. Laitinen showed that *FH is distributed as a Hotelling's T2, which itself is distributed as a constant multiple («-l)(T-n-2)/(T-2n) of F(«-l,T-2n). This exact test is very useful in applications where the sample size is relatively small. Application of the tests of homogeneity to the OECD data

Table 7.1 presents the sample size after lagging (T) and the number of commodities (n) in columns 2 and 3 for the 23 OECD countries. The last column presents the value of (T-2n) which is used to verify the necessary condition for

International Consumption Comparisons

232

Table 7.1 Further characteristics of the OECD database Country (1) 1. Australia

Sample size after lagging T (2) 36

Number of commodities n (3) 9

T-2n (4) 18

2.

Austria

32

9

14

3.

Belgium

36

4.

Canada

35

8 9

20 17

5.

Denmark

29

9

11

6.

Finland

36

8

20

7.

France

32

9

14

8.

Germany

33

8

17

9.

Greece

34

9

16

10. Iceland

19

9

1

11. Ireland

23

9

5

12. Italy

32

9

14

13. Japan

26

8

10

14. Luxembourg

21

8

5

15. Netherlands

44

8

28

16. New Zealand

12

5

2

17. Norway 18. Portugal

32

9

14

9

8

-7

19. Spain

32

8

16

20. Sweden

33

9

15

21. Switzerland

33

8

17

22. UK

35

8

23. USA

35

9

19 17

Chapter 7 Testing Demand Theory Hypotheses

233

the non-singularity of the error covariance matrix S. Among the 23 OECD countries considered, S is non-singular (i.e., T-2n > 1) for 21 countries and singular (i.e., T-2n < 1) for the remaining 2 countries, New Zealand and Portugal. In order to achieve non-singularity of S for New Zealand, we aggregate the commodities into n = 5 commodity groups so that T-2n = 2 > 1 (where the housing group includes housing and durables; and the miscellaneous group includes transport, recreation, education and miscellaneous). As the sample size for Portugal is only 8, we drop Portugal from our analysis. We now calculate the test statistic (2.4) to test homogeneity using the data from 22 OECD countries (after dropping Portugal and using only 5 commodity groups for New Zealand). The results from the homogeneity test for the OECD countries are shown in Table 7.2. The observed values of the test statistic (2.4) are presented in column 2 of the table. The critical values at the 5 percent level of significance for the asymptotic %2-test are presented in column 3. Comparing column 2 with column 3, we see that homogeneity is acceptable only for 9 of the 22 OECD countries. These results are consistent with the results from most previous studies where the asymptotic test was used to test homogeneity (e.g., Selvanathan, 1993; Theil and Clements, 1987; and Chen 2001). Now we employ Laitinen's exact test to test the hypothesis of demand homogeneity. For the 22 OECD countries, the observed and critical values based on exact distributions are presented in columns 5 and 6 of Table 7.2. Comparing the observed values of the test statistic in column 5 with the critical values in column 6, we can see that homogeneity is now acceptable for all countries except Greece and the USA. These results support the view of Barten (1977) that the rejection of homogeneity is due to the failure of the asymptotic test.

International Consumption Comparisons

234

Table 7.2 Testing homogeneity in 22 OECD countries Asymptotic x2 test

Laitinen's exact test

Country

(1) 1. Australia

Data-based Critical Conclusion Data-based Critical Conclusion ¥H x2("-1.-05) T2 F(n-1 ,T-2n,a) (2) (3) (4) (5) (6) (7) 2 Do not rej F(8,18)=2.51 Do not rej 12.24 X (8)=15.51 1.10

2. Austria

12.38

X2(8)=15.51

Do not rej

1.03

F(8,14)=2.70

3. Belgium

23.31

X2(7)=14.07

Reject

2.56

F(7,20)=3.70* Do not rej*

4. Canada

9.59

Z2(8)=15.51

Do not rej

0.85

F(8,17)=2.55

Do not rej

5. Denmark

22.27

X2(8)=15.51

Reject

1.70

F(8,11)=2.95

Do not rej

6. Finland

27.92

X2(7)=14.07

Reject

3.07

F(7,20)=3.70* Do not rej*

7. France

44.64

X2(8)=15.51

Reject

3.72

F(8,14)=4.14* Do not rej*

2

Do not rej

8. Germany

17.13

X (7)=18.48*

Do not rej*

1.81

F(7,17)=2.61

Do not rej

9. Greece

64.52

X2(8)=15.51

Reject

5.61

F(8,16)=2.59

Reject

10 Iceland

58.31

X2(8)=15.51

Reject

0.91

F(8,1)=238.9

Do not rej

11 Ireland

154.35

X2(8)=15.51

Reject

8.04

F(8,5)=10.29*

Do not rej*

12 Italy

15.81

X2(8)=20.09*

Do not rej*

1.32

F(8,14)=2.70

Do not rej

13 Japan

40.76

X2(7)=14.07

Reject

3.64

F(7,10)=5.20* Do not rej*

14 Luxembourg

19.31

X2(7)=14.07

Reject

1.25

F(7,5)=4.88

15 Netherlands

2

Do not rej

X {7)=14.07

Reject

2.98

F(7,28)=3.36* Do not rej*

X2(4)= 9.49

Reject

1.89

F(4,2)= 19.25

Do not rej

X2(8)=20.09*

Do not rej*

1.43

F(8,14)=2.70

Do not rej

18 Spain

17.18 14.79

X2(7)=18.48*

Do not rej*

1.54

F(7,16)=2.66

Do not rej

19 Sweden

24.65

X2(8)=15.51

Reject

2.10

F(8,15)=2.64

Do not rej

20 Switzerland

16.52

X2(7)=18.48*

Do not rej*

1.74

F(7,17)=2.61

Do not rej

8.17

X2(7)=14.07

Do not rej

0.89

F(7,19)=2.54

Do not rej

56.77

X2(8)=15.51

Reject

5.03

F(8,17)=2.55

Reject

16. New Zealand 17 Norway

21. UK 22. USA

25.32 18.89

The level of significance a = 0.05. A * denotes critical value and conclusion at a = 0.01.

Chapter 7 Testing Demand Theory Hypotheses

235

Application of the tests of homogeneity to the LDC data

Table 7.3 presents the sample size after lagging (T) and the number of commodities (n) in columns 2 and 3 for the 23 LD countries. The last column presents the value of (T-2«) which is used to verify the non-singularity condition (T-2n > 1). For the original data, S is non-singular for 17 LD countries and singular or near-singular for the remaining 6 countries, Honduras, Hungary, India, Iran, Jamaica and Philippines. In order to achieve non-singularity of S for these 6 countries, we aggregate some of the commodities to achieve nonsingularity. The number of commodity groups presented in column 3 for these countries reflect the number of combined commodity groups. Table 7.4 presents the results for testing homogeneity for the LD countries. Columns 2-4 of the table present the results based on the asymptotic test statistic. As can be seen, homogeneity is acceptable only for 11 of the 23 countries. This result is also consistent with the findings of the OECD results. Columns 5-7 of Table 7.4 present the exact homogeneity test results for the 23 LD countries. As with the results for the OECD countries, using the exact test, homogeneity is now acceptable for all LD countries. As pointed out in the introduction to this chapter, the reason for the universal rejection of homogeneity could be due to the test procedures that are based on asymptotic distribution without correction for small sample bias. The results in this chapter for testing the homogeneity restriction for the OECD and LD countries using asymptotic and exact tests support this.

7.3

Slutsky Symmetry

We now take homogeneity as given and consider symmetry. The homogeneityconstrained version of model (1.1) is obtained by imposing the homogeneity

International Consumption Comparisons

236

Table 7.3 Further characteristics of the LDC database Country

(D

Sample size after lagging T (2) 20

Number of commodities n (3) 9

T-2n (4) 2

1.

Colombia

2.

Cyprus

14

6

2

3.

Ecuador

20

7

6

4.

Fiji

14

6

2

5.

Honduras

12

5

2

6.

Hong Kong

25

9

7

7.

Hungary

11

5

1

8.

India

15

7

1

9.

Iran

12

5

2

10. Israel

25

9

7

11. Jamaica

14

6

2

12. Korea

22

8

6

13. Malta

20

8

4

14. Mexico

28

8

12

15. Philippines

12

5

2

16. Puerto Rico

31

8

15

17. Singapore

32

8

16

18. South Africa

35

8

19

19. Sri Lanka

21

8

5

20. Taiwan

35

8

19 3

21. Thailand

19

8

22. Venezuela

11

5

1

23. Zimbabwe

12

5

2

Chapter 7 Testing Demand Theory Hypotheses

237

Table 7.4 Testing homogeneity in 23 LD countries Asymptotic %2 test

Laitinen's exact test

Country

(D 1. Colombia 2. Cyprus

Data-based Critical Conclusion H»H X2("-1,.05) (3) (4) (2) 2 Reject 268.72 Z (8)=15.51 21.36

X2(5)=11.07 2

Data-based Critical Conclusion T2 F(n-1 ,T-2n,<x) (5) (6) (7) F(8,2)=19.37 Do not rej 7.46

Reject

1.42

F(5,2)=19.30

Do not rej

3. Ecuador

14.84

1.35

F(6,6)=4.28

Do not rej

15.80

X (6)=16.81* 3C2(5)=11.07

Do not rej*

4. Fiji

Reject

1.06

F(5,2)=19.30

Do not rej

5. Honduras

13.74

5C2(4)=9.49

Reject

1.37

F(4,2)=19.25

Do not rej

6. Hong Kong

13.40

Do not rej

0.84

Do not rej

0.29

F(8,7)= 3.73 F(4,1)=224.6

Do not rej

4.58

X2(8)=15.51 *2(4)=9.49

8. India

191.76

Z2(6)=12.59

Reject

3.33

F(6,1)=234

Do not rej

9. Iran

15.14

X2(4)=9.49

Reject

1.51

F(4,2)=19.25

Do not rej

7.57

X2(8)=15.51

Do not rej

0.47

F(8,7)=3.73

Do not rej

7. Hungary

10. Israel 11. Jamaica

2

Do not rej

139.32

X (5)=11.07

Reject

9.29

F(5,2)=19.30

Do not rej

12. Korea

8.79

X2(7)=14.07

Do not rej

0.63

F(7,6)=4.21

Do not rej

13. Malta

27.70

Reject

1.32

F(7,3)=8.89

Do not rej

14. Mexico

19.16

5C2(7)=14.07 X2(7)=14.07

Reject

1.83

F(7,12)=2.91

Do not rej

15. Philippines

72.83

JC2(4)=9.49

Reject

7.28

F(4,2)=19.25

Do not rej

16. Puerto Rico

10.32

X2(7)=14.07

Do not rej

1.05

F(7,15)=2.71

Do not rej

17. Singapore

14.96

5C2(7)=18.47*

Do not rej*

1.55

F(7,16)=2.66

Do not rej

2.94

5C2(7)=14.07

Do not rej

0.32

F(7,19)=2.54

Do not rej

19. Sri Lanka

27.01

X2(7)=14.07

Reject

1.75

F(7,5)=4.88

Do not rej

20. Taiwan

13.87

X2(7)=14.07

Do not rej

1.51

F(7,19)=2.54

Do not rej

21. Thailand

23.64

X2(7)=14.07

Reject

1.12

F(7,3)=8.89

Do not rej

22. Venezuela

1.91

X2(4)=9.49

Do not rej

0.12

F(4,1)=224.6

Do not rej

23. Zimbabwe

1.46

X2(4)=9.49

Do not rej

0.15

F(4,2)=19.25

Do not rej

18. South Africa

The level of significance a = 0.05. A * denotes critical value and conclusion at a = 0.01.

238

International Consumption

Comparisons

restriction (2.1) on (1.1), Jit = OiDgt + S1 7iu(Dpjt-Dpm)+ eit,

Let Y,H= [9i % ••• "in-il' a n d Then, (3.1) can be written as

ji

= X H Y r + 6i,

x

i=l,...,n; t=l,...,T.

(3.1)

? = [DQt (DPn - DPm) ••• (DPn-i,t - D/V>]'-

i=l,...,n,

(3.2)

where XH is a T x n matrix whose Ith row is xf1'; andji and £j are as before. As for the unconstrained case, it can be shown that the best linear unbiased estimators of the Yi 's in (3.2) are the single-equation LS estimators (Theil, 1971). As before, we delete the n*equation and write (3.2) in matrix form as

y

= (I®X H )Y H + e,

(3.3)

where I is the identity matrix of order (n-l); y^ = [ Yj ] is a vector consisting of (n-l) subvectors; and y and E are as before. Let Y; be the LS estimator of Yi for i=l,...,n; and Y = [ Yi ] be the vector consisting of (n-l) subvectors. Here, we reproduce the Slutsky symmetry restriction, given by (3.18) from Section 2.3: 7tjj = 7Iji,

i,j=l,...,7l.

(3.4)

Chapter 7 Testing Demand Theory Hypotheses

239

In vector form, for i,j=l,...,n-l, the symmetry restrictions (3.4) can be written as Rf

= 0,

(3.5)

where R is a q x n(n-\) matrix with q = }4(W-I)(AI-2) and each row of R consists of zeros except for a 1 and a -1 corresponding to 7iy and np for some i^j. The test statistic for symmetry is

;

,

(3-6)

[q/(n-l)]trTlS

where S is the error covariance matrix of model (3.1) for i=l,...,n-l (Theil, 1971). Under the null, (3.6) is distributed as F with q and («-l)(T-«) degrees of freedom. As before, we replace X by its estimator S (when S is non-singular) and the test statistic becomes vps = (Ry H )'{R[S®(X H 'X H )- 1 ]R'}" 1 (Ry H ),

(3.7)

which has an asymptotic %2 distribution with q degrees of freedom. Using simulation experiments, Meisner (1979) showed that the asymptotic test is biased against symmetry, particularly in large demand systems. Since (3.4) involves cross-equation restrictions, the exact distribution of Ts is complicated and has not yet been derived. Now we apply (3.7) to the data from the 22 OECD countries and the results are shown in Table 7.5. A comparison of the observed value of (3.7) in

240

International Consumption Comparisons Table 7.5 Testing symmetry in 22 OECD countries

Country

Data-based

Critical

Conclusion

(1) 1. Australia

(2) 66.10

(3) X2(28)=41.34

2. Austria 3. Belgium

36.98

X2(28)=41.34

Do not reject

18.00

X2(21)=32.67

Do not reject

4. Canada

38.50

X2(28)=41.34

Do not reject

5. Denmark

77.80

X2(28)=41.34

Reject

6. Finland

51.50

Reject

(4) Reject

7. France

71.00

X2(21)=32.67 X2(28)=41.34

8. Germany

86.20

X2(21)=32.67

Reject

9. Greece

33.50

X2(28)=41.34

Do not reject

10. Iceland

111.27

X2(28)=41.34

Reject

11. Ireland

49.40

X2(28)=41.34

Reject

12. Italy

36.80

X2(28)=41.34

Do not reject*

13. Japan

61.30

X2(21)=32.67

Reject

14. Luxembourg

35.30

X2(21)=38.93*

Do not reject

15. Netherlands

15.20

X2(21)=32.67

Do not reject

16. New Zealand

9.67

X2(6)=12.59

Do not reject

17. Norway

39.70

X2(28)=41.34

Do not reject

18. Spain

33.70

X2(21)=38.93*

Do not reject*

19. Sweden

39.20

X2(28)=41.34

Do not reject

2

Reject

20. Switzerland

38.70

X (21)=38.93*

21. UK

29.50

X2(21)=32.67

Do not reject

22. USA

29.50

X2(28)=41.34

Do not reject

Do not reject*

q = 14(0-1 )(n-2). The level of significance a = 0.05. A * denotes critical value and conclusion at a = 0.01.

Chapter 7 Testing Demand Theory Hypotheses

241

column 2 with the x2-critical values for the asymptotic test presented in column 3 shows that Slutsky symmetry is acceptable for 11 countries at the 5 percent level and acceptable for 14 countries at the 1 percent level. Table 7.6 presents the results for testing symmetry based on (3.7) using the data for the 23 LD countries. Symmetry is acceptable for 12 countries at the 5 percent level and acceptable for 13 countries at the 1 percent level.

7.4

Summary results

In this chapter, we tested the demand theory hypotheses, demand homogeneity and Slutsky symmetry. We used the asymptotic tests as well as the finite-sample exact tests (for homogeneity) to test these hypotheses. Tables 7.7 and 7.8 summarize our findings regarding the homogeneity and symmetry hypotheses tests for the OECD and LD countries, respectively. As can be seen, homogeneity is acceptable for all OECD countries (except Greece and the US) and all LD countries. That is, as a whole, demand homogeneity is acceptable for 43 out of 45 countries. Symmetry is acceptable for only 14 out of the 22 OECD countries and 13 out of the 23 LD countries. That is, as a whole, Slutsky symmetry is acceptable for only 27 out of the 45 countries. Table 7.9 presents a summary of the findings, in terms of the proportion of acceptances (in percentages) of each hypothesis in the 45 countries (22 OECD and 23 LD) considered in this study. As can be seen from the table, among all 45 countries, demand homogeneity is acceptable for 96 percent of the countries while Slutsky symmetry is acceptable for only about 60 percent of the countries. Consequently, an overall picture emerges that demand homogeneity is generally acceptable while Slutsky symmetry is also generally acceptable but to a lesser extent.

