80248 DIREC TIONS IN DE VELOPMENT Poverty Understanding Changes in Poverty Gabriela Inchauste, João Pedro Azevedo, B. Essama-Nssah, Sergio Olivieri, Trang Van Nguyen, Jaime Saavedra-Chanduvi, and Hernan Winkler Understanding Changes in Poverty Direc tions in De velopment Poverty Understanding Changes in Poverty Gabriela Inchauste, João Pedro Azevedo, B. Essama-Nssah, Sergio Olivieri, Trang Van Nguyen, Jaime Saavedra-Chanduvi, and Hernan Winkler © 2014 International Bank for Reconstruction and Development / The World Bank 1818 H Street NW, Washington DC 20433 Telephone: 202-473-1000; Internet: www.worldbank.org Some rights reserved 1 2 3 4 17 16 15 14 This work is a product of the staff of The World Bank with external contributions. The findings, interpreta- tions, and conclusions expressed in this work do not necessarily reflect the views of The World Bank, its Board of Executive Directors, or the governments they represent. 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Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Contents Acknowledgments ix About the Authors xi Abbreviations xv Chapter 1 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction 1 Introduction 1 Decomposing Poverty Reduction 2 Contributions of This Volume 5 Decompositions Can Inform Policy Priorities 11 Notes 11 Bibliography 12 Chapter 2 A Simple Approach to Understanding Changes in Poverty and Inequality 15 Introduction 15 The Size and Redistribution Effects 16 Accounting for the Contribution of Demographics and Income Components 25 Summary and Conclusions 32 Notes 33 Bibliography 35 Chapter 3 What Accounts for Changes in Poverty over the Past Decade? 39 Introduction 39 Growth and Poverty Reduction 40 Forces behind Poverty Reduction 44 Results 53 Summary and Conclusions 57 Annex 3A: Data Sources 58 Annex 3B: Complementary Tables 60 Notes 66 Bibliography 66 Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7   v   vi Contents Chapter 4 Counterfactual Decomposition of Changes in Poverty Outcomes 69 Introduction 69 The Composition and Structural Effects 71 Accounting for Behavior 90 Concluding Summary and Remarks 97 Notes 99 Bibliography 104 Chapter 5 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction 109 Introduction 109 Modeling Strategy 111 Decomposition Approach 116 Final Remarks 123 Annex 5A: Estimating the Residual Term in Multinomial Logit 124 Annex 5B: The Cumulative Decomposition Technique 124 Notes 128 Bibliography 128 Chapter 6 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 131 Introduction 131 Country Context 132 The Decomposition Approach 141 Decomposition Results 143 Final Remarks 150 Annex 6A: Regression and Simulation Results 152 Notes 170 Bibliography 170 Figures 1.1 Decomposition of Changes in Moderate Poverty, by Income Level, in Selected Developing Countries, 2000s 3 1.2 Cumulative Contributions to Moderate Poverty Reduction in Bangladesh, Peru, and Thailand, 2000s 10 2.1 Determinants of Consumption per Capita 27 3.1 Average Real GDP Growth in Selected Developing Countries, 2000s 44 3.2 Contribution of Growth and Redistribution to Poverty Reduction in Selected Developing Countries, by Poverty Line, 2000s 45 3.3 Change in Age-Dependency Ratio of Selected Developing Countries, 2000s 46 Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Contents vii 3.4 Change in Subsidies and Other Social Transfers in Selected Developing Countries, 2000s 49 3.5 Change in International Remittances to Selected Developing Countries, 2000s 50 3.6 Decomposition of Changes in Moderate Poverty, by Level, in Selected Developing Countries, 2000s 54 5.1 Model of Contributors to Poverty Reduction, by Stage Sequence 112 6.1 Change in Moderate Poverty Rates in Bangladesh, Peru, and Thailand, 2000s 133 6.2 GDP in Bangladesh, Peru, and Thailand, 2000–10 134 6.3 Population Growth in Bangladesh, Peru, and Thailand, 2000–10 136 6.4 Growth Incidence Curves of Labor Income in Bangladesh, Peru, and Thailand, 2000s 138 6.5 Nonlabor Income Growth, by Source, in Bangladesh, Peru, and Thailand, 2000s 140 6.6 Change in Household Consumption-to-Income Ratio in Bangladesh, Peru, and Thailand, 2000s 140 Tables 2.1 Shapley Allocations for a Three-Player Game 22 2.2 Application of Barros Methodology to Measure Contributions of Variables to Change in Poverty 30 2.3 Proposed Methodology to Decompose Change in Poverty along One Possible Path 31 3.1 Poverty Headcount Rates, by Benchmark, in Selected Developing Countries, 2000s 42 3.2 Share of Adults per Household, by Poverty Level, Selected Developing Countries, 2000s 47 3.3 Share of Working Adults per Household, by Poverty Level, in Selected Developing Countries, 2000s 48 3.4 Share of Transfers in Total Household Income, by Poverty Level, in Selected Developing Countries, 2000s 51 3.5 Change in Household Consumption-to-Income Ratio in Selected Developing Countries, 2000s 52 3.6 Contributions to Declines in Moderate Poverty, by Level, in Selected Developing Countries, 2000s 55 3A.1 Survey Sources of Data for Poverty Reduction Analysis in Selected Developing Countries, 2000 59 3B.1 Contributions to the Decline in the $1.25-a-Day (PPP) Poverty Headcount in Selected Developing Countries, 2000s 60 3B.2 Contributions to the Decline in the $2.50-a-Day (PPP) Poverty Headcount in Selected Developing Countries, 2000s 62 Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 viii Contents 3B.3 Contributions to the Decline in the $4.00–$5.00-a-Day (PPP) Poverty Headcount in Selected Developing Countries, 2000s 64 6.1 Change in Poverty Rates, by Level, in Bangladesh, Peru, and Thailand, 2000s 133 6.2 Growth and Redistribution Decomposition of Moderate Poverty Rate Changes in Bangladesh, Peru, and Thailand, 2000s 135 6.3 Population and Labor Force Characteristics in Bangladesh, Peru, and Thailand, 2000s 137 6.4 Household Consumption-to-Income Ratio, by Income Decile, in Bangladesh, Peru, and