International Consumption Comparisons

242

Table 7.6 Testing symmetry in 23 LP countries Country

Data-based

Conclusion

1. Colombia

(2) 78.29

Critical x2(q) (3) X2(28)=41.34

2. Cyprus

29.68

X2(10)=18.31

Reject

3. Ecuador

15.28

X2(15)=25.00

Do not reject

4. Fiji

17.69

X2(10)=18.31

Do not reject

5. Honduras

24.98

X2(6)=12.59

Reject

6. Hong Kong

36.48

X2(28)=41.34

Do not reject

7. Hungary

22.68

X2(6)=12.59

Reject

(D

2

(4) Reject

8. India

23.03

X (15)=25.00

9. Iran

30.19

X2(6)=12.59

Reject

10. Israel

28.60

X2(28)=41.34

Do not reject

11. Jamaica

29.43

X2(10)=18.31

Reject

12. Korea

87.07

X2(21)=32.67

Reject

13. Malta

39.22

X2(21)=32.67

Reject

14. Mexico

43.06

X2(21)=32.67

Reject

4.88

X2(6)=12.59

Do not reject

15. Philippines

2

Do not reject

16. Puerto Rico

18.32

X (21)=32.67

Do not reject

17. Singapore

27.05

X2(21)=32.67

Do'not reject

18. South Africa

24.30

X2(21)=32.67

Do not reject

19. Sri Lanka

36.86

X2(21)=38.93*

Do not reject*

20. Taiwan

20.63

X2(21)=32.67

Do not reject

21. Thailand

42.30

X2(21)=32.67

Reject

22. Venezuela

5.12

X2(6)=12.59

Do not reject

23. Zimbabwe

11.04

X2(6)=12.59

Do not reject

q = '/2(n-1)(n-2). The level of significance a = 0.05. A * denotes critical value and conclusion at a = 0.01.

Chapter 7 Testing Demand Theory Hypotheses

243

Table 7.7 Summary results: Testing demand theory hypotheses 22 OECD countries Country (1) 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14.

Australia Austria Belgium Canada Denmark Finland France Germany Greece Iceland Ireland Italy Japan Luxembourg

15. 16. 17. 18. 19. 20. 21.

Netherlands New Zealand Norway Spain Sweden Switzerland UK

22. USA

Demand homogeneity (2)

Slutsky symmetry (3)

Do not Do not Do not Do not Do not Do not Do not Do not Reject Do not Do not Do not Do not Do not Do not Do not Do not Do not Do not Do not Do not

reject reject reject* reject reject reject * reject * reject

Reject Do not reject Do not reject Do not reject Reject Reject Reject Reject

reject reject * reject reject * reject reject * reject reject reject reject reject reject

Do not Reject Reject Do not Reject Do not Do not Do not Do not Do not Do not Do not Do not

Reject

reject

reject* reject reject reject reject reject* reject reject* reject

Do not reject

The level of significance used is a = 0.05. A * denotes conclusion at a = 0.01.

244

International Consumption Comparisons Table 7.8 Summary results: Testing demand theory hypotheses 23 LD countries

Country (1) 1. Colombia 2. Cyprus 3. Ecuador 4. Fiji 5. Honduras 6. Hong Kong 7. Hungary 8. India 9. Iran 10. Israel 11. Jamaica 12. Korea 13. Malta 14. Mexico 15. Philippines 16. Puerto Rico 17. Singapore 18. South Africa 19. Sri Lanka 20. Taiwan 21. Thailand 22. Venezuela 23. Zimbabwe

Demand homogeneity (2) Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject Do not reject

Slutsky symmetry (3) Reject Reject Do not reject Do not reject Reject Do not reject Reject Do not reject Reject Do not reject Reject Reject Reject Reject Do not reject Do not reject Do not reject Do not reject Do not reject* Do not reject Reject Do not reject Do not reject

The level of significance used is a = 0.05. A * denotes conclusion at a = 0.01.

245

Chapter 7 Testing Demand Theory Hypotheses Table 7.9 Summary of percentage acceptance of the demand theory hypotheses: 22 OECD and 23 LD countries Percentage acceptance Hypothesis (1)

OECD countries (2)

LD countries (3)

All countries (4)

1. Demand homogeneity

91

100

96

2. Slutsky symmetry

64

57

60

References Attfield, C.L. (1997). 'Estimating a Cointegrating Demand System,' European Economic Review 41(1): 61-73. Attfield, C.L. (1998). 'Bartlett Adjustments of Linear Equations with Linear Restrictions,' Economics Letters 60(3): 277-283. Barnard, G.A. (1963). 'In discussion,' Journal of the Royal Statistical Society, Series B, 25: 294. Barten, A.P. (1969). 'Maximum Likelihood Estimation of a Complete System of Demand Equations,' European Economic Review 1: 7-73. Barten, A.P. (1977). 'The Systems of Consumer Demand Functions Approach: A Review,' Econometrica 45: 23-51. Bera, A.K., R.P. Byron and CM. Jarque (1981). 'Further Evidence on Asymptotic Tests for Homogeneity and Symmetry in Large Demand Systems,' Economics Letters 8: 101-105. Bewley, R.A. (1983). 'Tests of Restrictions in Large Demand Systems,' European Economic Review 20: 257-269.

246

International Consumption

Comparisons

Buse, A. (1998). 'Testing Homogeneity in the Linearised Almost Ideal Demand System,' American Journal of Agricultural Economics 80(1): 208-220. Chen, D.L. (2001). World Consumption Economics. Singapore, London: World Scientific. Cribari, N.F., and S.G. Zarkos (1997). 'Finite-Sample Adjustments for Homogeneity and Symmetry Tests in Systems of Demand Equations: A Monte-Carlo Evaluation,' Computational Economics 10(4): 337-351. Deschamps, P.J. (2000). 'Exact Small-Sample Inference in Stationary, Full Regular Dynamic Demand Models,' Journal of Econometrics 97(1): 51-91. Karagiannis, G., and G.J. Mergos (2002). 'Estimating Theoretically Consistent Demand Systems using Cointegration Techniques with Application to Greek Food Data,' Economics Letters 1'4(2): 137-143. Keuzenkamp, H.A. (2000). Probability, Econometrics and Truth: The Methodology of Econometrics. Cambridge: Cambridge University Press. Keuzenkamp, H.A., and A.P. Barten (1995). 'Rejection without Falsification on the History of Testing of Homogeneity Condition in the Theory and Consumer Demand,' Journal of Econometrics 67: 103-128. Laitinen, K. (1978). "Why is Demand Homogeneity So Often Rejected?' Economics Letters 1: 187-191. Meisner, J.F. (1979). 'The Sad Fate of the Asymptotic Slutsky Symmetry Test for Large Systems,' Economics Letters 2: 231-233. Muellbauer, J., and P. Pashardes(1992). 'Test of Dynamic Specification and Homogeneity in a Demand System,' in L. Phlips and L.D. Taylor (eds.), Aggregation, Consumption and Trade: Essays in Honour of H.S. Houthakker. Dordrecht: Kluwer Academic Publishers, pp.55-98.

Chapter 7 Testing Demand Theory Hypotheses

247

Ng, S. (1995). 'Testing for Homogeneity in Demand Systems when the Regressors are Nonstationary,' Journal of Applied Econometrics 10: 147163. Pollak, R.A., and T.J. Wales (1992). 'Specification and Estimation of Dynamic Demand Systems,' in L. Phlips and L.D. Taylor (eds.), Aggregation, Consumption and Trade: Essays in Honour ofH.S. Houthakker. Dordrecht: Kluwer Academic Publishers, pp.99-119. Selvanathan, E.A. (1995). Data Analytic Techniques for Consumer Economics,' Chapter 3 in E.A. Selvanathan and K.W. Clements (eds), Recent Developments in Applied Demand Analysis. Berlin: Springer. Selvanathan, S. (1987). 'A Monte Carlo Test of Preference Independence,' Economics Letters 25: 259-261. Selvanathan, S. (1993). A System-wide Analysis of International Consumption Patterns. Boston: Kluwer Academic Publishers. Theil, H. (1971). Principles of Econometrics. New York: John Wiley and Sons. Theil, H. (1987). 'The Econometrics of Demand Systems,' Chapter 3 in H. Theil and K.W. Clements (eds.), Applied Demand Analysis: Results from System-wide Approaches. Cambridge, MA: Ballinger Publishing Company. Theil, H., and K.W. Clements (1987). Applied Demand Analysis: Results from System-wide Approaches. Cambridge, MA: Ballinger Publishing Company.

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CHAPTER 8

A Comparison of Alternative Demand Systems H~A. Selvanathan <& S. Selvanathan

In Chapters 1 and 2, we presented a review of the economic theory of the consumer and developed a number of differential demand systems. We also pointed out that there are a number of competing demand systems available which are commonly used in applied demand studies for estimating the demand elasticities and for testing various demand theory hypotheses. In this chapter, we consider four of the well-known demand systems introduced in Chapter 2, namely, (1) Rotterdam demand system; (2) Almost Ideal Demand System (AIDS); (3) CBS demand system; and (4) NBR demand system. Choosing between different demand model specifications is very complicated. There are no set criteria available for the choice of functional forms in demand analysis. Choice of functional form is considered by many researchers as one of the most important issues in any aspect of empirical analysis of consumer behaviour (see Blundell, 1988). Many recent research studies have considered the choice of functional forms (for example, see Barten, 1993; Chua et al, 2001; Clements et al, 2001; Fisher et al, 2001; Lee et al, 1994; Neves, 1994; Tridimas, 2000). In this chapter, we use the most popular measure, the information inaccuracy to select the preferred demand system among the four systems.

International Consumption Comparisons

250

In Section 8.1, we present the finite-change version of these demand systems and estimate them to test the demand theory hypotheses, demand homogeneity and Slutsky symmetry, and compare the results with those from Chapter 7. In the following section, we use a concept from information theory, called the 'information inaccuracy', to measure the goodness-of-fit of the demand systems. This measure has been extensively used by a number of researchers in applied demand analysis (see, for example, Theil, 1975/76, 1980, 1996) and is well suited to analyzing the fitness of allocation models such as those considered in this book. In Section 8.3, we compare the performances of the four demand systems based on the goodness-of-fit criterion, the information inaccuracy. In the final section, we present our conclusion.

8.1

Four Demand Systems

In this section, we first present the four demand systems introduced in Chapter 2. The estimating forms of the Rotterdam, AIDS, CBS and NBR demand systems given by equations (3.21), (4.11), (5.5) and (5.6), respectively, of Chapter 2, with a random error term added, are given below (see also Barren et al, 1989). Rotterdam demand System w.aDgit = cti + Q]PQt+ £ xgDpj,+ En,

i=l,...,n.

(1.1)

i=l,...,n.

(1.2)

7=1

AIDS model Awit

= Xi + PiDQ, + t ^ D p j , + E i t , 7=1

Chapter 8 A Comparison of Alternative Demand Systems

251

CBS demand system wi( (Dq« - DQO = 8i + VjDGt + £ WgDPjt + eit,

i=l,...,/i.

(1.3)

M?/? demand system Awit+witDQt

= Ki + \iiDQt+ Y.
i=l,...,n.

(1.4)

The random error term captures the effect of all the variables not explicitly included in the specified models. It is assumed that the errors are contemporaneously correlated and are normally distributed with zero mean. We now use the demand analysis package DEMMOD (Barten et al, 1989) to estimate the four demand systems (1.1)-(1.4) with data for the OECD and LD countries individually. For all countries, we also test the demand homogeneity and Slutsky symmetry hypotheses, which were tested in Chapter 7 using only the Rotterdam demand system. For the OECD countries, Table 8.1 presents the value of the test statistics for homogeneity (given by equation (2.4) of Section 7.2) and symmetry (given by equation (3.7) of Section 7.3) and Table 8.2 presents the outcomes of the hypotheses testing across the four demand systems. The hypotheses test results for the LD countries are presented in Tables 8.3 and 8.4. The results corresponding to the Rotterdam demand system columns are the same as those reported in Chapter 7. We also use the same critical values presented in columns 3 and 6 of Tables 7.2 and 7.4 for homogeneity and column 3 of Tables 7.5 and 7.6 for symmetry. A comparison of columns 2-5 with columns 6-9 of Tables 8.2 and 8.4 for the four demand systems confirms our conclusion in Chapter 7 that

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International Consumption Comparisons

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The reason for the rejection of homogeneity is the asymptotic nature of the distribution of the test statistic used in columns 2-5. Based on Laitinan's (1978) finite-sample test, homogeneity is acceptable for all OECD countries (except for Greece and the US) and for all LD countries, irrespective of the demand system used. Looking at columns 10-13 of Tables 8.2 and 8.4, we see that Slutsky symmetry is acceptable for 14 of the 22 OECD countries and 14 of the 23 LD countries. This result holds for at least two of the four demand systems. Therefore, we conclude that for a majority of the OECD and LD countries, the Slutsky symmetry hypothesis is also acceptable.

8.2

Measure of Goodness-of-fit

The standard measure of goodness-of-fit used in econometrics is the multiple correlation coefficient. Since this coefficient refers to a single equation, its use is unattractive when the objective is to measure the fit of several equations that are estimated simultaneously. It is possible, however, to introduce a generalized multiple correlation coefficient to measure the fitness of an equation system (for example, see McElroy, 1977). In this section, we use a measure of goodness-offit, the information inaccuracy, a concept from information theory. This measure has been widely used in allocation models such as ours (see, for example, Theil, 1980, 1996). For illustration, we use the CBS demand system given by (1.3). However, simple modifications can be made to accommodate the other three demand systems. In order to define the information inaccuracy, first we shall start with the budget share predictions implied by the demand system.

257

Chapter 8 A Comparison ofAlternative Demand Systems Budget Share Predictions from the Demand Equations

Let wit be the actual budget share of commodity i in year t and wit be the predicted budget share. As the model determines the change in the share, we write the prediction as wu

=

wit.i + prediction of Aw,„

i= 1,... ,n,

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where 0 3 is the remainder term of the third-order in the price, quantity and income log-changes. Equation (2.3) can also be written as Aw„ = wu(Dqit -DQt)

+ wit(DQt + Dpit -DM,)+

03.

(2.4)

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International Consumption Comparisons

258

Prediction of wu{Dqit -DQ,) = w„(Dqit -DQ,) - e„,

(2.5)

where eit is the residual of the i* demand equation. Using (2.4) and recognizing that the second term in that equation is given, we obtain Prediction of Aw,-, = Prediction of wit (Dqjt - DQ,) + wit (DQt + Dpit - DM,) = wit{Dqu-DQt)

- eit + wit{DQt+DPil

-DM,)

= ™i,D(lit + ™uDPi, - witDM,- £,,, where the remainder term 0 3 is ignored and the second step is based on (2.5). Using (2.3), the above equation becomes Prediction of Aw„ = Aw„ - sit.

(2.6)

Therefore, using (2.6) in (2.1) gives wit

= wit_, + Aw,-, - sit.

wit

=

That is, w« - e,7.

(2.7)

Thus, equation (2.7) gives the budget share predictions implied by the demand system.

Chapter 8 A Comparison of Alternative Demand Systems

259

The Information Inaccuracy

To measure the quality of the predictions, we use a concept from information theory, called the information inaccuracy. This measure has been extensively used by Theil (1975/76, 1980, 1996) and is well suited to analysing the fit of allocation models such as ours. In general, if we have n goods with budget share predictions wu,...,wnt, the information inaccuracy of these predictions is defined as 1=

n

w.

/=i

wu

I>„log^.

(2.8)

When predictions are perfect (i.e., wit= wit, i=l,... ,n), I, = 0; otherwise I, > 0. Therefore, the smaller the information inaccuracy, the better the predictions. Consequently, the preferred demand system would be the one with the lowest value of information inaccuracy. If we define e;t = log (wit I wit) as the relative error, then I, = X"=1w,7e,-r can be interpreted as the Divisia mean (i.e., the budgetshare-weigh ted mean) of the relative errors. Thus Ir x 100 is approximately equal to the weighted average percentage error.

8.3

The Preferred Demand System

In this section we shall choose between the four versions of the model on the basis of the goodness-of-fit criterion, the information inaccuracy. We start with the budget share predictions implied by the four versions. For a particular country, we use the residuals from each demand system to obtain the predicted budget shares given by (2.7). We then use equation (2.8) to calculate the information inaccuracies for each demand system for t=l,...,T

260

International Consumption Comparisons

(T=sample size after lagging). We then evaluate the mean information inaccuracy for each demand system as 1T T (=1

These mean information inaccuracies are presented in Table 8.5 (OECD) and Table 8.6 (LDC) for the four demand systems. In column 2 of each table, we present the constraint acceptable for each country based on our conclusion from Section 8.2. Now, we use the information inaccuracy presented in columns 3 to 6 to select the preferred model based on the lowest value of the mean information inaccuracy (I). For example, for Australia, across the four demand systems, we found that only homogeneity restriction is acceptable. The information inaccuracies obtained under the homogeneity restriction for the four demand systems, Rotterdam, AIDS, CBS and NBR, are 137.94, 147.62, 144.14 and 193.52, respectively. The lowest value among these is 137.94, which corresponds to the Rotterdam demand system. Therefore, for Australia, the preferred demand system is the Rotterdam model. For the USA, we found that symmetry is acceptable for all four demand systems. The information inaccuracies under the symmetry restriction for the four demand systems, Rotterdam, AIDS, CBS and NBR, are 84.39, 69.21, 84.32 and 86.47, respectively. Here, the lowest value is 69.21, which corresponds to the AIDS. Therefore, the preferred demand system for the US is the AIDS. Table 8.7 gives the preferred demand system for each country based on the minimum information inaccuracy. As can be seen from column 2, for the 22 OECD countries, the CBS is the preferred demand system for 12 countries; AIDS for 5 countries; Rotterdam for 3 countries; and NBR for 2 countries. As can be seen from column 5, for the 23 LD countries, the CBS is the preferred demand

Chapter 8 A Comparison ofAlternative Demand Systems

261

Table 8.5 Mean information inaccuracies, OECD countries Acceptable constraint Country

(D

(Based on Table 8.2)

Mean information inaccuracy Rotterdam

AIDS

CBS

NBR

1.

Australia

(2) Homogeneity

2.

Austria

Homogeneity

200.44

189.00

182.38

197.18

3. 4.

Symmetry Symmetry Homogeneity Homogeneity

252.77

245.72 252.47

241.26 257.06

261.18 178.22

5. 6.

Belgium Canada Denmark Finland

169.59 236.61

173.05 244.19

160.78 257.37

7. 8. 9. 10.

France Germany Greece Iceland

Homogeneity Homogeneity

64.81 87.05 465.83 477.77

63.71 79.76 442.23

63.36 77.71 415.93 473.30

87.58 468.91 493.47

11. Ireland 12. Italy 13. Japan 14. Luxembourg 15. Netherland 16. NewZealand 17. Norway 18. Spain 19. Sweden 20. Switzerland 21. UK 22. USA

Symmetry Homogeneity Symmetry Symmetry Homogeneity Symmetry Symmetry Symmetry Symmetry Symmetry Symmetry Symmetry Symmetry Symmetry

All entries in columns 3-6 are to be divided by 106.