Thailand, 2000s 141 6.5 Marginal Contributions to Poverty Reduction in Bangladesh, Peru, and Thailand, 2000s 144 6.6 Contributions to Poverty Reduction by Returns to Endowments in Bangladesh, Peru, and Thailand, 2000s 145 6.7 Cumulative Contributions to Poverty Reduction in Bangladesh, Peru, and Thailand, 2000s 146 6A.1 Simulating the Changing Characteristics of Households in Bangladesh, 2000–10 152 6A.2 Simulating the Changing Characteristics of Households in Peru, 2005–09 153 6A.3 Simulating the Changing Characteristics of Households in Thailand, 2000–09 154 6A.4 Multinomial Logit on Occupational Choice of Working-Age Population, by Household Status, in Bangladesh, 2000 and 2010 155 6A.5 Multinomial Logit on Occupational Choice of Working-Age Population, by Household Status, in Peru, 2004 and 2010 157 6A.6 Multinomial Logit on Occupational Choice of Working-Age Population, by Household Status, in Thailand, 2000 and 2009 159 6A.7 Earnings Regressions for Nonfarm Working-Age Population in Bangladesh, 2000 and 2010 161 6A.8 Earnings Regressions for Nonfarm Working-Age Population in Peru, 2004 and 2010 163 6A.9 Earnings Regressions for Nonfarm Working-Age Population in Thailand, 2000 and 2009 165 6A.10 Net Revenue Regressions for Farm Households in Bangladesh, 2000 and 2010 167 6A.11 Net Revenue Regressions for Farm Households in Peru, 2004 and 2010 168 6A.12 Net Revenue Regressions for Farm Households in Thailand, 2000 and 2009 169 Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Acknowledgments This book was cofunded by the Poverty Reduction and Economic Management Network and the Multi-Donor Trust Fund for the Diagnostic Facility on Shared Growth. The team was led by Gabriela Inchauste (task team leader and senior econo- mist, Poverty Reduction and Equity Department [PRMPR]) under the guidance of Jaime Saavedra-Chanduvi (Director, PRMPR) and Christina Malmberg Calvo (Acting Director, PRMPR). Members of the team and tasks were as follows: Chapter 1 Gabriela Inchauste Jaime Saavedra-Chanduvi Chapter 2 João Pedro Azevedo B. Essama-Nssah Gabriela Inchauste Sergio Olivieri Chapter 3 João Pedro Azevedo Gabriela Inchauste Trang Van Nguyen Sergio Olivieri Hernan Winkler Chapter 4 B. Essama-Nssah Chapter 5 Gabriela Inchauste Sergio Olivieri Hernan Winkler Chapter 6 Gabriela Inchauste Sergio Olivieri Hernan Winkler The team is grateful to Mary A. Anderson (consultant, PRMPR) for provid- ing feedback on organization and content as well as for formatting and editing the manuscript. The authors acknowledge analytical inputs provided by Reena Badiani-Magnusson (economist, EASHS); Reno Dewina (consultant, EASPW); Jenny Lighthart (consultant, EAP); Minh Cong Nguyen (economist, ECSP3); and Viviane Sanfelice (consultant, LCSPP). Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7   ix   x Acknowledgments The authors thank colleagues for their insightful suggestions, in particular, Kathleen Beegle (lead economist, AFRCE); Francisco Ferreira (chief economist, AFRCE); Samuel Freije (lead economist and sector leader, LCSPR); and Emmanuel Skoufias (lead economist, LCSPP). The authors are grateful to colleagues from the World Bank for their comments at various stages in developing the concept note and the drafts and presentations of the book. The authors thank all of them, in particular Dean Joliffe (senior economist, DECPI); Ambar Narayan (lead econo- mist, PRMPR); Luis Servén (senior advisor, DECMG); Erwing Tiongson (senior economist, LCSPP); and Renos Vakis (lead economist, DECPI). The research also benefited from presentations of draft papers at the Latin American and Caribbean Economic Association meetings in Lima, 2012; at the Network of Inequality and Poverty meetings at Columbia University, 2012; at Tulane University, 2013; and at World Bank workshops between 2011 and 2013. The authors gratefully acknowledge the insightful comments and suggestions of participants at these workshops. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 About the Authors João Pedro Azevedo is a senior economist at the World Bank, where he currently works for the Europe and Central Asia region, focusing on Turkey and Central Asia and leading the region’s Statistical Team. Azevedo has focused much of his work on helping developing countries to improve their systems for evidence- based decision making. Before joining the World Bank, he served as the superin- tendent of monitoring and evaluation at the Secretary of Finance for the State of Rio de Janeiro, Brazil. He was also a research fellow at the Brazilian Institute of Applied Economic Research. He is a former chairman of the Latin American Network on Inequality and Poverty. He holds a PhD in economics from the University of Newcastle upon Tyne. B. Essama-Nssah worked for 17 years for the World Bank in Washington, DC, before he retired as a senior economist in 2011. During his tenure at the World Bank, he performed economic analyses, prepared policy research and technical papers, and conducted an annual training course on impact evaluation method- ologies for staff from the World Bank and client countries. Before joining the World Bank, he worked for 2 years as a senior research associate on the Food and Nutrition Program at Cornell University, and for 6 years as head of the Economics Department and vice dean of the Faculty of Law and Economics of the University of Yaoundé, Cameroon. He currently works as a consultant focusing on poverty and growth incidence analysis, program evaluation, and analysis of the social impact of public policy. He holds a PhD in economics from the University of Michigan in Ann Arbor. Gabriela Inchauste is a senior economist in the Poverty Reduction and Equity Department at the World Bank. Her research interests include poverty, macro- micro linkages, and the distributional impact of fiscal policy. She has published in academic