(3) 137.94

282.85 163.82 262.97

500.11 151.13 150.80 291.68 384.89 125.49 330.13 264.54 158.80 74.34 130.16 84.39

(4) 147.62

487.08 486.32 123.83 139.45 291.69 326.00 129.24 259.09 236.62 152.06 80.86 131.67 69.21

(5) 144.14

475.89 118.78 143.72 291.00 311.73 129.43 313.33 229.95 152.36 77.45 126.15 84.32

(6) 193.52

64.33

515.95 156.30 158.04 299.54 394.67 118.83 266.90 260.10 165.16 81.46 134.05 86.47

262

International Consumption Comparisons

Table 8.6 Mean information inaccuracies, LD countries Acceptable constraint Country

(Based on Table 8.4)

Mean information inaccuracy Rotterdam

(D 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14.

AIDS

Colombia

Homogeneity

(2) 127.49

Cyprus Ecuador

Homogeneity

333.85

349.10

Symmetry Symmetry Homogeneity

206.36 984.11 397.98

230.89 1097.72

Symmetry Symmetry Symmetry Homogeneity

742.53 228.85 173.85 693.00 956.38 513.65 298.61 798.59 230.29

Fiji Honduras Hong Kong Hungary India Iran Israel Jamaica Korea Malta Mexico

Symmetry Homogeneity Homogeneity Homogeneity Homogeneity

15. Philippines 16. Puerto Rico

Symmetry

17. Singapore 18. South Africa 19. Sri Lanka 20. Taiwan

Symmetry Symmetry Symmetry Symmetry Homogeneity

21. Thailand 22. Venezuela 23. Zimbabwe

Symmetry

Symmetry Symmetry

All entries in columns 3-6 are to be divided by 106.

15.79 798.64 584.65 233.35 1926.03 573.95 206.76 187.17 2145.38

(3) 121.85

379.63 760.58 175.26 173.06 693.61 952.62 547.34 136.39 833.56 208.49 16.68 775.86 536.50 227.72 1866.86 409.72 191.01 205.93 2365.79

CBS

NBR

(4) 119.67 361.75

(5) 106.27 352.11

207.89

251.35 1143.18 396.12

939.26 366.45 759.33 219.52 158.37 706.96 938.81 523.53 132.77 848.70 198.15

742.61 171.59 183.07 681.81 1001.52 536.88 173.69 790.61 249.24

19.50 772.60

807.29

534.68 238.08 1929.78 400.47 177.79 177.74 2274.59

0.77 584.86 233.87 1857.92 539.27 173.24 222.19 2206.2

Chapter 8 A Comparison of Alternative Demand Systems

263

Table a 7 Preferred demand systems, OECD and LD countries Country

Demand Mxtel (2)

1.

(1) Australia

Ftotterdam

2.

Austria

3.

Belgium

4.

Canada

5. 6.

Country

Ftestriction

Demand Wbdel (5)

(4)

Restriction (6)

(3) Homogeneity

1.

Colombia

CBS

Homogeneity

CBS

Homogeneity

2

Cyprus

Ftotterdam

Homogeneity

CBS

Symmetry

3.

Ecuador

Ftotterdam

Homogeneity

NBR

Symmetry

4.

Fiji

CBS

Symmetry

Denmark

NBR

Homogeneity

5.

Honduras

CBS

(Homogeneity

Finland

AIDS

Homogeneity

6.

Hong Kong

Ftotterdam

Symmetry

7.

France

CBS

Homogeneity

7.

Hungary

NBR

Syrrmetry

8.

Germany

CBS

Homogeneity

8.

Inda

CBS

Symmetry

9.

Greece

CBS

Symmetry

9.

Iran

CBS

Homogeneity

10.

Iceland

CBS

Homogeneity

10.

Israel

NBR

Syrrmetry

11.

Ireland

C8S

Syrrmetry

11.

Jamaica

Rotterdam

Horrogeneity

12

Italy

CBS

Symmetry

12

Korea

CBS

Homogeneity

13. Japan

AIDS

Homogeneity

13.

Malta

NBR

Horrogeneity

14.

Luxembourg

CBS

Symmetry

14.

Mexico

CBS

Homogeneity

15.

Netherlands

CBS

Symmetry

15.

Philippines

NBR

Syrrmetry

16.

New Zealand

Ftotterdam

Syrrmetry

16.

Puerto FSco

CBS

Syrrmetry

17.

Norway

AIDS

Syrrmetry

17.

Sngapore

CBS

Syrrmetry

18.

Spain

CBS

Symmetry

18.

South Africa

AIDS

Syrrmetry

AIDS

Syrrmetry

19.

Sri Lanka

NBR

Syrrmetry Syrrmetry

19. Sweden 20.

Switzerland

Rotterdam

Symmetry

20.

Taiwan

CBS

21.

UK

CBS

Syrrmetry

21.

Thailand

NBR

Horrogeneity

22

USA

AIDS

Symmetry

22

Venezuela

CBS

Symmetry

23.

Zrrfoabws

Ftotterdam

Syrrmetry

International Consumption Comparisons

264

system for 11 countries; NBR for 6 countries; Rotterdam for 5 countries; and AIDS for only 1 country. In summary, the CBS is the preferred system for most OECD and LD countries. Table 8.8 presents the preferences in percentages. As can be seen, for the majority of OECD and LD countries, the CBS demand system performs well. Overall, the CBS performs the best followed by Rotterdam, NBR and AIDS, in that order.

Table 8.8 Preferred demand systems for 22 OECD and 23 LD countries (in percentages) Percentage preference Demand system

1. 2. 3. 4.

(1) Rotterdam AIDS CBS NBR

8.4

OECD countries (2) 14 23 55 9

LD countries (3) 22 4 48 26

All countries (4) 18 13 51 18

Conclusion

In this chapter, we tested the demand theory hypotheses, demand homogeneity and Slutsky symmetry, using four demand systems, Rotterdam, AIDS, CBS and NBR. Our results show that, across the four demand systems, the demand homogeneity restriction is generally acceptable while the Slutsky symmetry restriction is also acceptable, but to a lesser extent.

Chapter 8 A Comparison of Alternative Demand Systems We also compared the performance of four demand systems using a measure of goodness-of-fit, the information inaccuracy, and found that the CBS system performs better than the other three demand systems. In the next chapter, we shall investigate the implications of imposing a restriction on the utility function to further simplify the model estimation.

References Barten, A.P. (1993). 'Consumer Allocation Models: Choice of Functional Form,' Empirical Economics 18: 129-158. Barten, A.P., L. Bettendorf, E. Meyermans and P. Zonderman (1989). Users' Guide to DEMMOD-3. Kathlieke Universiteit Leuven, Belgium. Chua, C.L., W.E. Griffiths and C.J. O'Donnell (2001). 'Bayesian Model Averaging in Consumer Demand Systems with Inequality Constraints,' Canadian Journal of Agricultural Economics 49(3): 269-291. Clements, K.W., W. Yang and D.Chen (2001). 'The Matrix Approach to Evaluating Demand Equations,' Applied Economics 33: 957-967. Fisher, D., A.R. Fleissig and A. Serletis (2001). 'An Empirical Comparison of Flexible Demand Systems Functional Forms,' Journal of Applied Econometrics 16(1): 59-80. Laitinen, K. (1978). 'Why is Demand Homogeneity So Often Rejected?' Economics Letters 1: 187-191. Lee, J.Y., M.G. Brown and J.L. Seale Jr. (1994). 'Model Choice in Consumer Analysis: Taiwan 1970-89,' American Journal of Agricultural Economics 76: 504-512. McElroy, M.B. (1977). 'Goodness of Fit for Seemingly Unrelated Regressions,' Journal of Econometrics 6: 381-387.

265

International Consumption Comparisons

266

Neves, P.D. (1994). 'A Class of Differential Demand Systems,'

Economics

Letters 44: 83-86. Theil, H. (1975/76). Theory and Measurement of Consumer Demand. Two Volumes. Amsterdam: North-Holland Publishing Company. Theil, H. (1980). The System-Wide Approach to Microeconomics. Chicago: The University of Chicago Press. Theil, H. (1996). Studies in Global Economics. Boston: Kluwer Academic Publishers. Tridimas, G. (2000). 'The Analysis of Consumer Demand in Greece: Model Selection and Dynamic Specification,' Economic Modelling 17(4): 455471.

CHAPTER 9

The Structure of Preferences: O E C D and LD Countries S. Selvanathan & E.A. Selvanathan

Estimating a system of demand equations in an unrestricted fashion requires the estimation of an impossibly large number of coefficients, especially with large demand systems. As discussed in Chapter 7, one way of reducing the number of coefficients to be estimated is to impose a priori restrictions such as demand homogeneity and symmetry. In Chapters 7 and 8, we carried out tests of these two hypotheses for the OECD and LD countries and across a number of demand systems. In this chapter, we investigate the implications of imposing another a priori restriction by specifying a form of utility structure, known as strong additivity (or preference independence) discussed in Chapters 1 and 2. Selvanathan (1993), using 10 broad aggregate commodity classification of the OECD countries, and Clements et al (1997) using a narrowly defined alcohol commodity group consisting of beer, wine and spirits, found tentative support for the preference independence hypothesis. Moschini et al (1994) also looked at testing separability restrictions on the demand systems. As pointed out in Chapter 7, one problem associated with testing is the test procedure, which is usually based on the asymptotic distribution of the test statistic without correction for small-sample bias and, therefore, the results are biased towards rejection. In view of these difficulties, Selvanathan (1987)

International Consumption Comparisons

268

developed an alternative distribution-free testing procedure for preference independence based on Barnard's (1963) Monte Carlo simulation procedure. In Sections 3.7 and 4.7, we performed an informal test of preference independent utility structure using the data from OECD and LD countries, respectively, and found indirect support for the preference independence hypothesis for both groups of countries. In this chapter, we present a detailed account of the conventional tests used for testing the hypothesis of independent preference structures within goods, and the new Monte Carlo simulation procedure to test the hypotheses, and illustrate their application using the OECD and LDC data. In Chapter 8, we presented a comparison of the performances of four alternative demand models and found that the CBS demand system is the preferred demand model for a majority of countries. Therefore, we use the CBS demand system in this chapter. The organisation of this chapter is as follows. In Section 9.1, we present the demand model under preference independence and in Section 9.2, we present the estimation procedure. In the following section, we present the estimation results under preference independence. In Section 9.4, we present the test results for preference independence using the asymptotic test for OECD and LDC data and then introduce the Monte Carlo method and discuss its application to test the preference independence hypothesis for the same data. Finally, in Section 9.5, we present the implied income and price elasticities and in Section 9.6, we present our concluding comments.

9.1

The Demand Model

For commodity i (=l,...,n, the number of goods) and period t (=1,...,T, the sample size after lagging), the finite-change version of the absolute price version of the

269

Chapter 9 The Structure of Preferences

CBS model, given by (5.5) in Section 2.5, can be written as wit (Dqit - DQt) = Pi DQt + £ TiijDpj, + Eit,

(1.1)

7=1

where p\ is the i* income coefficient satisfying S"=iA = 0; Jty is the (ij)"1 Slutsky coefficient satisfying Y!i=\nij - 0; a n d all other notations are as defined in Chapter 2. If Pi < 0, then good i is a necessity and if Pi > 0, then good i is a luxury. The error terms are assumed to be normally distributed with zero mean and are independent over time. When consumer's tastes can be described by means of a utility function, which can be written as the sum of n sub-utility functions, each involving one good only, then tastes are said to exhibit preference independence or additive preferences. Preference independence also means that the marginal utility of good i is independent of the consumption of commodity j , i^j. If the commodities are fairly broad groups such as those considered in this study, then it may be possible that, for example, the marginal utility derived from food may be independent from the marginal utility derived from clothing and so on. Then the broad commodity groups can be interpreted as representing the "basic wants" of the consumer and if these are truly basic wants, they could be expected to exhibit little interaction in the utility function. In the next section, we outline the estimation procedure and, in the following section, we now formally test the preference independence hypothesis with consumption data from OECD and LD countries. Under preference independence, the Slutsky coefficients take the form (see, for example, Selvanathan and Selvanathan, 1994)

^(KA+^x^-A-w,,),

(1.2)

270

International Consumption Comparisons

where <{) is the income flexibility (the reciprocal of the income elasticity of the marginal utility of income) and 8y is the Kronecker delta. Substituting (1.2) for 7ijj in (1.1) and adding a constant term ai? the preference independent version of (1.1) can be written as

wit (DqirDQt) = ai + PiDQ. + HP, + wit) DPil-UJ3j+wJt)Dpjt

+eit. (1.3)

As can be seen, equation (1.3) is nonlinear in its parameters. Therefore, we apply the maximum likelihood estimation procedure, as described in the next section, for its estimation.

9.2

Model Estimation

We write equation (1.3) in the following form: yit = a, + PiDQt + (j)zit + eit where yit = wit (Dqa - DQt), n-\

Zit = {Pi +W„) Dpl-UPj+wjt)Dp)t

and Dp*t = Dpit - Dpm, where we have also used S"=i Pi =0. In vector form, (2.1) can be written as

(2.1)

271

Chapter 9 The Structure of Preferences

yt

= X, y+ et,

whereat = tVu]; Xt = [DQtI„.i zt I„.i] with I„_i being the identity matrix of order n-1; zt= [ZiJ; y= IP' <> t «']' = [Pi ••• Pn-i I <> t I Od ... a n 4 ]'; and £j = [eit]. Assuming that the £j's are independent normal errors with zero mean and non-singular covariance matrix X, the log-likelihood function of them's is given by *(y,Z;y) = C + ^ n l s " 1 ! ~ ^ ( y 2

'

*

t

- X ^ ' E ^ y , -Xj),

(2.2)

lt=\

where C is a constant and T is the sample size. The first-order conditions for a maximum of (2.2) are d£

T

I

T

—-=

T-=--Z(yt-xt7)(yt-xt7)' = 0

dS

2

dy

<=i

(2.3)

2 t=i

and (2.4) d y

where

d(X,y) By'

3z, DQ.I + 0—L

z, I

(2.5)

272

International Consumption Comparisons 3z t

dig

and dz.

^ = - ( A + w a ) ^ p ; , + ^ Dpl-Zifa+wJDpl dfi

From the first order condition (2.3), we have

i-^I(yt-Xty)(yt-XtY)'.

This is the usual ML estimator of Z. It follows from (2.4) that

l

dZ.~ dy'

3(X t y) = I (y t - X j ) dy' t=i

(2.6)

Since E[(y t - X ^ ) ] = E[£j] = 0, the expected value of the right-hand side of (2.6) vanishes, so that the information matrix of the ML procedure is blockdiagonal with respect to yand 2T1. From (2.4), we also have d2l _ T d(Xty)', dydy' t=\ dy

3(X t y) r a 2 (x (7 ) + i ( y t -Xt^ys-1 a , ay <=i

273

Chapter 9 The Structure of Preferences

The second term on the right-hand side has zero expectation. Therefore, the asymptotic covariance matrix of the ML estimator of y is

V =

d2l> dydy'

£ d(xtry^ d(xty)y t=i dy

dy'

The ML estimator of y is obtained by means of Newton's iterative scheme based on successive estimates of V and 2. The asymptotic standard errors are the square roots of the diagonal elements of V with ML-estimates substituted for the unknown parameters in V.

9.3

Estimation Results

In this section we present the estimation results of the demand system (1.3) based on the estimation procedure described in the previous section. Tables 9.1 and 9.2 present the estimation results for the OECD countries. Table 9.1 presents the estimates of the intercept terms. As can be seen, for most countries, the intercept terms for food, clothing, durables and transport are negative while the intercept terms for housing, medical care, education and recreation are positive. This indicates that, in most countries, there is an autonomous trend in consumption out of food, clothing, durables and transport into housing, medical care, education and recreation. Table 9.2 presents the estimates for the income coefficient, Pi, i=l,...,9, in columns 2-10 and the estimates for income flexibility in the last column. As can be seen, for most countries, the income coefficient estimates for food, housing, and medical care are negative, indicating that food, housing and medical care are

International Consumption Comparisons

274

Table 9.1 Estimates of the intercept terms of the model under preference independence for 9 commodities in 22 OECD countries (Standard errors are presented below the point estimates)

Country

o

O (5) -0.364 0.088

0.298

-0.028

0.043 0.090

-0.072

0.061 0.204

0.072 -0.198

0.061 -0.177

0.104 0.421

0.049 -0.021

0.035 -0.175 0.044

Finland

0.075 -0.097

France

0.100 -0.040

1.

(2) -0.040

2.

Austria

0.076 -0.152

Belgium

0.093 -0.003

4.

Canada

0.106 -0.211

5.

Denmark

6. 7.

3.

u (3)

X (4) 0.427 0.055

Li-

(1) Australia

-0.212 0.039 -0.201 0.058

-0.211 0.082

2 (6) 0.015

H <7) -0.007 0.099

a: (8) 0.002 0.049

•o

(9) 0.030 0.013 -0.004

z (10) 0.149 0.055

0.086

0.023 0.147

-0.079 0.096 0.003

0.101 •0.043

0.056 -0.086

0.072 -0.092

0.028 0.090

0.071

0.119 0.027

0.059 0.390

0.052 -0.224

0.072 0.037

0.066 -0.224

0.042 0.098

0.019 0.068

0.045 0.049

0.093 0.624

0.036 -0.114 0.041

0.017 0.067

0.097 -0.369

0.046 0.079 0.049

0.011

0.043 0.019 0.050 -0.174

0.056

0.049 0.093

0.005

-0.011 0.059 -0.173

-0.133 0.032

0.363 0.061

-0.322

0.020 0.503

0.134 -0.156

-0.044

C.001

0.063

0.053

0.090

0.025

0.005

-0.087 0.057

-0.187

0.442 0.060

0.04S 0.016

-0.141

0.032

-0.170 0.060

0.207 0.041

0.220

-0.504 0.112

0.266

-0.076

0.148

0.068

0.136

-0.012 0.109

-0.008 0.019

-0.001

0.050

-0.033 0.047

-0.290

0.155

0.042

0.121

1 1 . Ireland

0.090

-0.207

0.091 0.162

0.145 -0.140

0.034 0.019

-0.275

0.187

-0.160 0.066

0.240

-0.006

0.231 -0.076

0.098 0.051

0.033 0.036

0.109 0.090

0.176 -0.126

0.082 -0.268

0.059

0.073

0.074

0.166

-0.105

0.031 0.100

0.116

1 2. Italy

-0.015

0.089

0.033 0.007

0.072 0.152

0.076

0.046

0.029

0.043

0.038

0.081

0.042

0.006

1 3. Japan

-0.369

-0.279

0.605

-0.119

0.168

-0.091

0.222

0.078

0.062

0.067

0.090

0.073

0.088

0.089

0.130

14. L u x e m b o u r g

-0.063

-0.188 0.085

0.088 0.151

-0.089

-0.102 0.090

0.287

0.162

-0.095

0.192

0.066

0.168

-0.363 0.101 -0.359

0.157 0.054 0.459

-0.208 0.090

0.143

-0.004 0.080

0.105 0.047

0.105 0.049 0.377

0.082 -0.209

0.216 0.470

-0.134

-0.063

-0.227

0.097

0.001

0.144 0.183

0.047 -0.106

0.052 0.084

0.049

0.048 0.105

0.131 0.104

0.045

0.006

0.065

-0.093

0.061 -0.119

0.058

0.040

0.050

0.091

0.271

-0.107

0.082

-0.020

0.029 0.063

0.040 8.

Germany

9.

Greece

0.137 1 0. Iceland

0.133

0.194 1 5. Netherlands

0.065

1 6. New Zealand

0.099 -0.078 0.089

1 7. Norway

-0.119 0.065

1 8. Spain

-0.646 0.161

0.136

0.040 -0.399 0.295

0.085

0.042 -0.109 0.060 0.067

0.047 -0.137

0.035

0.517 0.099 -0.039

1 9. Sweden

-0.130 0.058

0.045

0.063

0.036

0.012

0.064

20. Switzerland

-0.195

-0.202

0.264

-0.227

0.038 0.025

0.029

0.054

0.026

0.208 0.023

0.003

0.046

0.054

0.022

0.023

-0.207

0.043

0.179

-0.112

0.020

-0.006

0.038

0.045

0.028

0.010

0.074

0.182 0.036

-0.099

0.065 -0.075

-0.078

0.174

-0.113

0.336

-0.415

0.127

0.016

0.028

0.051

0.038

0.044

0.033

0.045

0.080

0.039

0.009

0.047

2 1 . UK 22. USA

All entries are t o be divided by 100.

0.000 0.002

0.040 0.125

0.079

275

Chapter 9 The Structure of Preferences Table 9.2 Estimates of the income coefficients for 9 commodities and income flexibility under preference independence in 22 OECD countries (Standard errors are presented below the estimates)

Country 1.

(1) Australia

o •0.145

U (3) 0.021

0.028

0.013

LL.

(2)

-D UJ

s (10)

0.068

(9) 0.008

0.008

0.017

0.005

0.017

0.058

-0.001

-0.001

-0.024

-0.262

0.001

2 (6) 0.007

H (7)

(8)

-0.117

Q (5) 0.120

0.030

0.016

0.025

0.013

0.034

-0.074

0.026

-0.023

0.128

X (4)

_c -0.545

2.

Austria

-0.088

0.057

0.025

0.015

0.018

0.019

0.006

0.026

0.013

0.017

0.059

3.

Belgium

-0.146

0.015

-0.077

0.095

-0.016

0.037

-0.012

0.104

0.020 0.035

0.035

0.009 0.025

0.039

-0.068 0.037

-0.015

0.008

-0.119 0.016

0.024 0.067 0.017

-0.153

0.039

-0.015

0.231

0.006 -0.010

-0.606 0.047

0.039 0.013

0.011 -0.002

0.031 0.013

Denmark

0.013 -0.140

0.033 0.022 0.014

0.019

Canada

0.036 -0.057

0.029

0.010

0.029

0.012 0.014

-0.578 0.069

-0.176 0.014

0.043

0.013 0.007

0.003

0.032

0.003 -0.016

0.035

•0.109

0.005 -0.086

0.033 0.115

4. 5.

0.025 6.

Finland

7.

France

8.

Germany

-0.116 0.024 -0.134

0.020 -0.012

0.010 0.078

0.011 0.021

0.191

0.012

0.012

0.010

-0.061 0.022

0.019

0.009

0.027

0.035 0.007

-0.089 0.016

0.043 0.009

-0.136 0.019

0.053 0.016

-0.011 0.005

0.139 0.024

-0.068 0.006

Greece

-0.197

0.122

-0.057

0.016

0.031

0.034

0.029

0.032

0.026

0.011

-0.166

0.023

-0.180

0.015 0.103

0.010

10. Iceland

-0.006

0.030 0.191

0.038 -0.217

0.013

0.016

0.027

0.003

1 1 . Ireland

0.072

-0.076

-0.005

0.019

0.013 -0.071

0.006

12. Italy

0.039 -0.092

0.049 0.017 0.047

0.001

0.022

0.011

-0.130

0.012 0.017

9.

0.073

0.026

0.046

0.001

0.013 0.063

0.002

0.014

-0.405 0.041

0.070

-0.392

0.013 0.034

-0.256

-0.013 0.004

0.016

0.039 0.055 -0.324

-0.010

0.050

0.041

-0.005 0.017

0.005

0.025

0.076

0.076

0.054

O.OOS

0.042

0.02S

0.016

0.017

0.065

-0.011

0.008 -0.002

-0.232 0.047

-0.011

-0.090

0.023 0.085

0.012 -0.024

0.014 0.062

0.031 -0.397

0.002

1 3. japan

-0.048

0.013 0.057

0.020

0.019

0.019

0.020

-0.018 0.017

0.024

0.022

0.036

0.053

14. Luxembourg

-0.135

0.008

-0.01 5

0.062

0.070

0.041

-0.041

0.011

-0.477

0.057

0.025

0.046

0.036

0.028

0.055

0.018

0.054

0.081

1 5. Netherlands

-0.139

0.093

-0.064

0.091

-0.029

0.060

0.001

-0.013

-0.109

0.025

0.023

0.012

0.013 0.067

0.043 •1.384

0.016

0.007

0.028 0.032

0.011 -0.024

0.020

-0.103

0.026 0.032

0.014

16. New Zealand 1 7. Norway

-0.101 0.016

0.029 0.012

-0.189 0.011

0.040 0.012

0.208

0.016

-0.004

0.025 -0.021

-0.575

0.002

0.059

0.001

-0.057

0.008

0.010

0.009

0.011

0.021

0.008

19. Sweden

0.035 -0.067

0.009 0.011

0.036 0.074

0.011

18. Spain

-0.159

0.050

-0.021

0.143

0.039

0.001

0.024

0.049 0.017

0.024

0.027

0.016

0.000

0.013

0.046

0.053

-0.156

0.016 0.064

0.004

0.018

-0.044

0.066

0.018

-0.020

-0.560

0.020

0.012 0.000

0.010 0.048

0.011 -0.002

0.023 0.102

0.010

-0.127

0.013 0.091

-0.117

0.012 0.024

0.015 -0.091

0.009 0.040

0.003 -0.082

0.024 0.207

0.027 •0.007

0.031 -0.336

0.012

0.016

0.011

0.019

0.028

0.019

0.046

20. Switzerland 2 1 . UK 22. USA

-0.099 0.021 -0.100 0.018

0.009

0.022

0.023 0.021 0.007

0.006

-0.012 0.012 0.011 0.013

0.016 -0.100

-0.001 0.004

0.098 0.057 -0.284

0.015

0.035

-0.035

-0.268

0.052

276

International Consumption Comparisons

necessities for most of the OECD countries. On the other hand, for all countries, the income coefficients for clothing (except for France), durables and transport are positive, indicating that these three commodities are generally considered as luxuries by the OECD consumers. The income flexibility estimates presented in the last column of Table 9.2 are all negative as they should be with an average value of -0.38, which is close to the preliminary estimates presented in Chapter 3 (see Table 3.20). Tables 9.3 and 9.4 present the estimation results of model (1.3) for the LD countries. Table 9.3 presents the estimates of the intercept terms. As with the OECD countries, the observation is very similar for the LD countries. In most LD countries, there was an autonomous trend in consumption out of food and clothing into housing and medical care. Table 9.4 presents the estimates of the income coefficients Pi, i=l,...,9, in columns 2-10 and the estimate for income flexibility in the last column. As with the OECD results, in most countries, food, housing and medical care are necessities; and durables and transport are luxuries. But, in contrast to the OECD results, a majority of LDC consumers consider clothing as a necessity. As expected, all the estimates for income flexibility presented in the last column of the table (except for Cyprus and India) are negative, as they should be, with an average of-.46 (excluding Cyprus and India). This average is well in agreement with the preliminary estimates for the LD countries presented in Chapter 4 (see Table 4.19) and with the OECD estimates in Table 9.2. Two points are worth noting in Tables 9.2 and 9.4. First is that, in contrast to our expectation, the income coefficient for food is positive for some countries, implying that food is a luxury in these countries. Therefore, for these countries, we estimate the model by suppressing the intercept term and found that their food income coefficient estimates are now negative. We use these estimates to calculate the elasticities. For Hungary and the Philippines, no improvement in the

277

Chapter 9 The Structure of Preferences Table 9.3 Estimates of the intercept terms of the model under preference independence for 9 commodities in 23 LD countries (Standard errors are presented below the estimates)

Country

Ecuador Fiji

0.154 -0.230

1. 2.

Cyprus

3. 4. 5. 6.

o (2) •0.077 0.099 -0.333 0.413 -0.451

(1) Colombia

Honduras H o n g Kong

7.

Hungary

8.

India

9.

Iran

10. Israel 1 1 . Jamaica 12. Korea 1 3. Malta 14. Mexico I S . Philippines 16. Puerto Rico 17. Singapore 18. South Africa 19. Sri Lanka

0.146 -0.399 0.400 -0.072 0.255 -0.818 0.195 -0.814 0.195 -0.411 0.551 0.116 0.103 -0.277 0.279 -0.560 0.239 0.218 0.289 0.106 0.075 0.020 0.059 -0.571 0.205 -0.322 0.166 0.014 0.093 -0.614 0.364

-0.238 0.201 -1.053 2 1 . Thailand 0.238 0.221 22. Venezuela 0.218 -0.331 23. Zimbabwe 0.742 All entries are t o be divided by 1 0 0 . 20. Taiwan

U (3) -0.223 0.084 0.423 0.329 -0.053 0.093 0.057 0.350 -0.384 0.364 -1.168 0.251 -0.309 0.076 0.053 0.160 -0.132 0.404 -0.207 0.166 0.041 0.125 -0.260 0.132 -0.178 0.192 -0.228 0.057 -0.018 0.015 -0.171 0.163 -0.209 0.102 -0 045 0.044 0.084 0.146 -0.022 0.049 0.242 0.089 -0.179 0.103 -0.071 0.307

X (4) 0.182 0.033 0.431 0.241 0.106 0.040 -0.100 0.250 0.719 0.678 0.718 0.097 0.283 0.162 0.036 0.029 0.207 0.524 0.417 0.116 0.085 0.169 0.274 0.094 -0.176 0.118 0.170 0.059 0.057 0.045 0.170 0.059 0.336 0.106 0.019 0.025 0.098 0.049 0.720 0.166 0.222 0.065 0.006 0.062 0.411 0.799

a (5) -0.064 0.055

-0.136 0.090

0.272 0.226

-0.447 0.171

-0.618 0.122 -0.119 0.170 -0.050 0.046

-0.158 0.111 0.032 0.093 -0.134 0.051 0.025 0.116 0.028 0.072 0.104 0.078

s (6) -0.121 0.073 0.247 0.056 0.028 0.043 0.036 0.065 0.004 0.033 0.131 0.110 0.030 0.023 0.098 0.089 0.084 0.145 0.146 0.058 0.073 0.063 0.232 0.089 0.064 0.088 0.044 0.029 -0.005 0.020 0.213 0.060 0.088 0.045 0.061 0.022 -0.007 0.048 0.080 0088 0.309 0.154 0.078 0.012 0.227 0.226

H (7) 0.167 0.072 -0.668 0.383

Q£

XJ

(8) -0.015 0.049

(9) -0.005 0.016

2 (10) 0.156 0.067 -0.101 0.270 0.212

0.295 0.075 0.244 0.237

0.075 -0.007 0.182

-0.077 0.108

0.059 0.066 0.029 0.138

-0.108 0.129 0.059

0.184 0.086

-0.017 0.016

-0.030 0.008

0.382 0.071

-0.020 0.055

0.006 0.027

0.216 0.312 0.090 -0.100 0.165 -0.013 0.075

-0.059 0.037

0.016 0.156 0.035

0.040 0.062 0.145

0.136 0.107

0.148 0.020 0.049 0.094 0.111 0.120 0.151 0.023 0.047

0.065 0.342 0.262 -0.329 0.153 -0.274 0.177

0.332 0.086 0.072 0.108

0.814 0.155 0.275 0.087 0.252 0.345 0.097 0.085 0.018 0.178 0.289 0.165 0.220 0.284 0.031 0.066 -0.054 0.038 0.461 0.159 -0.104 0.157 -0.042 0.035 -0.022 0.128 -0.360 0.218 0.428 0.151 -0.126 0.172 -0.236 0.471

278

International Consumption Comparisons Table 9.4 Estimates of the income coefficients for 9 commodities and income flexibility under preference independence in 23 LD countries (Standard errors are presented below the estimates)

Country 1.

(1) Colombia

2.

Cyprus

3.

Ecuador

4.

Fiji

5.

Honduras

6.

Hong Kong

7.

Hungary

8. 9.

India Iran

10. Israel 1 1 . Jamaica 12. Korea 1 3. Malta 14. Mexico 15. Philippines 16. Puerto Rico 1 7. Singapore 18. South Africa 19. Sri Lanka 20. Taiwan 2 1 . Thailand 22. Venezuela 23. Zimbabwe

o (2) -0.044 0.036 •0.026 0.053 -0.048 0.047 -0.044 0.028 -0.038 0.019 -0.134 0.037 0.135 0.046 0.108 0.071 -0.142 0.029 -0.132 0.018 -0.109 0.037 -0.069 0.036 -0.132 0.038 -0.127 0.019 0.011 0.027 0.047 0.040 -0.079 0.030

U

(3) 0.039 0.027 -0.093 0.037 0.058 0.029 -0.030 0.006 -0.071 0.012 0.256 0.037 0.040 0.021 -0.010 0.058 -0.140 0.008 0.057 0.027 0.014 0.012 0.011 0.019 -0.003 0.019 0.062 0.015 0.009 0.007 0.017

-0.089 0.025 -0.042 0.054 -0.106 0.030 0.016 0.042 -0.156 0.052

0.030 0.026 0.018 0.035 0.012 0.007 0.016 0.015 0.007 -0.028 0.017 0.044 0.024

-0.013 0.054

0.005 0.019

o X (4) •0.104 0.013 -0.034 0.038 -0.044 0.014 •0.002 0.033 0.114 0.023 -0.119 0.014 -0.153 0.018 -0.058 0.011 0.091 0.023 -0.165 0.021 -0.031 0.019 -0.059 0.016 0.020 0.014 -0.079 0.016 -0.021 0.021 -0.040 0.012 -0.057 0.019 -0.077 0.006 -0.045 0.007 -0.096 0.025 •0.078 0.012 0.012 0.014 0.012 0.050

Q (5) 0.032 0.020

0.062 0.028

£ (7)

(8)

0.080

0.017 0.025 0.097

0.003 0.015

0.025 -0.025 0.007 •0.018 0.013 0.034 0.005 -0.008

0.015 0.031

0.003 -0.014 0.016

0.124 0.019 0.000 0.021 0.029 0.012

0.024 0.022 •0.024 0.017 0.033 0.013 0.036 0.012 0.008 0.011 0.034 0.014

0.032 0.028 0.006 -0.025 0.007 -0.022 0.009 -0.003 0.012 -0.020 0.008 -0.010 0.008 0.014 0.009 -0.015 0.016 -0.011 0.008 -0.011 0.005 -0.002 0.004 0.004 0.013 -0.034 0.028 -0.015 0.003 -0.024 0.012

(9) -0.001

5 (10) -0.022

c

01)

0.026 0.081

-0.256 0.037 0.855

0.059 -0.010 0.022 0.081

0.039 0.000 0.024 -0.039

0.265 -0.097 0.039 -0.427

0.012

0.013 0.003 0.004

0.035 -0.964 0.041

0.015 0.021 -0.017 0.032 -0.041

-0.262 0.061 -0.681

0.013 0.016

-0.006 0.001 0.007

0.153 0.027

•D

2

(6)

0.122 0.022 -0.007 0.018 0.014 0.014 0.038 0.023 0.088 0.019

0.030 0.029 0.030 0.024 0.078 0.018 0.050 0.034 0.099 0.023 0.138 0.031

0.005

•0.023 0.013

•0.009 0.002

•0.017 0.003

0.011 0.026

0.032 0.007

-0.009 0.003

-0.018 0.014 -0.014 0.013 0.035 0.010

0.006 0.011 0.042 0.025 0.006 0.010 -0.016 0.018 0.016 0.023 0.002 0.009

0,032 0.163

0.084 0.009 0.035 -0.789

0,019 -0.033 0.016 0.156

0.055 •0.412 0.033 -0.943

0.028 0.000 0.027 0.109 0.037 0.0O1 0.017 -0.012 0.018 -0.068

0.073 -0.256 0.040 -0.625 0.100 -0.025 0.019 -0.055 0.023 -0.879

0.032 0.073 0.029 0.024 0.012 0.014 0.013 0.060 0.033 -0.051 0.028 0.116

0.099 -0.286 0.059 -0.494 0.047 •0.512 0.066 -0.225 0.041 -0.245

0.040 0.020 0.038

0.052 -0.070 0.058 -1.096 0.249

Chapter 9 The Structure of Preferences

279

estimates were achieved even after suppressing the intercept term. Therefore, we report the elasticities based on the original model, (1.1), for the Philippines and the homogeneity constrained model for Hungary. The second point is that the income flexibility for Cyprus and India were positive contrary to its usual negative sign, however, with the suppression of the intercept term, the resulting income flexibility is negative, as it should be.