volumes and peer-reviewed journals in the areas of fiscal policy, the informal sector, the impact of crises on the poor, and the role of remittances in developing countries. Before joining the World Bank, she was a senior economist at the Inter-American Development Bank and the International Monetary Fund, where she contributed to operational and analytical activities in numerous countries on topics including macroeconomic forecasting, public expenditure ­ policy, poverty and social impact analysis, fiscal and debt sustainability analysis, Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7   xi   xii About the Authors postdisaster needs assessments, and subsidy reform. Inchauste holds a PhD in economics from the University of Texas at Austin. Trang Van Nguyen is a senior economist in the Poverty Reduction and Equity Department at the World Bank. Previously, she worked in the East Asia and Pacific, Africa, and Europe and Central Asia Regions of the World Bank, in the areas of labor, poverty and inequality, education, health, social protection, and gender and development. Nguyen is one of the lead authors of the World Bank’s regional flagship report, East Asia Pacific at Work: Employment, Enterprise, and Well-Being. She is also coauthor of two other World Bank flagship publications: Toward Gender Equality in East Asia and the Pacific: A Companion to the World Development Report (2012) on gender equality and development and International Migration and Development in the East Asia and Pacific Region. She holds a PhD in economics from the Massachusetts Institute of Technology. Sergio Olivieri is an economist in the Poverty Reduction and Equity Department at the World Bank. His main research areas are ex ante analysis of the distributional impact of macroeconomic shocks, understanding how economic growth affects poverty, poverty measurement, and multidimensional poverty. He has published articles in peer-reviewed journals on labor informality, polarization, and multidi- mensional poverty and has contributed to edited volumes on inequality, poverty, and social cohesion. Previously, he was an assistant professor of labor economics in the Department of Economics of University of La Plata, Argentina, and as a researcher in the university’s Center of Distributional, Labor and Social Studies. Jaime Saavedra-Chanduvi is Minister of Education in Peru. He was previously the director of the Poverty Reduction and Equity Department at the World Bank. His major areas of interest include education policy, poverty reduction, inequality, labor markets, and social policies. He was executive director and prin- cipal researcher at Grupo de Análisis para el Desarollo, a nonpartisan think tank based in Lima, and a principal advisor to the Ministry of Labor and Social Promotion in Peru. He has been a consultant and researcher for the World Bank, the Economic Commission for Latin America and the Caribbean, the Inter- American Development Bank, and the International Labour Organization. He has been president of the executive committee of the Network on Inequity and Poverty of the Inter-American Development Bank–World Bank–Latin American and Caribbean Economic Association as well as a board member of Latin American and Caribbean Economic Association, the Nutrition Research Institute, and the National Council of Labor in Peru. He has held teaching positions at Pontificia Universidad Católica del Peru and Universidad del Pacífico in Peru, and has been a visiting researcher at the University of Toronto. Saavedra-Chanduvi holds a PhD in economics from Columbia University. Hernan Winkler is an economist in the Office of the Chief Economist for Europe and Central Asia at the World Bank. He specializes in applied microeconomics, Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 About the Authors xiii with a particular focus on labor market issues and the sources and consequences of inequality and poverty. He was part of the core team of the World Bank’s regional flagship report, Diversified Development: Making the Most of Natural Resources in Eurasia (2014), and also on the core team of the next regional flag- ship report on the aging populations of Europe and Central Asia. Before joining the World Bank, Winkler was a researcher at the Center of Distributional, Labor and Social Studies at the University of La Plata, Argentina. He holds a PhD in economics from the University of California at Los Angeles. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Abbreviations ATET average treatment effect on the treated ENAHO Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information) FAO Food and Agriculture Organization of the United Nations GDP gross domestic product GIC growth incidence curve HIES Household Income and Expenditure Survey (Bangladesh Bureau of Statistics) PPP purchasing power parity RIGA Rural Income-Generating Activities (datasets compiled jointly by the Food and Agriculture Organization of the United Nations and the World Bank) SEDLAC Socio-Economic Database for Latin America and the Caribbean SES Household Socio-Economic Survey (Thailand National Statistical Office) Currency is in U.S. dollars unless specified otherwise. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7   xv   Chapter 1 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction Introduction A 2013 cover of The Economist virtually declared victory: “Towards the End of Poverty” (Economist 2013). Given international benchmarks, a battle has indeed been won—to cut in half the share of the world’s population living in extreme poverty. In fact, the achievement of this 2015 Millennium Development Goal was met with time to spare.1 By 2013, the percentage of developing-country populations living under the direst conditions—measured by the extreme pov- erty line, typically set at $1.25 a day2—decreased from 43 percent in 1990 (1.9 billion people) to 21 percent by 2010 (1.2 billion people). Clearly there is still a long way to go, with 1.2 billion people still struggling to get enough to eat. But what can we learn from the recent success? For example, how much do we truly understand about the specific drivers of such momentous changes in poverty—be they reductions or increases, in low- income or middle-income countries, at extreme or moderate poverty levels? To be sure, 21st-century poverty reduction is largely a growth story, and one that is indisputable by either national or international poverty lines.3 Even knowing that growth correlates strongly with poverty reduction (Ravallion and Chen 2007), economists and policy makers want to “drill down” into the data to answer many more questions: • What role have demographic changes and lower dependency ratios had on the reduction in poverty? • What was the role of higher employment and higher real earnings? Did higher labor productivity lead to higher real earnings? Or did earnings growth result either from improved human capital (in education, training, or experience) or from changes in the returns to those characteristics? Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7   1   2 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction • To what extent did changes in the sectoral composition of employment lead to higher productivity and higher earnings? For instance, how did movements from agriculture to the services or industry sectors contribute to poverty reduction? • What was the role of transfers from the government, including the new gen- eration of social safety net programs that have begun to proliferate? • What was the role of private transfers in the form of international remittances? International bodies and financial institutions are setting ambitious new pov- erty reduction targets for 2030. Similarly, many developing countries have clear development goals and national plans to reduce poverty and promote inclusive growth. The methods and results presented in this book are envisioned to con- tribute to the evidence base that governments can use in setting the policy agenda. Decomposing Poverty Reduction The links between economic growth, income redistribution, and poverty reduc- tion have long interested economists. Growth, at the end of the day, is a means to an end. Bolstered by decades of previous work, recent methods can be used to decompose the contributions to poverty reduction. Decomposition methods originated in the seminal papers of Oaxaca (1973) and Blinder (1973), which aimed to decompose changes in wages over time. Since then, the increase in wage inequality observed in the United States and several other countries since the late 1970s has led to the development of new methods, including those introduced by Juhn, Murphy, and Pierce (1993) and Bourguignon, Ferreira, and Lustig (2005). Although these methods were focused on better understanding distributional changes, they can also be used to better understand changes in poverty. In particular, we focus on two questions: What was the main contributor to poverty reduction? What was behind the poverty reduction due to labor income growth in particular? The first question can be addressed with a simple accounting approach that quantifies the contributions to poverty ­ reduction on account of changes in demographics, changes in employment and labor income, and changes in nonlabor income (including remittances, public transfers, and other private transfers). The second question requires a more complex approach to further distinguish between distributional changes because of changes in endowments or returns to those endowments; changes in occupational choice; and changes in the geographical, age, and gender struc- ture of the population, along with the nonlabor dimensions mentioned above. Such an approach can, for instance, help distinguish whether improvements in human capital (via a more educated work force) have been accompanied by increases in the returns to education (and potential improvements in productivity). Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction 3 What Was the Main Contributor to Poverty Reduction? By covering and expanding upon existing decomposition methods, chapters 2 and 3 describe and apply the first of these methods to identify the forces that account for substantial declines4 in moderate poverty over the past decade5 in a selected set of 21 developing nations. The main results are as follows: • Labor income growth (comprising growth of employment and earnings) clearly contributed the most to poverty reduction in the studied countries (­figure 1.1). Being the main asset of the poor, increased labor income accounts for more than half of the poverty reduction in 12 of the 21 countries with substantial poverty reduction. In another 6 countries, it accounted for more ­ than 40 ­ percent of the reduction in poverty. Moreover, in most cases, it was the growth in income per worker that contributed the most to poverty reduc- tion, rather than an increase in employment (measured by the share of work- ing adults). • Demographic changes (primarily increases in the share of adults per household) led to declining age-dependency rates, which in turn can lead to increases in per capita income and consumption. This effect occurred in most of the Figure 1.1  Decomposition of Changes in Moderate Poverty, by Income Level, in Selected Developing Countries, 2000s 140 Contributions to poverty reduction (%) 120 100 80 60 40 20 0 –20 –40 009 0 –10 8 –10 0 11 05 09 –10 9 –09 0 003 10 9 09 09 0 9 0 201 0–0 2–1 1–0 4–1 1–0 4–1 6–0 7–1 07– –20 02– 03– 01– 00– 9–2 000 000 001 000 6–2 99– 200 200 , 200 , 200 200 , 200 200 , 200 a, 20 998 a, 20 r, 20 il, 20 e, 20 199 sh, 2 na, 2 va, 2 d, 2 9 y, 19 l, 19 , bia, , nes, Rica ania nam ama na, 1 Peru ia ado goli ank ilan Braz Chil , lade bod uras do