9.4

Testing Preference Independence

In this section, we test the hypothesis of preference independence, initially using a likelihood ratio test, which is an asymptotic test. We then check the validity of these results using Monte Carlo simulations proposed in Selvanathan (1987). Asymptotic test

We now test the preference independence hypothesis using the likelihood ratio test. The test statistic has an asymptotic %2 distribution with k = l/2n(n-l)-l degrees of freedom. The results for this test for the OECD and LD countries are presented in columns 2-4 of Tables 9.5 and 9.6, respectively. As can be seen, for most countries, preference independence is not supported by the data. This result is consistent with previous studies which use the asymptotic test (for example, see Barten, 1977). Below, we shall investigate this matter further. Monte Carlo test

It is now well accepted in the econometrics literature that the negative results of various hypothesis testing in demand systems are at least in part due to the failure

International Consumption Comparisons

280

Table 9.5 Testing preference independence in 22 OECD countries Asymptotic %2 test

Monte Carlo Simulations

Country

(D 1. Australia 2. Austria

Data-based Critical (2) (3) 96.18 X2(35)=49.80

Conclusion (4) Reject

Rank (5) 1000

Conclusion (6) Reject

58.54

Z2(35)=49.80

Reject

707

Do not reject

3. Belgium

50.42

X2(27)= 40.11

Reject

907

Do not reject

4. Canada

119.47

9C2(35)= 49.80

Reject

1000

Reject

5. Denmark

51.17

X2(35)= 57.34

Do not reject*

432

Do not reject

6. Finland

24.11

X2(27)= 40.11

Do not reject

93

Do not reject

7. France

99.85

3C2(35)= 49.80

Reject

998

Reject

1000

Reject

2

8. Germany

78.46

X (27)= 40.11

Reject

9. Greece

64.91

X2(35)= 49.80

Reject

879

Do not reject

10. Iceland

115.73

X2(35)= 49.80

Reject

11. Ireland

74.09

X2(35)= 49.80

Reject

770 652

Do not reject

12. Italy 13. Japan

47.98

X2(35)= 49.80

Do not reject

379

Do not reject

77.93

X2(27)= 40.11

Reject

996

Reject

14. Luxembourg

51.94

X2(27)= 40.11

Reject

594

Do not reject

15. Netherlands

51.21

Z

(27)= 40.11

Reject

946

Do not reject

16. New Zealand

50.98

2

X (9)= 16.92

Reject

982

Do not reject*

17. Norway

72.48

Z2(35)= 49.80

Reject

955

Do not reject*

18. Spain

62.51

X2(27)= 40.11

Reject

985

Do not reject*

19. Sweden

72.31

%2(35)= 49.80

Reject

954

Do not reject*

20. Switzerland

71.71

X2(27)= 40.11

Reject

998

Reject

21. UK

60.56

X2(27)= 40.11

Reject

972

Do not reject*

116.36

X2(35)= 49.80

Reject

1000

22. USA

2

Do not reject

Reject

k = Vi>n(n-1)-1. The level of significance a = 0.05. A * denotes critical value and conclusion at a = 0.01.

281

Chapter 9 The Structure of Preferences Table 9.6 Testing preference independence in 22 LD countries

Monte Carlo simulations

Asymptotic Xk test Country (1) 1. Colombia 2. Cyprus 3. Ecuador

Data-based Critical (2) (3) 109.07 X2(35)=49.80 41.17 86.55

%2(14)=23.68

Conclusion (4) Reject

Rank (5) 888

Conclusion (6) Do not reject

Reject

743

Do not reject

2

Reject

999

Reject

2

Do not reject*

X (20)=31.41

4. Fiji

67.08

X (14)=23.68

Reject

989

5. Honduras

34.79

X2(9)=16.92

Reject

919

Do not reject

6. Hong Kong

64.65

X2(35)=49.80

Reject

583

Do not reject

7. Hungary

42.57

X2(9)=16.92

Reject

899

Do not reject

8. India

65.23

Z2(20)=31.41

Reject

693

Do not reject

9. Iran

13.11

X2(9)=16.92

Do not reject

670

Do not reject

119.59

X2(35)=49.80

Reject

999

Reject

Do not reject

119

Do not reject Do not reject

10. Israel 11. Jamaica

15.90

2

X (14)=23.69 2

12. Korea

50.96

% (27)=40.11

Reject

621

13. Malta

61.70

X2(27)=40.11

Reject

609

Do not reject

14. Mexico

49.54

X2(27)=40.11

Reject

770

Do not reject

15. Philippines

21.69

X2(9)=16.92

Reject

510

Do not reject

16. Puerto Rico

57.63

X2(27)=40.11

Reject

962

Do not reject*

17. Singapore

35.76

X2(27)=40.11

Do not reject

420

Do not reject

65.63

X2(27)=40.11

Reject

989

Do not reject*

18. South Africa

2

19. Sri Lanka 20. Taiwan

70.38 37.07

Reject Do not reject

906

Do not reject

X2(27)=40.11

572

Do not reject

21. Thailand 22. Venezuela

30.01

X2(27)=40.11

Do not reject

35

Do not reject

20.85

Z

Do not reject*

437

Do not reject

23. Zimbabwe

33.55

X2(9)=16.92

Reject

875

Do nor reject

X (27)=40.11

2

(9)=21.67*

k = 14n(n-1)-1. The level of significance a = 0.05. A * denotes critical value and conclusion at a = 0.01.

International Consumption Comparisons

282

of asymptotic tests which use the moment matrix S that could be singular (or near-singular) with insufficient data (for a review, see Barten, 1977). To overcome the problems associated with the asymptotic tests, distribution-free tests based on Barnard's (1963) Monte Carlo simulation procedure have recently been developed for demand theory hypotheses, homogeneity, Slutsky symmetry (Theil, 1987) and preference independence (Selvanathan, 1987, 1993). The basic idea behind the Monte Carlo tests is to simulate a large number of values of the test statistic under the null hypothesis to construct its empirical distribution. The observed value of the test statistic is then compared to this distribution, rather than its asymptotic counterpart. Below, we set out this Monte Carlo procedure and then present its application to preference independence. Using the standard notation, consider the system of equations y = XP + e. Suppose we are interested in testing the null hypothesis RP = b using a test statistic x. Obviously x is a function of the estimate of the parameter vector p. In general, the Monte Carlo procedure can be summarized as follows: Step 1: Estimate the unrestricted model and obtain the data-based value Xi Of X.

Step 2: Estimate the model under the null hypothesis RP = b and obtain the estimate S of the covariance matrix £ of the disturbances. Step 3: Generate quasi-normal error terms with zero means and covariance matrix S and use these errors together with the observed value of X and the restricted estimates to generate a new data set for y under the null. Use the generated data to estimate the unrestricted model. Step 4: Repeat Step 3 a certain number of times, N say, and in each case calculate the simulated value of the test statistic x.

Chapter 9 The Structure of Preferences

283

Step 5: Let x2, x3 ... xM be the values of the test statistic x obtained from the simulated data, where M=N+1. For a one-tailed test, we reject the null hypothesis for the observed sample at the a percent significance level if Xi is among the M' largest values of the Xi's such that (M'/M)xl00 = cc. The number of replications (N) is usually chosen to be sufficiently large to reduce the 'blurring effect', which leads to loss of power (see Marriot, 1979). However, after a certain number of replications, the return for increased computing time diminishes. According to Besag and Diggle (1977), the suggested number of replications to reduce the "blurring effect' for a 5 percent significance test is 999. If we use a = 5 percent significance level and N = 999 simulations, for a one-tailed test, we reject the null hypothesis if the rank of X] is 951,....,999 or 1000. For a = 1 percent and N = 999 simulations, for a one-tailed test, we reject the null if the rank of Xi is 991, ...., 999 or 1000. We now apply this Monte Carlo simulation procedure to test the preference independence hypothesis using the data for the OECD and LD countries. The results for the OECD and LDC data are reported in columns 5 and 6 of Tables 9.5 and 9.6, respectively. As can be seen from Table 9.5, preference independence is now acceptable for 15 of the 22 OECD countries. The results are even more encouraging for the LD countries. As can be seen from Table 9.6, preference independence is now acceptable for 21 out of the 23 LD countries. Table 9.7 summarizes the hypothesis testing results for preference independence for the OECD and LD countries. As can be seen, all 45 countries taken together, preference independence of the utility structure is acceptable for 36 out of the 45 countries. Consequently, the overall picture which emerges from the table is that preference independence hypothesis is generally acceptable for the 9 broad commodity groups considered in this study.

International Consumption Comparisons

284

Table 9.7 Summary results: Testing preference independence 22 OECD countries and 23 LD countries LD countries

OECD countries

Country (3) Colombia Cyprus Ecuador Fiji Honduras Hong Kong Hungary India Iran

Conclusion (4) Do not reject Do not reject Reject Do not reject* Do not reject Do not reject Do not reject Do not reject Do not reject

Conclusion (2) Reject Do not reject Do not reject Reject Do not reject Do not reject Reject Reject Do not reject

1. 2. 3. 4. 5. 6. 7. 8. 9.

10. Iceland

Do not reject

10. Israel

Reject

11. Ireland 12. Italy 13. Japan 14. Luxembourg 15. Netherlands 16. New Zealand 17. Norway 18. Spain 19. Sweden 20. Switzerland 21. UK 22. USA

Do not Do not Reject Do not Do not Do not

reject reject

11. Jamaica 12. Korea 13. Malta

Do not reject Do not reject Do not reject

reject reject reject*

14. Mexico 15. Philippines 16. Puerto Rico

Do not reject Do not reject Do not reject Do not reject Do not reject* Do not reject Do not reject Do not reject Do not reject

Country

(D 1. 2. 3. 4. 5. 6. 7. 8. 9.

Australia Austria Belgium Canada Denmark Finland France Germany Greece

Do not reject* Do not reject* Do not reject* Reject Do not reject* Reject

17. 18. 19. 20.

Singapore South Africa Sri Lanka Taiwan

21. Thailand 22. Venezuela 23. Zimbabwe

The level of significance used is a = 0.05. A * denotes conclusion at a = 0.01.

Do not reject

285

Chapter 9 The Structure of Preferences

9.5

Implied Income and Price Elasticities

In Section 9.4, we found that the preference independence hypothesis is widely acceptable for the OECD and LD countries. In this section, we present the implied income and price elasticitiy estimates under preference independence. The income elasticity implied by model (1.3) can be calculated as ili = 1 + A ,

i=l,...,/L

(5.1)

When the budget shares are fairly stable over time, wit in (5.1) can be replaced by its sample mean wt = (1/T) X^i^r and the implied income elasticity can then be written as

ili = 1 + = S

i=l,...,n.

(5.2)

When Pi < 0, we can deduce from (5.2) that T|i will be less than one and good i will be a necessity. On the other hand, when Pi > 0, r|j will be greater than one and good i will be a luxury. Similarly, the Slutsky (or compensated) own-price elasticity of good i implied by model (1.3) at sample means is

Tin =

'-

'—

'•

'—,

1=1, ...,n.

(5.3)

286

International Consumption Comparisons

To calculate these elasticities, we use the ML estimates of the income coefficient (Pi) and income flexibility ((()) presented in Table 9.2 for the OECD countries and Table 9.4 for the LD countries and the budget shares presented in Table 3.3 (OECD) and Table 4.3 (LDC). We present these income and price elasticity estimates for the OECD countries in Tables 9.8 and 9.9 and for the LD countries in Tables 9.10 and 9.11. In general, all except four of the income elasticities presented in Table 9.8 are positive. As can be seen from column 2 of Table 9.8, the income elasticity estimates for food are all less than one and positive. This means that food is considered to be a necessity by consumers in the OECD countries. For consumers in most OECD countries, housing, medical care and education are also necessities as the income elasticity estimates are mostly less than one. Also, for consumers in most OECD countries, clothing, durables, transport and recreation are luxuries as their income elasticity estimates are mostly greater than one. The average OECD income elasticity is .58 for food, .44 for housing, .88 for medical care and .70 for education. Also, the OECD average income elasticity is 1.46 for clothing, 1.60 for durables, 1.79 for transport and 1.10 for recreation. All (except four) own-price elasticities are negative as they should be. Most of these own-price elasticities are less than one in absolute value, indicating that the demand for all goods is price inelastic. Looking at Table 9.10, we see that all but three of the income elasticities are positive. The average LDC income elasticity is .78 for food, 1.19 for clothing, .69 for housing, 1.52 for durables, .85 for medical care, 1.37 for transport, 1.20 for recreation and .66 for education. This means that, as in the case of the OECD consumers, the LD consumers also consider food, housing, medical care and education as necessities, and clothing, durables, transport and recreation as luxuries.

287

Chapter 9 The Structure of Preferences Table 9.8

0.716

1.482

5. 6. 7.

Denmark

0.449 0.612

1.613 1.474 0.834

8.

Finland France Germany

9. 10.

Greece

11. 12.

Ireland Italy

Iceland

13. Japan 14. Luxembourg

0.416 0.670 0.522 0.340 0.444 0.696 0.792

1.753

1.321

0.770

0.428 0.356

1.233

0.809 1.284

1.449

0.428

1.216 1.120

1.625 1.849

2.473 2.258 1.824

0.179

0.052

0.266 0.507

1.361 0.973 1.084 1.550

1.295

1.308 1.482 1.867

1.499

1.449

0.555 0.004

2.005

2.040

0.420 0.490

1.720 1.603

0.296

1.765 1.803 1.108 1.854

0.433 0.465 0.444

Norway

0.631

1.337

18.

Spain* Sweden

0.842

0.783

0.740

1.640

0.956

1.415 1.004 1.330

1.608

0.923 0.552 1.094 -0.029 0.692 0.358 0.404 0.304

1.498 1.199

0.148 0.632 0.616 0.826 1.011

1.576

1.282 1.632

0.809 2.034

1.829 1.264

1.895

0.691

1.497

0.845 1.680

0.923 1.729

(8) 2.038 0.990

(9) 1.615

(10) 1.064

0.825

0.855 1.834

0.272 1.752

-0.131

0.945

-0.393

1.413 1.464

1.739 0.849

1.168 0.676

0.926

1.524

0.770

1.416

1.647

-0.085 1.011

1.080 0.888

2.420

1.188

0.300

1.219 0.816

0.183

1.781 1.944

1.158 1.419

1.530

0.865 0.555

1.539 1.689 2.343

0.870 1.159

0.959

1.063 1.574 0.954

1.786

1.097

0.704

1.205

1.707

0.523

1.591

1.456 0.440 Mean 0.575 * Elasticities are from the no constant model.

1.595

0.880

0.609 0.365

1.967 1.309 2.200 1.584

1.437 1.662

1.892

0.789 0.798 0.325

21. 22.

Switzerland* UK USA

0.537

2.232 1.256

Netherlands New Zealand

20.

(7) 1.203 1.895

0.636 0.253

15. 16. 17. 19.

(6) 1.113 0.397

Miscel

Canada

0.494

(5) 2.567 1.304

Educat

4.

(4) 0.342

Recrea

1.204

Trans f

0.430

3.

Medic;

(3) 1.272 1.538

Durabl

(2) 0.428 0.647

Australia Austria Belgium

Housir

0) 1. 2.

Clothii

Country

Food

Estimates of the income elasticities under preference independence for 9 commodities in 22 OECD countries

1.228

288

International Consumption Comparisons Table 9.9

-0.372 -0.230

Finland France Germany

-0.055 -0.152

8. 9. Greece 10. Iceland 11. 12.

Ireland

-0.215 -0.105 -0.101 -0.085

(3) -0.624

(4) -0.175 -0.120

(5) -1.124

(6) -0.563

(7) -0.540

(9) -0.861

-0.304

-0.102

-0.361

(8) -0.961 -0.243

-0.033

-0.093 -0.662

-0.051

-0.076

-0.738 -0.153 -0.054

-0.688 -0.876 -0.162

-0.059 -0.243 -0.452

-0.550 -0.554

-0.337 -0.074 -0.802 -0.838 -0.145 -0.317 -0.490 -0.445 -0.362 -0.407

-0.006 -0.230

-0.764

-0.215

(10) -0.503 -0.192 -0.096

-0.256 -0.103

-0.610 -0.578 -0.121

-0.565 -0.104 -0.418

-0.521

-0.484 -0.623

0.034

-0.319

-0.282

0.128

-0.353 -0.071

-0.262

-0.400 -0.311

-0.060

-0.072

-0.518 -0.108

-0.095 -0.132

-0.158 -0.620 -0.495 -0.277

-0.001

-0.516

-0.198

-0.286 -0.463

-0.092 -0.041

-0.353

-0.187

-0.293

-0.126 -0.469

-0.086 -0.2%

-0.116 -0.590

-0.653 -0.167

-0.836 -0.070

-0.486 -0.152

-1.015 -0.915

-0.898

-0.615

-0.261

-0.201

-0.368 -0.632

-0.330

-0.368

Italy 13. Japan 14. Luxembourg

-0.049

15.

-0.045 -0.565 -0.300

-0.161

-0.055

-2.039 -0.679

-0.758

-0.118

-0.136

-1.019 0.017 -0.117 -0.088 -0.185

-0.409 -0.645

-0.034

-0.093

-0.148

-0.158

-0.171 -0.477

-0.538 -0.093

-0.105

-0.503

-0.358

-0.316

-0.275

-0.157

-0.448

-0.315

-0.429

-0.328

-0.251

-0.361

Netherlands New Zealand

16. 17.

Norway 18. Spain* 19. Sweden

-0.256 -0.185

-0.131 -0.624 -0.484

-0.236 -0.188

-0.050 -0.747

Miscellaneous

Education

Canada Denmark

Recreation

-0.026

Transport

5. 6. 7.

Austria Belgium

Medical care

3. 4.

(2) -0.208 -0.142

Durables

2.

(1) Australia

Housing

1.