enti m a gua ippi Rom Nep Pan ta Viet Ecu Sri L Mon Gha Tha Mol Colo Cam Arg g d Cos Para Phil Ban Hon ≤ $1.25 a day $4.00 a day $5.00 a day Nonlabor income Employment + earnings Share of working-age family members Consumption-to-income ratio Sources: Data from SEDLAC, various years; FAO n.d.; and national household surveys. Note: “Nonlabor income” refers to public and private transfers (including remittances), pensions, capital, and other nonlabor income. “Employment + earnings” refers to the combined change in employment and earnings per working-age adult (aged 15–64 years). The “consumption-to-income ratio” represents the ratio of measured consumption to measured income. Changes in this ratio capture changes in savings patterns of households as well as measurement errors in household consumption and income. Consumption-based measures of poverty are used in Bangladesh, Ghana, Moldova, Nepal, Peru, Romania, and Thailand. The remaining countries use income-based measures of poverty. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 4 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction countries considered here over the past decade and was especially important in Costa Rica, Paraguay, and the Philippines. However, in most of the countries studied, the magnitude of this effect was small relative to the effect of labor income growth. • Nonlabor income (such as government spending for subsidies or public ­transfers)6 grew, as a share of gross domestic product (GDP), more than sixfold in Ghana and by more than 60 percent in Bangladesh, Moldova, Mongolia, and Romania. Remittances also grew strongly, especially in Honduras (to an aver- age of 17.8 percent of GDP in 2009) and Nepal (to an average of 12 percent of GDP in 2003). Although transfers contributed to poverty reduction, they played a relatively smaller role in explaining declines in moderate poverty for most countries in the sample. Three notable exceptions were Moldova, Mongolia, and Romania. Moldova’s poor benefited mostly from an increase in international remittances, whereas in Romania, the increase was related to both transfers and capital income. However, public transfers clearly play an increasingly important role in reducing extreme poverty. In other words, increases in transfers to the extremely poor were critical in reducing the sever- ity of poverty. Why Did Labor Income Grow? Although the results clearly point to growth in income per worker as the main contributor to poverty reduction in most of the countries studied, the method is unable to discern why labor income grew. In many developing countries, poverty reduction has coincided with the labor force’s increasing education and health— as well as, in some cases, more equitable distribution of land or other productive assets. Did earnings increase because of changes in the endowments of the popu- lation (such as higher educational levels or increases in other productive assets)? Or did marketplace premiums (that is, the returns to endowments) rise for ­ workers with those endowments? The rest of the book explores alternative methods to better understand the ­ hapters roots of these changes. After a review of the literature, the book’s final two c describe and implement a second method based on Bourguignon, Ferreira, and Lustig (2005) and impose an underlying labor model and greater structure to understand why earnings increased. This decomposition approach is applied to Bangladesh, Peru, and Thailand. The results show that changes in individual char- acteristics (such as education, work experience, and region of residence) were influential, but that, overall, labor income grew mainly because of higher returns to endowments—signaling an increase in the marginal value of work as a result of increases in productivity or in the relative price of labor. In Bangladesh and Peru, this increase in the marginal value of work was not driven by higher returns to education, but rather by higher returns to labor with low levels of education. In the case of Bangladesh, the increase in the marginal value of work seems to have been associated with higher food prices in the farm sector, while in Peru it was associated with higher premiums in the service sector, Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction 5 potentially resulting from improving productivity. Thailand, in contrast, demon- strated that greater specialization and higher returns to education can boost the marginal value of work, potentially through productivity increases. The past decade affords us a fantastic opportunity to study the most signifi- cant factors that worked in favor of the poor. The decomposition methods reviewed in this volume provide a window to quantify the contributions to changes in poverty at a finer level of detail than ever before. The results point to the centrality of jobs in reducing poverty—particularly through increases in labor productivity—that will lead to sustained income growth for the poor. It is the authors’ hope that the decompositions developed in this volume can expand the evidence base to establish the necessary conditions for future poverty reduction and therefore guide policy to enable these conditions to take hold. Contributions of This Volume The decomposition methods developed in this volume make some distinct ­ contributions, further described in the chapter synopses below and summarized as follows: • Focus on consumption as a measure of welfare. Up until now, decomposition methods often focused on income-based measures of welfare. These methods are adapted in this volume to focus on consumption, given that most develop- ing countries use a consumption aggregate to measure poverty. • Address path dependence by calculating the Shapley-Shorrocks estimate of each component. Like most micro-decomposition approaches in the literature, the methods proposed in this