Clothing

Country

Food

Estimates of the own-price elasticities under preference independence for 9 commodities in 22 OECD countries

20.

Switzerland*

-0.161 -0.337

21.

UK

-0.060

22.

USA

-0.115

-0.645 -0.109 -0.404

-0.176

-0.484

Mean

-0.385

-0.111 -0.362

* Elasticities are from the no constant model.

-0.161

-0.296 -0.049

-0.281 0.041

-0.443 -0.438 -0.087

-0.101

-1.057 -0.172

-0.426 -0.140

-0.410

-0.143 -0.477 -0.138

Chapter 9 The Structure of Preferences

289

Table 9.10

Taiwan Thailand* Venezuela

23. Zimbabwe

1.870

0.588 0.962

1.080 1.047

1.508 1.042

1.396 0.178 1.245 0.544 1.283 0.247 0.825 0.450 1.313 0.260 0.878 0.884 0.449 0.322 0.113 0.432 0.542

2.546 0.882 1.132

2.325 3.069 1.004 1.255 0.962 0.716 1.269 1.808 1.160 1.611

0.749 -2.164 1.790 1.669 0.508 -0.018 0.942 0.472 0.749 1.295 1.219 0.644 0.725 0.848 1.079 1.220 0.379 0.476

(7) 1.118 1.585 0.911 1.559

(8) 1.071

(9) 0.960

1.163

0.681

0.337

0.085

2.204

2.073 0.944

1.809

1.132

0.826 0.793

1.259 1.814

1.643

1.288 1.227 1.516 1.383

1.203 1.352 1.109 0.582

2.368 1.838

1.140 1.116

0.674

Miscellaneous

0.728 0.473 0.993

(6) 2.375 0.546 0.552

Education

(5) 1.549

Recreation

(4) 0.132

Medical care

(2) (3) 0.884 1.582 0.872 0.884 0.875 1.552 0.883 0.596 0.918 0.301 0.477 2.391 0.857 1.351 0.800 1.079 0.662 -0.298 0.516 1.869 0.740 1.376 0.827 1.169 0.620 0.967 0.637 1.725 1.234 1.018 0.951 0.902 0.698 1.319 0.737 1.401 0.931 1.096 0.749 1.290 1.094 0.625

Transport

Korea Malta Mexico Philippines Puerto Rico* Singapore South Africa Sri Lanka

Durables

12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22.

Housing

(1) Colombia 2. Cyprus 3. Ecuador 4. Fiji 5. Honduras 6. Hong Kong 7. Hungary** 8. India* 9. Iran 10. Israel 11. Jamaica 1.

Food

Country

Clothing

Estimates of the income elasticities under preference independence for 9 commodities in 23 LD countries

(10) 0.818 1.055 1.002 0.685 1.038 1.188 1.072 1.440 2.516 0.653 1.722 0.998 1.705 1.010 0.923 0.806 1.398 1.264 1.374 1.839 1.142 1.321 1.082

Mean 0.775 0.688 1.193 1.518 0.847 1.368 1.195 0.657 1.220 * Elasticities are from the no constant model. ** Elasticities are for homogeneity constrained model.

290

International Consumption Comparisons Table 9.11

Medical care

Transport

Recreation

Education

Miscellaneous

(8) -0.262

(9) -0.242

(10) -0.188

-1.183 -1.758 -1.558 -0.057 -0.126 -0.044 -0.158 -0.053

-1.416

1.035

-0.080

-0.077

-0.251

-0.515

-0.268

Housing

(7) -0.241

Clothing

3. 4.

(6) -0.524

Food

2.

(5) -0.361

(1) Colombia

(2) -0.151

(3) -0.361

(4) -0.033

Cyprus Ecuador

-0.323

Fiji

Country 1.

Durables

Estimates of the own-price elasticities under preference independence for 9 commodities in 23 LD countries

5.

Honduras

6.

Hong Kong

-0.243 -0.316 -0.510 -0.281 -0.807 -0.110 -0.350 -0.045

7.

Hungary**

-0.425

-0.720

0.392

-0.354

8.

India*

-0.029

-0.060 -0.032

-0.105

9.

Iran

-0.377

0.242 -0.593 -0.676 -0.096

11. Jamaica

-0.183 -0.482

12. Korea

-0.142

-0.277 -0.110

-0.642

-0.230 -0.255

-0.194

-0.227

13. Malta

-0.304

-0.556

-0.753

-0.564

-0.290 -0.640 -0.470

-0.784

14. Mexico

-0.013

-0.037 -0.006

-0.027 -0.019

15. Philippines

-0.023

-0.065

-0.041

-0.067

-0.044

16. Puerto Rico*

-0.526 -0.163

-0.631

-0.675

-0.336

-0.588 -0.122

-0.192

-0.800 -0.848 -0.180 -0.293 -0.324

-0.555 -0.297

18. South Africa 19. Sri Lanka

-0.273

-0.608

-0.154

-0.529

-0.348 -0.577 -0.514

-0.554

-0.203

-0.519 -0.057

-0.852

-0.428

-0.580 -0.291

-0.667

20. Taiwan

-0.115

-0.272

-0.090 -0.247 -0.229

-0.442

-0.223

-0.360

21. Thailand*

-0.104

-0.212

-0.113

-0.249 -0.318

-0.233

-0.218

22. Venezuela

-0.032

-0.091

23. Zimbabwe

-0.713

-0.998

-0.063 -0.846

Mean

-0.240

-0.442

-0.293

10. Israel

17. Singapore

-1.232

-1.026 -0.799 -0.259

-0.188

-0.916 -0.275

-0.170 -0.088

-0.282

-0.005

-0.112

-0.082

-0.652

-0.692

-0.007

-1.224 -0.701

-0.663

-0.309

-0.424

-0.204 0.017

-1.448 -0.273

-0.782

-0.252 -1.021

-0.037 -0.038

-0.022

-0.866

-0.026

-0.048

-0.510

-0.870

-0.395

-0.465

-0.336

-0.201

* Elasticities are from the no constant model. ** Elasticities are for homogeneity constrained model.

-0.354

291

Chapter 9 The Structure of Preferences

As can be seen from Table 9.11, almost all of the own-price elasticities are negative as they should be and most of them are less than one in absolute value, indicating that, in general, demand for all goods in the LD countries is also price inelastic. In contrast to the OECD results, demand for clothing in Cyprus and Jamaica, housing in Cyprus, medical care in Cyprus, Fiji and Iran, and transport in Cyprus are price inelastic. A comparison of the preliminary income and price elasticity estimates presented in Chapters 3 and 4 with the estimates presented in this section reveals that they are very similar.

9.6

Conclusion

In this chapter, we tested the well-known utility structure, preference independence among consumer goods. We used the asymptotic test as well as the Monte Carlo simulations to test this hypothesis. Table 9.12 presents a summary of the findings for the 45 countries (22 OECD and 23 LD countries) considered in this book. As can be seen from the table, among all 45 countries, preference independence among commodity groups is acceptable for 80 percent of the countries.

Table 9.12 Summary of acceptance of preference independence hypothesis: 22 OECD and 23 LD countries (D 1. Number of acceptance 2. Percentage acceptance

OECD countries (2) 15 68

LD countries (3) 21

All countries (4) 36

91

80

292

International Consumption Comparisons

We also presented the income and own-price elasticities under preference independence. The results show that, in general, for a typical 'world' consumer, food, housing, medical care and education are necessities while clothing, durables, transport and recreation are luxuries. Mostly, demand for all goods is price inelastic.

References Barnard, G.A. (1963). 'In discussion,' Journal of the Royal Statistical Society, Series B, 25: 294. Barten, A.P. (1969). 'Maximum Likelihood Estimation of a Complete System of Demand Equations,' European Economic Review 1: 7-73. Barten, A.P. (1977). 'The Systems of Consumer Demand Functions Approach: A Review,' Econometrica 45: 23-51. Bera, A.K., R.P. Byron and CM. Jarque (1981). 'Further Evidence on Asymptotic Tests for Homogeneity and Symmetry in Large Demand Systems,' Economics Letters 8: 101-105. Besag, J., and PJ. Diggle (1977). 'Simple Monte Carlo Tests for Spatial Patterns,' Applied Statistics 26: 327-333. Bewley, R.A. (1983). 'Tests of Restrictions in Large Demand Systems,' European Economic Review 20: 257-269. Chen, D.L. (2001). World Consumption Economics. Singapore, London: World Scientific. Clements, K.W., W. Yang and S.W. Zheng (1997). 'Is Utility Additive? The Case of Alcohol,' Applied Economics 29: 1163-1167. Laitinen, K. (1978). 'Why is Demand Homogeneity So Often Rejected?' Economics Letters 1: 187-191.

Chapter 9 The Structure of Preferences

293

Marriot, F.H.C. (1979). 'Barnard's Monte Carlo Tests: How Many Simulations?' Applied Statistics 28: 75-77. Meisner, J.F. (1979). 'The Sad Fate of the Asymptotic Slutsky Symmetry Test for Large Systems,' Economics Letters 2: 231-233. Moschini, G., D. Moro and R.D. Green (1994). 'Maintaining and Testing Separability in Demand Systems,' American Journal of Agricultural Economics 76: 61-73. Selvanathan, E.A. (1995). 'Data Analytic Techniques for Consumer Economics,' Chapter 3 in E.A. Selvanathan and K.W. Clements (eds), Recent Developments in Applied Demand Analysis. Berlin: Springer. Selvanathan, S. (1987). 'A Monte Carlo Test of Preference Independence,' Economics Letters 25: 259-261. Selvanathan, S. (1993). A System-wide Analysis of International Consumption Patterns. Boston: Kluwer Academic Publishers. Selvanathan, S., and E.A. Selvanathan (1994). Regional Consumption Patterns. London: Avebury Publishing Company. Theil, H. (1971). Principles of Econometrics. New York: John Wiley and Sons. Theil, H. (1980). The System-Wide Approach to Microeconomics. Chicago: University of Chicago Press. Theil, H. (1987). 'The Econometrics of Demand Systems,' Chapter 3 in H. Theil and K.W. Clements (eds.), Applied Demand Analysis: Results from Systemwide Approaches. Cambridge, MA: Ballinger Publishing Company. Theil, H., and R.B. Brooks (1970/71). 'How Does the Marginal Utility of Income Change When Real Income Changes?' European Economic Review 2: 218240. Theil, H., and K.W. Clements (1987). Applied Demand Analysis: Results from System-wide Approaches. Cambridge, MA: Ballinger Publishing Company.

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APPENDIX

The Demand Analysis Package 2000 (DAP2000) Wana Yang, Kenneth W Clements <& Dongling Chen

The Demand Analysis Package 2000 (DAP2000 for short) is a computer program written in the GAUSS matrix programming language for students and researchers working in applied demand analysis. It is an enhanced version of the Demand Analysis Package (DAP), which was written in FORTRAN and BASIC by Selvanathan et al (1989). Features of DAP2000 include: * Preliminary data analysis, which tabulates consumption data, computes a variety of Divisia index numbers and estimates demand elasticities based on double-log demand equations. * Hypotheses testing, using both conventional asymptotic procedures and the recently-developed Monte Carlo simulation approach. The hypotheses tested are homogeneity, symmetry and preference independence. * Estimation of demand systems. These demand systems include the Rotterdam model (Barten, 1964; Theil, 1965), Working's (1943) model, Working's model under substitution independence (Keller, 1984), Working's model under preference independence (Clements, 1987), Selvanathan's (1985) model, and the constant elasticity model. (The Rotterdam and Working's models are included in the hypothesis testing part of the package; the other models are included in the MAS part, mentioned below.)

International Consumption Comparisons

296

*

The matrix approach to simulation (MAS), which is a recently-developed technique to evaluate demand systems. Four demand systems are employed with MAS here, Working's model under substitution independence, Working's model under preference independence, Selvanathan's model, and the constant elasticity model. The GAUSS code for DAP2000 can be downloaded from the web site: http://www.econs.ecel.uwa.edu.au/erc/.

A.1

Using the Package

To use DAP2000, one needs a PC with GAUSS for DOS (version 3.01 or higher) installed under the subdirectory \gauss. Four steps should then be followed: 1. Set up a user-specified subdirectory. This step can be completed by using the md command under MS-DOS mode or by using Windows Explorer, File, New Folder under Windows. 2. Copy the program file, dap. run, and the input data file into the subdirectory defined in Step 1. 3. Switch to MS-DOS mode and then select the subdirectory defined in Step 1 by using the cd command. 4. Type \gauss\gaussi dap.run and press Enter. For GAUSS version 3.2.17 or higher, type \gauss\gauss dap2000r.run and press Enter. DAP2000 will then commence running and prompt for the name of the output file (no more than 8 characters). PLEASE NAME THE OUTPUT FILE>

The output file contains all the results and the interactive correspondence between the program and the user. It is located in the user-specified subdirectory, defined in Step 1 above, when no other path is given.

Appendix The Demand Analysis Package

A.2

297

Input Options

An ASCII file is needed for input data for running DAP2000. This can be created in EXCEL by saving the document as a text file, or as output from other programs. The construction of the data file is quite flexible in DAP2000, which provides seven options. This and the next section draws on Selvanathan et al (1989). Data File Options

The data file can be constructed using one of the following seven options according to the nature of the data. Option 1: (a) Consumption expenditures in current prices (in millions of currency units); (b) Consumption expenditures in constant prices (in millions of currency units); and (c) Population (in millions). Option 2: (a) Consumption expenditures in current prices (in millions of currency units); (b) Price indexes; and (c) Population (in millions). Option 3: (a) Per capita consumption expenditures in current prices (in currency units); and (b) Per capita consumption expenditures in constant prices (in currency units). Option 4: (a) Per capita consumption expenditures in current prices (in currency units); and (b) Price indexes. Option 5: (a) Volume of consumption of each commodity (in millions of units); (b) Prices per unit (in currency units); and (c) Population (in millions). Option 6: (a) Per capita volume of consumption of each commodity (in volume units); and (b) Prices per unit. Option 7: (a) Price log-changes of each commodity; (b) Quantity log-changes of each commodity; and (c) Average budget shares. Structure of Data File

For all options, the data should be arranged with each column indicating one commodity and each row indicating one observation. Let n be the number of

International Consumption Comparisons

298

commodities and T be the number of observations. The option-specified data files take the form as follows: Options 1. 2 and 5: Lines 1 to T (n+1 entries): Item (a) for the n commodities and item (c). Lines T+l to 2T (n+1 entries): Item (b) for the n commodities and zero. Options 3. 4 and 6: Lines 1 to T (n entries): Item (a) for the n commodities. Lines T+l to 2T (n entries): Item (b) for the n commodities. Option 7: Lines 1 to T (n entries): Item (a) for the n commodities. Lines T+l to 2T (n entries): Item (b) for the n commodities. Lines 2T+1 to 3T (n entries): Item (c) for the n commodities. Interactive Input The following interactive input is programmed in DAP2000. Data Description PLEASE INPUT THE NAME OF THE COUNTRY/REGION OF ANALYSIS> PLEASE INPUT THE NAME OF THE CURRENCY OF THE COUNTRY/REGION> PLEASE INPUT THE SAMPLE SIZE> PLEASE INPUT THE INITIAL YEAR (4 digits)> PLEASE INPUT THE NUMBER OF COMMODITIES> PLEASE INPUT THE NAMES OF THE COMMODITIES EACH COMMODITY NAME SHOULD BE LESS THAN 8 CHARACTERS (Press ENTER key after each commodity name) Commodity 1 > Commodity 2 > Commodity 3 > Commodity 4 > ENTER DATA INPUT OPTION 1: Consumption Expenditures in Current and Constant Prices for the Commodities; and Population 2: Consumption Expenditures in Current Prices and Price Indexes for the Commodities; and Population 3: Per Capita Consumption Expenditures in Current and Constant Prices for the Commodities 4: Per Capita Consumption Expenditures in Current Prices and Price Indexes for the Commodities 5: Volume of Consumption and Prices Per Unit for the Commodities; and Population 6: Per Capita Volume of Consumption and Prices Per Unit for the Commodities 7: Price and Quantity Log-Changes, and the Arithmetic Average Budget Shares for the Commodities

299

Appendix The Demand Analysis Package OPTION NUMBER>

(The message "PLEASE INPUT THE BASE YEAR (4 digits)>" follows when Options 1-4 are entered.) PLEASE ENTER THE INPUT FILENAME>

Task Selection The package performs three major tasks, (i) preliminary data analysis; (ii) hypothesis testing; and (iii) MAS. Users can perform these major tasks simultaneously or separately by selecting the corresponding options when the package prompts. Note that the preliminary data analysis procedure is not valid when data input option 7 is used. The messages prompted for task selection are as follows: IS PRELIMINARY DATA ANALYSIS REQUIRED? ( 0-No; 1-Yes ) > IS HYPOTHESES TESTING REQUIRED? ( 0-No; 1-Yes) >

When the "Hypotheses Testing" option is chosen, the following messages will appear: PLEASE SELECT DEMAND MODEL 1: Rotterdam Model 2: Working's Model OPTION NUMBER> DO YOU REQUIRE CONSTANT TERMS IN THE DEMAND EQUATIONS? (0-No,1-Yes)> PLEASE INDICATE THE SIMULATIONS 1: Normal Disturbances 2: Bootstrap Disturbances OPTION NUMBER>

METHOD TO

IS MAS REQUIRED? ( 0-No; 1-Yes) >

GENERATE

THE

DISTURBANCES

FOR

300

International Consumption Comparisons

When the "MAS" option is selected, the package asks about the number of trials for the simulations, and the format of simulation results (see Section A.5 for further information): PLEASE INDICATE THE NUMBER OF TRIALS FOR SIMILATIONS> WHAT FORM OF RESULTS DO YOU WANT PRESENTED? 1: Detailed Results 2: Summary of Results OPTION NUMBER>

A.3

Preliminary Data Analysis

The preliminary data analysis procedure computes a variety of Divisia index numbers, estimates demand elasticities based on double-log demand equations, and produces high-quality tables of the data. Depending on the input data option, the preliminary data analysis procedure produces some or all of the following items in the form of tables: [This does not apply to data Option 7 which produces no tables for this part of the package.] 1. Current price expenditure, total expenditure and population. 2. Consumption expenditure in constant prices. 3. Per capita expenditure in current prices. 4. Per capita expenditure in constant prices. 5. Prices (or price indexes). 6. Per capita volume of consumption. 7. Budget shares. 8. Price log-changes. 9. Per capita quantity log-changes. 10. Arithmetic average of budget shares. 11. Divisia moments. 12. Relative price log-changes. 13. Relative quantity log-changes. 14. Frequencies of relative price and quantity log-changes. 15. Frequency distributions of relative price and quantity log-changes. 16. Least-square estimates of double-log demand equations.

301

Appendix The Demand Analysis Package

17. Residuals from double-log demand equations. 18. Frequencies of joint signs of relative consumption (adjusted for autonomous trends) and relative price changes. Table A. 1 provides an overview of what is produced for each input option. An explanation of the terms used in the tables is provided in Chapter 2 of the book. Table A.1 Overview of output of preliminary data analysis Input option

Output item*

Total number of tables

1-2 1-5,7-18 18 3-4 3-5,7-18 16 5-6 5-18 15 7 None 0 * Note that when an item is not produced for a given input option, the program will automatically skip it and continuously count the next item. Note also that two tables are produced for item 17, one for residuals with constants, and one for residuals without constants.

A.4

Hypothesis Testing and Estimation

The hypotheses of demand homogeneity, Slutsky symmetry and preference independence are tested in this part of the package, using both conventional asymptotic procedures and a newer Monte Carlo simulation approach. Two popular differential demand systems are used here, viz., the Rotterdam model and Working's model. A brief introduction to differential demand systems is given in Chapter 2 of this book.

International Consumption Comparisons

302 Two Demand Systems

Let pit, qit be the price and quantity demanded for commodity i (i=l,...,n) at time t (t=l,...,T), M(=X"=iP„9,( be total expenditure ('income' for short), where n is the number of commodities. Let wit=pitqit/Mt be the share of 1 income devoted to commodity i at year t, or the i" budget share. Furthermore, let wit be the arithmetic average of the i* budget share in year t and t-1; Dpit = logpit - logpit_x and Dqu = logqit - logqit_x be the log-change in the price and quantity of i from t-1 to t. Finally, define DQ, =£"=1wir £>#,., as the Divisia volume index. The Rotterdam Model The i* equation of the absolute price version of the Rotterdam model (Barten, 1964; Theil, 1965) takes the form witDqit = a, +0,D<2, + 1 XijDpj, +eu ,

(A4.1)

where cij is the intercept for commodity i; &, is the marginal share of i;flyis the (ij)* Slutsky coefficient; and elt is a disturbance term. As there are n commodities, the Rotterdam model consists of equation (A4.1) for i=l,...,n. The adding-up conditions for equation (A4.1) for i=l,...,n are Z"=ia;',- = 0> Y!i=\9i =1 and X"=i fty - 0 . These constraints imply that one of the demand equations is redundant, so that only n-\ equations are estimated. As there are t=l,...,T observations, we can express equation (A4.1) in vector form as y,= x Y,+e,-.

(A4.2)

Appendix The Demand Analysis Package

303

where yl = [yn,...,yn.]' withyu = witDqu, t=l,...,T; X=[i,DQ,DP1,...,DPJ is a Tx(«+2) matrix with i = [1,...,1]' a Txl vector, DQ= [DQU...,DQT]', DPj = [Dpku...,DpkT]' (k=l,...,«); Yi is a vector of (n+2) elements, with yi=[ai,0i,na,...,7iin]'\ and £,• = [en,...,ein ] ' . We can write equation (A4.2)fori=l,...,«-las y = ( I ® X ) Y + E,

(A4.3)

where y = [ yi,--,yn-i ] ' ; I is an (rc-l)x(rc-l) identity matrix; ® denotes the Kronecker product; Y = tYi»—.Yn-J'! anc^ e ~ [ei»"-,e'„-i]' • Equation (A4.3) represents a system of equations that can be estimated jointly by using GLS. The same result is obtained by applying OLS to each equation separately as each equation has the same independent variable matrix, X. Working's Model The i* marginal share 0; in equation (A4.1) is specified as a constant in the Rotterdam model. Under Working's (1943) parameterization, this marginal share is variable and takes the form fit + wit, where (3; is the (constant) income coefficient for commodity i and wit is the arithmetic average of the i* budget share in year t and t-1. Accordingly, the i* equation of this model is wit(Dqit -DQ,) = a, +/3tDQ, + £ n Dpj, +eu.

(A4.4)

The adding-up conditions for (A4.4) are YH=ia, = 0. S"=i A = 0 and Y."=\ n$ = 0, again implying that the number of equations to be estimated is n-1. Equation (A4.4) can be also expressed in the vector form as (A4.2) and (A4.3) by defining the following: yit=wit{Dqit-DQt) and

International Consumption Comparisons

304

Y, = [ai,/3i,nn,...,Kjn]'. As Working's model and the Rotterdam model are so similar, the discussion that follows in the next four sections will be based on the Rotterdam model only. The modifications required for Working's model are entirely straightforward. DAP2000 provides results for both models. Homogeneity

The hypothesis of demand homogeneity states that an equi-proportional change in all prices has no effect on any quantity demanded, when real income is held constant. In other words, consumers do not suffer from money illusion. In the context of the Rotterdam model (A4.1), homogeneity takes the form lTtij-0,

i=l

n.

(A4.5)

j=i

That is, the Slutsky coefficients 7l,j sum to zero over the second subscript. The vector form of (A4.5) is V'YJ = 0,

i=l,...,n,

(A4.6)

where v ' = [ 0, 0, 1, ..., 1]. As one equation is redundant in estimation, (A4.6) for i=l,..., n-\ can be written as R y = 0 , where R = I ® v ' ,

(A4.7)

with I the (n-l)x(n-l) identity matrix. Let b be the OLS estimator of Y- b =[b'1,...,b'„_1]' with b.^CX'X^'X'y,, i=l,..., Ti-1. Let S = [S;J] be an (7I-1)X(TZ-1) matrix with st: = e't e • /(T-k), where e; =y{ - X b ; is the OLS residual vector of the

Appendix The Demand Analysis Package

305

i equation and k is the number of independent coefficients in each equation. In the case of equation (A4.1), we have k = n+2. We assume that the disturbances Eit are normally distributed with zero means and a constant contemporaneous covariance matrix 2 , so that S is an unbiased estimator of 2 . Then, under the null hypothesis (A4.7), the test statistic b'R'S^Rb

v'(X'X) _1 v has an exact distribution as Hotelling's T2 with (n-l) and (T-k) degrees of freedom. This can be expressed as a multiple (n-l)(T-k)/(T-k-n+2) of F with (n-l) and (T-k-n+2) degrees of freedom. For more details, see Laitinen (1978) and Theil (1987). When homogeneity is imposed, equation (A4.1) can be written as witDqit =a t +diDQl +"f * (Dpj, -Dpnt) +eu.

(A4.8)

As each equation in (A4.8) for i=l,...,n-l has the same variables on the righthand side, the homogeneity-constrained estimator is obtained by applying OLS to each equation separately. Symmetry

The hypothesis of Slutsky symmetry states that when real income remains unchanged, the effect of an increase in the price of commodity i on the quantity demanded of commodity j is exactly the same as the effect of an increase in the price of commodity j on the demand for i. This implies that the substitution

International Consumption Comparisons

306

effect is symmetric in i and j , dqi/dpJ = dqj/dpi, implies that the Slutsky coefficients are symmetric Kij=Kji,

i,j=l,...,n.

i,j=l,...,n. In turn, this

(A4.9)

The objective here is to test (A4.9) given homogeneity. The total number of symmetry relations in (A4.9) for i=l,...,«-/ is m = (n-l)(n-2)/2. Accordingly, the hypothesis of Slutsky symmetry can be written in vector form similar to (A4.7) with R now being an mxn(n-l) matrix. The nonzero elements of R take the form ry = 1 and rik = -1 for i=l,...,m, j = (c-l)(n+l)+d+2 and k = (d-l)(n+l)+c+2, where c =l,...,n-l and d = c+l,...,n-l. These non-zero elements correspond to 7itj and n^for i^j. Let b be the estimator of y in (A4.3) under homogeneity, and S be the corresponding unbiased estimator of the disturbance covariance matrix 2 . Under normality, the test statistic b'R'{R[S ® (X'X)"1]R'}"1Rb is asymptotically (T—> °°) distributed as x^ under the null hypothesis (A4.9). The symmetry-constrained estimator and its covariance matrix are (Theil, 1987, p. 116) b = b-CR / [RCR']" 1 Rb var(b) = C - CRlRCR']"1 RC , where C = S ® (X'X)" 1 .

Appendix The Demand Analysis Package

307

Preference Independence, Part I: An Asymptotic Test

Consider the situation when the consumer's tastes can be characterised by a utility function that is additive in the n commodities: n

u(ql,...,qn)

= 'Zui(qi),

(A4.10)

i=l

where q\ is the quantity consumed of commodity i and U\(-) is the i* sub-utility function. Here, as the marginal utility of i is independent of the consumption of j , i*j, the Hessian matrix of the utility function is diagonal and (A4.10) is known as preference independence. Under preference independence, the Slutsky coefficients satisfy (see, e.g., Clements et al, 1995) TCI:/ =- - e

y

),

(A4.ii)

where (() is the income flexibility; 9; is the marginal share of i in equation (A4.1); and 8y is the Kronecker delta which takes the value of one if i=j and zero otherwise. The objective here is to test constraint (A4.ll) for i,j=l,...,«-7, given homogeneity and symmetry. We impose the hypothesis of preference independence by substituting the right-hand side of (A4.ll) for TTy in (A4.1) to obtain witDqit = or. + OPQ, + 06, [DPit -DPt']+eit,

(A4.12)

where DP't=Y!i=\^iDpit is the Frisch price index. As the term Dpu-DPt' is interpreted as the change in the relative price of commodity i, the implication of (A4.12) is that under preference independence only the own-relative price

308

International Consumption Comparisons

appears in each demand equation, which greatly reduces the number of unknown coefficients to be estimated.1 Equation (A4.12) is non-linear in its parameters and can be estimated by using a maximum likelihood procedure. The hypothesis of preference independence can then be tested using the likelihood ratio statistic A = -2(L r - L u ), where L r is the log-likelihood value for the restricted model, equation (A4.12), and L u is the corresponding value for the unrestricted model, equation (A4.8) with n^ -njt (i,j=l,...,«-7) imposed. Under the null hypothesis (A4.ll), A, has an asymptotic %2 distribution with n +(n-l)(n-2)/2 - 2 degrees of freedom. Preference Independence, Part II: A Simulation-Based Test

The likelihood ratio test of preference independence discussed in the previous section has only asymptotic justification; i.e., it holds only when the number of observations is large. The asymptotic nature of the test can bias the results against the null in small samples. The same problem also applies to the standard asymptotic tests of homogeneity and symmetry (Theil, 1987). To avoid these problems, this section sets out a distribution-free test procedure based on Monte Carlo simulations, which was first introduced into demand analysis by Theil et al (1985). This procedure involves comparing the data-based value of the test statistic with its empirical distribution generated from a simulation, rather than its asymptotic counterpart.2 For testing preference independence, both the restricted model (A4.12) and the unrestricted model (A4.8) with symmetry imposed are estimated and their likelihood values are computed. The procedure is as follows:

1

2

Other implications of preference independence are that inferior goods are ruled out and all goods are Slutsky substitutes. See also Selvanathan (1987, 1993), Taylor et al (1986) and Theil et al (1985).

Appendix The Demand Analysis Package

309

Step 1: Generate disturbances from a multivariate normal distribution with zero mean vector and covariance matrix S, the mean squares and cross-products of the restricted residuals.3 Step 2: Generate simulated values of the dependent variable of the restricted model by using (a) the data-based estimates of its coefficients, (b) the observed values of the independent variables, and (c) the generated disturbances. Step 3: Estimate both the restricted and unrestricted models with the generated values of the dependent variable and the observed values of the independent variables, and compute their log-likelihood values Lsr and Lsu , respectively. Step 4: Compute the value of the likelihood ratio test statistic A? = -2(L s r - L s u ). Step 5: Repeat 1,000 times Steps 1-4 to generate the simulated distribution of the test statistic under the null hypothesis. Step 6: Reject the null at the 5 percent level if the observed value of the test statistic X is larger than 950 simulated values of Xs. The assumption of normality of the disturbances can be relaxed by using the bootstrap procedure (Efron, 1979) to generate disturbances in Step 1. The DAP Output

The hypotheses testing and estimation procedure in the package produces the following results in the form of tables: 1. 2. 3. 4.

Estimates of the unrestricted model. The observed value of Hotelling's T2 test statistic. Estimates of homogeneity-constrained model. The asymptotic %2 test statistic for symmetry given homogeneity, its critical value and the test result at the 5 percent level. 5. Estimates of symmetry-constrained model. 6. Estimates of preference independent version of the model. 7. The asymptotic %2 test statistic of preference independence (given symmetry and homogeneity), its critical value and the test result at the 5 percent level. 3

Let S = L L , where L is the Cholesky decomposition for S. The quasi-normal error vectors, e, with zero mean and covariance matrix S can be generated from the standard normal error vector e* ~ iVf0,I) by using the transformation e=Le*.

310

International Consumption Comparisons 8. The simulation-based test result of preference independence (given symmetry and homogeneity), using normal disturbances. 9. The simulation-based test result of preference independence (given symmetry and homogeneity), using bootstrap disturbances.

Whenever estimates are reported, there is an accompanying table of the corresponding elasticities. Note that items 8 and 9 above are mutually exclusive. Therefore, a total of 12 tables are produced by this procedure.

A.5

The Matrix Approach to Simulation

The matrix approach to simulation (MAS) is a new technique for evaluating demand systems, which was developed by Clements et al (1998).

For

convenience, some details are presented here.

Four Demand Equations Although MAS is a general methodology for evaluating a number of alternative demand models, we confine ourselves to four such models. Working's Model under Substitution Let

yit=wit{Dqit-DQt).

For

Independence

commodity

i,

Working's

model

under

substitution independence takes the form

yu=a,+PtDQ,+Mji,+-wu)

Dpu-'£(Mj+wJ,)DpJt

+£„,

(A5.1)

where (%,ft,jUi and A are coefficients. This model is due to Keller (1984) who calls it the CBS/SI model. As this equation is formulated in terms of changes,

311

Appendix The Demand Analysis Package

the intercept (% reflects the residual trend in consumption of commodity i. Note that as Z/C/Zj+w^ J = l, the second term in the square brackets, Y.j( Mj+Wjt )Dpjt, is a weighted-average of the n prices, or a price index. Accordingly, the whole term in the square brackets is interpreted as the change in the relative price of commodity i. Note also that only the own relative price appears in this equation. The coefficients satisfy the following adding-up restrictions: X"=i a ,- = 0. X?=i/?,=0, S"=iMi= 0 • Dividing both sides of equation (A5.1) by wit and rearranging yields the following income and Slutsky ownprice elasticities for commodity i at time t

'lit

~ * "•" — ' W,,

'Iiit ~

— W:,

Working's Model under Preference Independence Working's model under preference independence can be expressed as (see, e.g., Clements, 1987, Sec. 1.15)

yu=ai+PlDQ,

+ 0(/Bi + wlt) DPu-JKPj+njtiDpj,

+£it,

(A5.2)

7=1

where (|) is the income flexibility (the reciprocal of the income elasticity of the marginal utility of income). Keller and van Driel (1985) call equation (A5.2) the CBS/PI model. The term in the square brackets is again the change in the i* relative price, with a (slightly) different price index acting as the deflator. The income and Slutsky own-price elasticities are

312

International Consumption

Comparisons

«H#+w,)[l-(#-w,)] w,.

Note that if the coefficient jx, in equation (A5.1) equals p ; , then (A5.1) becomes (A5.2). Selvanathan's Model Selvanathan's (1985) model can be written as

y^a^ftDQ.

+ yw,

+£«>

(A5.3)

7 =1

where y is a new coefficient, interpreted as the (common) elasticity of substitution. The income and Slutsky own-price elasticities are Vu=l + -=-,

tim=r(l-wa).

If (Xj - 0 in equation (A5.1), then that model becomes (A5.3). The Constant Elasticity Model The constant elasticity model takes the form Dqa = a, + n,DQ,+Vf,DPit-Y.Wj,Dp.

+ £«>

(A5.4)

where T], is the income elasticity and \|/; is a new coefficient. The Slutsky own-price elasticity for commodity i is

Appendix The Demand Analysis Package

313

y\iit = V f U - W f r ) . As is well known, equation (A5.4) does not satisfy the budget constraint; but it is still used as a pragmatic model. Note that (A5.4) is not a special case of (A5.1). As equations (A5.1) and (A5.2) are nonlinear in the parameters, we use a maximum likelihood procedure to estimate all four models.

Simulation Procedures

This section sets out the methodology of the matrix approach to simulation. We use the observed data set to estimate model j and provisionally regard it as the "true" model. The implied income and own-price elasticities are calculated and regarded as the true elasticities. Artificial data for the dependent variable are then generated from model j , by using the estimated parameters, the observations of the independent variables and simulated disturbances. These artificial data are then used to estimate model k. For all possible pairs k,j=l,2,3,4, this procedure yields a 4x4 comparison matrix. To describe this procedure in more detail, we write M(k| j) to denote the situation when model k is estimated given that the true model is j . ThisM(klj) lies behind the (kj)"1 cell of the 4x4 comparison matrix, as shown in Table A.2. Table A.3 gives the detailed simulation procedures for M(k|j). By repeating Steps 1-9 of Table A.3, with appropriate modifications for the true and the estimated models, we obtain all entries of Table A.3. Note that the diagonal of Table A.2 contains cases when the true and the estimated models coincide. These diagonal cases provide a simulation-based evaluation of the quality of the ML estimates for each of the four models; see Theil et al (1983) for details. Note also that the evaluation procedures described

314


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International Consumption Comparisons

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Appendix The Demand Analysis Package

il ! !