volume suffer from path dependence. In other words, the order in which the cumulative effects are calculated matters. The best-known remedy for path dependence is to calculate the decomposition across all possible paths and then take the average between them. Following the algorithm proposed by Azevedo, Nguyen, and Sanfelice (2012a, 2012b), we calculate the Shapley-Shorrocks (Shapley 1953; Shorrocks 1999) estimate of each component. • Apply to a wide set of countries experiencing poverty reduction around the world. This volume presents the most comprehensive application of these techniques across countries that have experienced substantial declines in poverty over the past decade. Previous efforts typically included only a limited number of countries. The ease of use of this technique now allows for replication in a ­ variety of contexts and can serve to decompose changes in poverty, inequality, or any other distributional change. • Propose a structural model that allows for household and individual decision ­making. Previous approaches typically modeled only individual decision making. The proposed approach models farm income at the household level, ­ Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 6 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction including earnings of farm household members who have secondary occupa- tions, thus recognizing not only that farm households typically make labor decisions as a unit but also that these households can be highly diversified. The chapter summaries below offer only snapshots of the issues and tech- niques involved in understanding changes in poverty, allowing the full chapters to speak for themselves. Chapter 2: A Simple Approach to Understanding Changes in Poverty and Inequality Chapter 2 provides a unifying framework and a theoretical foundation for the decomposition methods commonly used in the literature. The chapter begins with the simplest decompositions—in which poverty changes can be decom- posed into the growth effect and the redistribution effect (also known as the size and redistribution effects)—often referred to as the Datt and Ravallion (1992) decomposition. The chapter discusses the underpinnings of this decomposition and notes that in its original form, the Datt-Ravallion method includes a residual term. Moreover, the value of any effect (size or redistribution) depends on the chosen period of reference. To solve this problem, the standard practice is to compute the decomposition in both ways and then take the average. As it turns out, this average Datt-Ravallion decomposition is precisely the procedure proposed by Shorrocks (1999) based on the Shapley (1953) value. ­ Indeed, the Shapely allocation rule, based in game theory, provides a framework that can be extended to more complex decompositions, including those that decompose changes in poverty on account of changes within and between groups. Although these decompositions are interesting, analysts often want to go beyond these summary statistics. We describe an approach that quantifies the contributions to poverty reduction on account of changes in demographics, employment, earnings, and public and private transfers based on a simple accounting identity. The method is adapted from Barros et al. (2006) and has the distinct advantage of being easy to apply and easy to understand. In contrast with the methods that use aggregate measures, such as “growth” and “redistribution” effects, this approach generates entire counterfactual distributions, allowing us to quantify the contributions to poverty reduction stemming from changes in demographics, employment, earnings, and public and private transfers by chang- ing each one of these elements at a time.7 To avoid path dependence, the pro- posed method calculates the Shapley-Shorrocks estimates of each component to find the contribution of each component. Chapter 3: What Accounts for Changes in Poverty over the Past Decade? Chapter 3 implements both the Datt-Ravallion decomposition and the method proposed in chapter 2 for a sample of 21 countries where moderate poverty had declined substantially between 2000 and 2010. The chapter quantifies, by generating entire counterfactual distributions, contributions to poverty reduction ­ from changes in labor income, nonlabor income, and demographic characteristics. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction 7 Because most countries measure welfare through household expenditures or consumption (as opposed to income), this chapter modifies the Barros et al. (2006) methodology in three important respects: It decomposes consump- tion-based measures of poverty, computes a cumulative counterfactual ­ distribution by adding one variable at a time, and it calculates the Shapley- Shorrocks ­estimates of each component. The decompositions across the 21 countries resulted in the following general findings: • Labor income growth, by far, was the main driver of poverty reduction. Moreover, an increase in workers’ earnings was relatively more important in reducing poverty than the increases in the share of employed adults per household. • Demographic changes—increased percentages of working-age adults per house- hold (and thus declining dependency ratios)—also mattered in poverty reduc- tion, particularly in seven of the countries. In general, however, the magnitude of this effect is small relative to labor income growth. • Nonlabor income increases, such as public and private transfers, were important, but, for most countries in the sample, played the smallest role in explaining declines in moderate poverty. However, they were far more important in reducing extreme poverty. From decomposition of the extreme-poverty head- count, poverty gap, and poverty severity, transfers and pensions contributed a relatively higher share to poverty reduction than labor income growth.8 These results point to the crucial role that social protection systems play in reaching the ultrapoor. Although these methods are useful to distinguish the main contributors to poverty reduction, they cannot explain why workers’ earnings increased. To resolve that issue, the subsequent chapters consider alternative decomposition techniques that impose an underlying labor model and greater structure. Chapter 4: Counterfactual Decomposition of Changes in Poverty Outcomes Chapter 4 presents a literature review of commonly used micro-decomposition methods to identify key drivers of changes in poverty. The chapter begins with the standard Oaxaca-Blinder decomposition, which aimed to understand changes in between-group differences in average wages, and reviews how this technique has since been extended to the analysis of variation in other distributional statis- poverty, and inequality measures. tics, such as quantiles, ­ The chapter first reviews methods to identify and estimate the composition (or endowment) effect and structural (or price) effect associated with variation in a general distributional statistic. The methods underlying this decomposition are considered ­statistical to the extent that they do not involve causal models of the observed outcomes. In this context, nonparametric estimation has the advan- tage of not imposing a functional form on the relationship between the outcome and its determinants. Because these statistical methods cannot shed light on the Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 8 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction causal mechanism driving the outcome, their ability to inform policymaking is somewhat limited. Therefore, the review also considers methods that account for behavioral responses to changes in the socioeconomic environment. These methods rely on the specification and estimation of a microeconometric model based on some theory of individual (or household) behavior and social interaction. These methods go a step further toward identifying factors associated with structural ­ elements underpinning the observed changes in poverty outcomes. These struc- tural methods—combining economics and statistics—can be predictive. In this context, chapter 5 proposes one such structural approach. Finally, the chapter discusses the analogy between these decomposition meth- ods and treatment effect analysis. The chapter also notes that these decomposi- tion methods can be used in the study of the distributional and poverty impacts of an assigned intervention. Chapter 5: Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction The literature review presented in chapter 4 concludes that structural decompo- sition methods enable an analyst to study the distributional and poverty impacts of an assigned intervention by taking into account how agents respond to changes in their socioeconomic environments. This chapter presents a structure for mod- eling distributional changes over time that allows us to account for the contribu- tions to poverty reduction stemming from both changes in endowments and changes in the returns to those endowments. The proposed approach9 estimates an educational choice model, a sectoral choice model, an activity choice model, and individual and household earnings equations. Once all of these models are estimated for individuals and households in each time period, the estimated coefficients from one year can be replaced with the estimates from another year to simulate the impact of changes in each element at a time. A series of counterfactual income distributions can then be constructed from which a counterfactual poverty measure can be estimated. This new poverty measure is then compared with the observed outcome while hold- ing everything else constant. By changing one e ­ lement at a time, these decompo- sitions allow us to account for the observed changes in poverty. In addition, we present a method to estimate these counterfactuals cumula- tively, thereby accounting for the impact of concurrent changes. Although the method presented here draws heavily from Bourguignon and Ferreira (2005) and Bourguignon, Ferreira, and Leite (2008), it also offers some innovations: • It assumes that welfare is measured using a consumption aggregate and accounts for the contribution of changes in the consumption-to-income ratio. • It models farm household income at the household level and models the earn- ings of individuals in those farm households who have a secondary occupation, thus recognizing not only that farm households typically make labor decisions as a unit but also that these households can be highly diversified. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction 9 • It ensures that changes in the composition of activities, sectors, and education of the work force are consistent with the counterfactual choices. Chapter 6: Understanding Poverty Reduction in Bangladesh, Peru, and Thailand The method proposed in chapter 5 is applied in the volume’s concluding chapter to understand the drastic reduction in poverty in three countries between 2000 and 2010: Bangladesh, Peru, and Thailand. While diverse in their levels of income and urbanization, these three economies each reduced moderate national ­ poverty headcount rates by more than 14 percentage points. In each case, GDP growth remained high, well exceeding 4 percent between 2002 and 2008. Peru and Thailand had sharp deceleration in 2009 because of the global financial crisis but rebounded quickly in 2010. Bangladesh got through the crisis virtually unscathed given the country’s weaker integration into global finan- cial markets. In addition to healthy economic growth, the countries had further similarities in potential poverty-reduction factors: • Increases in employment, public social transfers, and remittances • Changes in the populations’ occupational