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International Consumption Comparisons

•W5 -1 =

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• m -I =

>WI

s aa

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<S 3 s 1

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317

Appendix The Demand Analysis Package

in this section are focused on the quality of the elasticity estimates. These procedures can be easily modified when the coefficients of the models are of major interest; see Clements and Chen (1999). The Loss Function To evaluate the performance of the models, a loss function is used in this section which combines the bias and the standard error into a scalar measure. Let the loss function take the general form /(B,S), where B is the bias and S the standard error. It seems reasonable to postulate /, ^ 0 for i = B, S (where /,• = df/di), and/,,>0 (where fu-d2f/di2). A simple functional form satisfying these properties is f{B,S) = jaB2+(l-a)S2,

(A5.6)

where 0 < « < 1 . According to (A5.6), the square of the loss is a weighted average of the squared bias and the variance. It has the attraction of involving only one unknown parameter, a. This function implies the following losses for various values of the weight parameter or. a

Loss

1

B

/2

(Jk)RMSE

0

s

1

The DAP Output

For each of the four demand systems (A5.1)-(A5.4), the following output is produced by the MAS procedure in DAP2000:

International Consumption Comparisons

318 1. 2. 3. 4.

The estimated coefficients of the true model. The estimated income elasticities of the true model. The estimated price elasticities of the true model. The biases, root-mean-square-errors and standard errors of the simulated income and price elasticities for each of the four estimated models, given the true model. 5. Values of the loss function when a is 1 (the bias), .75, .5, .25 and 0 (the standard error) for each of the four estimated models, given the true model. Two options are provided for item 4 above. Under the "detailed results" option, details of the biases, standard errors and root-mean-square-errors for both income and own-price elasticities are presented in six tables for each estimated model. Accordingly, 4 x ( 6 + l) + 3 = 31 tables are produced for each true model and a total of 123 tables for the four demand systems.4

Under the

"summary of results" option, sample means of the biases, standard errors and root-mean-square-errors for both income and own-price elasticities are given in one table for each estimated model. Consequently, 11 tables are produced for each true model and a total of 43 tables for the four models. Note that in some cases, the estimation procedure may not converge within 30 iterations. In such a case, a message is printed that "Model did not converge" and the MAS output is omitted when the model in question is the true model. Therefore the number of tables generated by the package may be less than the total number of tables mentioned above.

In the case when the constant elasticity model is the true model, as the estimated coefficients coincide with the income elasticities, the table for these elasticities is omitted. In this case, the total number of tables is 30.

319

Appendix The Demand Analysis Package

References Barten, A. P. (1964). 'Consumer Demand Functions Under Conditions of Almost Additive Preferences,' Econometrica 31: 1-38. Clements, K.W. (1987).

'Alternative Approaches to Consumption Theory,'

Chapter 1 in H. Theil and K.W. Clements Applied Demand

Analysis:

Results from System-Wide Approaches. Cambridge, Ma.: Ballinger, pp.l35. Clements, K.W. and D.L. Chen (1999). 'Simulating Demand Systems,' Chapter 8 in D.L. Chen (ed.) World Consumption Economics.

Singapore, London:

World Scientific, pp. 198-212. Clements, K.W., S. Selvanathan and E.A. Selvanathan (1995). 'The Economic Theory of the Consumer,' Clements (eds) Recent Alcohol,

Advertising

Chapter 1 in E.A. Selvanathan and K.W.

Developments

in Applied

and Global Consumption.

Demand

Analysis:

Berlin, Heidelberg:

Spring-Verlag, pp. 1-72. Clements, K.W., W. Yang and D.L. Chen (1998).

'The Matrix Approach to

Evaluating Demand Equations,' Applied Economics 33: 957-967. Efron, B. (1979). 'Bootstrap Methods: Another Look at the Jackknife,' Annals of Statistics 7: 1-26. Keller, W.J. (1984). 'Some Simple but Flexible Differential Consumer Demand Systems,' Economics Letters 16: 77-82. Laitinen, K. (1978).

'Why is Demand Homogeneity So Often Rejected?'

Economics Letters 1: 1987-91. Selvanathan, E.A. (1985).

'An Even Simpler Differential Demand System,'

Economics Letters 19: 343-47. Selvanathan, S. (1987). 'A Monte Carlo Test of Preference Independence,' Economics Letters 25: 259-61.

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Selvanathan, S. (1993). A System-Wide Analysis of International Consumption Patterns. Dordrecht, Boston, London: Kluwer Academic Publishers. Selvanathan, S., E.A. Selvanathan and K.W. Clements (1989). 'Demand Analysis Package, DAP: A Users Guide,' Discussion Paper 89.04. Department of Economics, The University of Western Australia. Taylor, T.G., J.S. Shonkwiler and H. Theil (1986). 'Monte Carlo and Bootstrap Testing of Demand Homogeneity,' Economics Letters 20: 55-57. Theil, H. (1965). 'The Information Approach to Demand Analysis,' Econometrica 33: 67-87. Theil, H. (1987). 'The Econometrics of Demand Systems,' Chapter 3 in H. Theil and K.W. Clements Applied Demand Analysis: Results From System-Wide Approaches. Cambridge, Ma.: Ballinger, pp. 101-62. Theil, H., R. Finke and M.C. Rosalsky (1983). 'Verifying a Demand System by Simulation,' Economics Letters 13: 15-18. Theil, H., J.S. Shonkwiler and T.G. Taylor (1985). 'A Monte Carlo Test of Slutsky Symmetry,' Economics Letters 19: 331-332. Working, H. (1943). 'Statistical Laws of Family Expenditure,' Journal of the American Statistical Association 38: 43-56.

INDEX

Subject Index Additive, 13,40,42,66,67,120, 269, 292,307,319 Aggregation, 17,30, 37,63, 64, 66,67, 68, 69, 246, 247 AIDS, 53, 56, 57, 58, 59, 60, 61, 228, 249,250, 260, 264 Alternative demand systems, 228 Annual growth, 78,130 Area, 4 Asymptotic test, 233, 235, 239, 241, 268,279,282,291,308 Australian states, 26 Average growth, 76, 78, 130, 135, 172 Block independence, 42,43 Blurring effect, 283 Budget constraint, 10, 11,13, 32, 33, 44,45, 313 Budget shares, 17,19,22,25,32, 36, 41, 54, 58,74,75,76,78, 94,95, 96, 97, 98, 127,129, 146, 170, 171,193,195,198,199,213,285, 286,297, 300 CBS, 30, 61, 62, 63, 105, 228, 249, 250, 251, 256, 260, 264, 265, 268, 269 CBS, 310, 311 CBS/PI, 62,63,105, 311 CBS/SI, 61,62,63,310 Compensated, 8, 10, 35, 36, 285 Complements, 41, 49

Consumer demand, 14,22, 30,63, 227, 228 Consumer preference, 2, 9, 31 Consumption comparisons, 14, 18 Consumption patterns, 1, 71,125,169, 170,175,184, 185 Contemporaneously correlated, 251 CPI, 201 Cross-equation restriction, 239 Cross-price elasticities, 9, 38, 39 Cross-sectional, 15 DAP2000,71, 125, 295,296,297, 298, 304, 317 Data analysis, 71,105,125,169,182, 184, 228, 295, 299, 300, 301 Demand analysis, 30, 34, 63, 187, 249, 250,251,227,295,308 Demand curves, 9 Demand homogeneity, 8, 37, 38,49, 64, 227, 230, 231, 233, 241, 245, 250,251,264,267,301,304 Demand theory hypotheses, 227,228, 241, 243, 244, 245, 249,250, 264, 282 DEMMOD,251,265 Differential demand equations, 30, 64, 65 Distribution-free, 227,268, 282, 308 Divisia price, 19,21,83 Divisia moments, 21, 87, 88,135,140, 175,300

322 Divisia price variance, 83,135,175, 196 Divisia price-quantity correlation, 83, 135, 172 Divisia quantity variance, 19, 21, 83, 88,135,139,172,175 Divisia volume, 18, 44, 48, 51, 78, 81, 130, 302 Double-log, 14, 34,43,71,102,125, 153,179,295, 300, 301 Economic indicators, 3 Elasticites, 102, 153 Empirical distribution, 282, 308 Empirical regularities, 71, 94,141,169, 175,179,184 Engel's law, 6,14,17,27,71,94,120, 122, 125, 141, 146, 169,170, 179, 184 Engle aggregation, 37 Estimation procedure, 268, 269, 270, 273,309,318 Exact test, 231, 233, 234, 235, 237, 241 Exports, 3 Finite-change version, 51, 52, 62, 105, 118,250,257 Functional approach, 187 GDP, 2,5,6,7, 117, 166,225 Goodness-of-fit, 24, 250, 256, 259, 265 Imports, 3 Income elasticity, 7, 9, 10, 22, 34, 36, 38,40,41,50,54,58,59,102, 105,106,117,118,119,153,156, 167,179, 270, 285,286, 311, 312 Income flexibility, 40,42,48,71,105, 106,107,112,113,114,116,125, 156,157,162, 165,179,180,182, 270,273,276, 279, 286,307, 311 Indirect utility, 52, 55 Industrialised countries, 1

International Consumption Comparisons Inferior good, 34,41, 55, 308 Inflation, 3, 5, 6,187,188,190,192, 198,199,200, 201,203,204,205, 206,213,214, 215,224,225 Information inaccuracies, 25,259, 260 Information matrix, 272 Klein-Rubin, 40, 53, 55 Lagrangian, 32, 33 Land size, 2 Language, 2,4,16, 27 Law of demand, 89,141,169,176 LES, 13, 22, 53, 54, 55, 59 Less developed countries, 1, 15 Likelihood ratio test, 16,279,308, 309 Low-income countries, 1 LPW database, 19 Luxury, 54, 59, 269, 276,285 Marginal share, 22, 36,41, 48, 54, 55, 58, 228, 302,303, 307 Marginal utility, 13, 33,40,42,43,48, 105,117,269,270,307,311 Marshallian, 33, 35,47 Matrix approach, 296, 310, 313 Maximum likelihood, 270, 308, 313 Microeconomic policy, 2 ML estimates, 286, 313 Model estimation, 265 Money illusion, 8, 304 Money income, 7, 8, 35, 37,48 Monte Carlo simulations, 279, 281, 291,308 NBR, 61,62, 228, 249,250,251, 260, 264 Necessary condition, 231 Necessity, 54, 59,102,156, 269,276, 285,286 Non-singularity, 233, 235 Organisation for Economic Cooperation and Development, 1

Index Own-price elasticity, 35,41,102, 118, 119,153,167,176,285,312 Population, 2,4,28,71,105,126,297, 298, 300 Predicted budget shares, 257, 259 Preference independence, 13, 40, 41, 42,43,50,52,62,71,105,118, 119,125,166,167,169,179,182, 267, 268, 269, 279, 280, 281, 282, 283, 284,285, 291, 292,295, 296, 301,307,308,309,310,311 Preferred demand system, 249, 259, 260, 264 Preliminary estimates, 71, 102, 125, 153, 276 Price index, 7, 8, 35, 41, 44, 48, 49, 51, 81, 87, 106, 130, 135, 192, 195, 297,300,307,311 Private consumption, 2 Quadratic expenditure system, 17 Quasi-normal error, 282, 309 Real income, 8, 12, 36, 38, 48,105, 117,166,188,304,305 Regional, 24,28, 120,121,122,123, 293 Relative consumption, 89, 93,114,115, 116, 141,145, 163, 164, 176, 177, 178,301 Relative price, 8, 41, 43, 48, 49, 50, 52, 65, 89, 91, 93, 102,106,108,109, 110,111,114,115,116,141,143, 145, 153, 158, 159, 160, 161, 163, 164,176,177, 178,188,189,190, 191,192,193, 194,195,196,197, 198, 199, 203, 204, 205, 300, 301, 307,311 Religion, 2, 4, 17 Revealed preference, 17 RMS, 24, 26

323 RMSE,317 Root-mean-squared, 25 Rotterdam model, 51, 52, 228,260, 295,299,301,302,303,304 Sampling variance, 190,192,197,198, 199 Separability restrictions, 267 Simulations, 239,268, 282, 283,295, 296, 300, 301, 308, 310,313, 320 Slutsky symmetry, 11, 12, 38, 50, 64, 227, 238, 241, 245,250,251, 256, 264,282,301,305,306 Small-sample bias, 227,267 Specific substitutes, 41,49 Standard errors, 99,151,188,201,203, 204, 205, 213, 214, 215, 222, 223, 224,273,318 Stochastic approach, 187, 188, 224 Stone-Geary, 40, 53, 54 Substitutes, 8, 308 Substitution effect, 8, 12, 38,49, 306 Summary measures, 126, 169 System-wide, 10, 14, 29, 70, 122, 123, 168,247,293 Total expenditure, 10, 32, 74, 300, 302 Trading partners, 3, 5 Translog, 53, 55 Unbiased estimator, 189, 196, 197, 199, 229,231,238,305,306 Uncompensated, 35, 36, 55, 57 Unemployment, 3, 7 Unweighted average, 190, 197 Weighted average, 37, 197, 200, 201, 259, 317 Working's model, 58, 59, 94, 99, 123, 146,151, 295, 299, 301,303, 304, 310,311

International Consumption Comparisons

324

Author Index Aasness, 120 Adams, 120 Attfield, 227, 245 Baccouche, 39, 65 Balk, 188,224 Barnard, 245,268,282, 292,293 Barnett, 63, 65, 66, 188 Barten, 28,39,45,46,51, 66,120,227, 229, 233, 245, 246,249,250,251, 265, 279, 282, 292, 295,302, 319 Becker, 15, 24, 29 Bera, 227,245,292 Bettendorf, 265 Bewley, 227, 245, 292 Blanciforti, 120 Blundell, 63, 66, 249 Brown, 265 Brozdin, 126, 168 Buse, 63, 66, 227, 246 Byron, 245, 292 Cassel, 34, 66 Chavas, 63, 66 Chen, 14, 26, 29, 72, 120, 123, 126, 168, 233, 246, 265, 292,295, 317, 319 Christensen, 55, 64, 66 Chua, 249, 265 Chung, 120,121,123 Clements, 14,24,26, 27,29,40,42, 47,66,69,70,83, 112,117,118, 119,120,121,122,123,166,168, 188,189,199, 200, 201,224,233, 247,249, 265, 267, 292,293,295, 307,310,311,317,319,320

Crompton, 188,199, 200,201,224 Deaton, 22, 27, 54, 56, 57, 64, 67, 118, 119,121,225 Deschamps, 227, 246 Diewert, 64, 67, 187,188, 199, 225 Driscoll, 39, 67 Edgerton, 39, 67 Efron, 309, 319 Fiebig, 121 Finke, 121, 123, 320 Fisher, 249, 265 Fleissig, 265 Flood, 121 Frisch, 41, 43, 49, 51, 71, 105,116, 117,121,125,165,166,168,187, 225, 307 Gamaletsos, 22, 28 Goldberger, 22, 28 Goldman, 39, 67 Gorman, 39, 67 Green, 68,120, 293 Griffiths, 265 Heineke, 63,67 Hessian, 33, 46,48, 307 Houthakker, 14,27,41,49, 67,246, 247 Imhoff, 121 Izan, 122,188,189,199,200,201,224 Jarque, 245, 292 Jorgenson, 55, 64, 66 Karagiannis, 227, 246 Keller, 30, 59, 61, 62, 67, 295, 310, 311,319 Keuzenkamp, 228, 246

Chapter 3 Data Analysis: OECD Countries Kravis, 15,16,22, 28 Laisney, 39,65 Laitinen, 227, 231,233, 234, 237, 246, 265,292, 305, 319 Lau, 55, 64, 66 Lee, 249, 265 Leontief, 39, 68 Leser, 94, 122 Lewbel, 39,63, 68 Lluch, 2,17,18,19,22,27, 28, 54,68 Lopez, 120, 121 Malinvaud, 63, 68 McElroy, 256, 265 McGuirk, 39, 67 Meisner, 83,122, 226, 227,239, 246, 293 Mergos, 227, 246 Meyermans, 265 Moschini, 39, 68, 267, 293 Mountain, 65, 68 Muellbauer, 56, 57, 64, 67,121, 228, 246 Neves, 61, 68, 249, 266 Ng, 228, 247 Parks, 22, 29 Pashardes, 66, 246 Pearce, 39, 68 Pollak, 16, 22, 26, 28, 228, 247 Powell, 2, 17, 22, 27, 54, 68, 120 Rao, 121,188,225,226 Rodseth, 120 Seale, 121,123,265 Selvanathan, 1, 2,14,16,17, 24,26, 28, 30,42,47, 59, 62, 63, 65, 66, 68,69,71,72,83, 112,117,118, 119,122, 125, 166, 168,169, 187, 188, 199, 201, 205, 225,226, 227, 228,233, 247, 249,267,269, 279,

325 282, 293,295, 296,297, 308,312, 319, 320 Serletis, 265 Shafer, 65, 69 Shonkwiler, 320 Slesnik, 63, 69 Sonnenschein, 64,69 Sono, 39, 69 Stigler, 15, 24, 29 Stone, 13, 21,28,34,40, 53,54, 57, 69,70 Strotz, 39,70 Suhm, 15, 29, 83,112,123,226 Taylor, 246,247, 308, 320 Theil, 10,14,15,16,27, 29,30,47,48, 51,63,65,70,83,112,117,120, 121, 122, 123, 166, 168,188, 225, 226,227,229, 231,233,238,239, 247, 250, 256, 259, 266,282, 293, 295, 302, 305, 306, 308, 313, 319, 320 Tridimas, 249, 266 Uzawa, 39, 67 Wales, 16, 22, 26, 28, 228, 247 Williams, 2, 17, 27, 29 Working, 58,70, 94,146,168,295, 303,320 Yang, 71,123, 265, 292, 295,319 Yoshihara, 22, 30 Yuen, 123 Zarkos, 227, 246 Zonderman, 265

International Consumption Comparisons OECO Versus LDC This book presents an analysis of consumption patterns in the OECD (rich) and LDC (poor) countries using recent data (1950-1998) and econometric methodology for a number of broadly aggregated consumer goods. The income elasticity estimates for the 46 countries and 9 commodity groups are tabulated. The reliability of these elasticity estimates, and also the demand theory hypotheses, are investigated using simulation techniques.

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