structure, with workers moving away from farm and daily work and toward more salaried employment and to jobs of relatively high productivity • Workers’ sharp shifts away from agriculture and toward the higher-­productivity manufacturing and service sectors • Improvements in the work force’s educational composition for several dimen- sions over the past 10 years, a result of each country’s higher investment in education in previous decades. Once the decompositions were performed, the main result, consistent with the findings mentioned above, was that the largest contributions to poverty reduction in all three countries were labor market–related factors, including changes in the sectoral, occupational, and educational structure of the labor force, as well as changes in the returns to individual and household characteris- tics. These changes cumulatively reduced moderate poverty levels in Bangladesh by 80 percent, in Peru by 69 percent, and in Thailand by 62 percent (figure 1.2). Furthermore, within these results, we can finally explain why labor income increased. Through the micro-decomposition methods employed here, it was ascertained that labor income grew mainly because of higher returns to human capital endowments. In other words, the marginal value of work increased, and that’s what made such a difference. This could signal increases in productivity, a higher relative price of labor, or both. In Bangladesh and Peru, this increase in the marginal value of work was not driven by higher returns to education, but rather by higher returns to workers with low levels of education. To the extent that these higher returns to low- educated workers were accompanied by changes in the sectoral and occupational structure of the work force, these premiums may be reflecting improvements in Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 10 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction Figure 1.2 Cumulative Contributions to Moderate Poverty Reduction in Bangladesh, Peru, and Thailand, 2000s 140 120 Contribution to moderate poverty reduction (%) 100 80 60 40 20 0 –20 –40 Bangladesh Peru Thailand 2000–10 2004–10 2000–09 Nonlabor income Sector Demographics Returns: farm Occupation Residuals Returns: nonfarm Education Others Sources: Calculations derived from household survey data from Bangladesh (HIES 2000–10), Peru (ENAHO 2004–10), and Thailand (SES 2000–09). Note: “Moderate poverty” refers to each country’s moderate poverty line. “Sector” refers to the sectoral composition of the workforce, including agriculture, industry, services. “Occupation” refers to the activity type of the workforce including daily workers, wage workers, self-employed, and unemployed. “Demographics” refers to changes in the age, gender, and regional composition of the population. “Others” includes changes in the consumption-to-income ratio and unexplained portion. HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics); ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information); SES = Household Socio-Economic Survey (Thailand National Statistical Office). the productivity of these unskilled workers. However, these higher returns might also simply reflect higher food prices, which have led to relative increases in the earnings of agricultural workers. In contrast, in Thailand, poverty decreased because of both improvements in the education of the work force and higher returns to education. In this case, the marginal value of work increased through higher labor productivity increases. Beyond increases in the returns to labor, all three countries showed reductions in poverty as a result of • A falling earnings penalty for living outside of the capital city • A shift in sectoral choices away from agriculture and toward services—reducing poverty only slightly in Bangladesh and Peru and a bit more in Thailand Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction 11 • A shift in occupational choices among nonfarm workers away from daily-wage and self-employed work and toward salaried jobs, all of which contributed to poverty reduction, particularly in Peru. Beyond the effects of labor income growth, the decomposition method showed that a greater share of working-age adults helped to reduce poverty, particularly in Bangladesh. Finally, although most poverty reduction was the result of labor income growth, it is important to recognize that nonlabor income in the form of transfers did play a role: International remittances accounted for 11 and 17 percent of poverty reduction in Bangladesh and Thailand, respectively. Public transfers accounted for about 9 percent of Peru’s poverty reduction, while Thailand’s generous new pension scheme, combined with various private and other trans- fers, accounted for more than 40 percent of its poverty reduction. Decompositions Can Inform Policy Priorities International bodies and financial institutions are setting ambitious new poverty reduction targets for 2030. Similarly, many developing countries have clear development goals and national plans to reduce poverty and promote inclusive growth. Some are facing clear challenges to improve well-being through employ- ment; some are facing the question of how to best design the tax-transfer system; others are undergoing tremendous demographic changes. A first step in putting together a policy agenda is to frame the issues with respect to achieving these poverty reduction goals. As such, understanding poverty trends and the factors underlying these trends is critical. In particular, a ­ better understanding of the roles of growth vis-à-vis distributional changes and ­ the role of labor versus nonlabor income in explaining poverty reduction in the past 5–10 years can usefully shed light on what has worked to date and where there is room for improvement. The methods presented in this book can be applied to analyze changes in poverty, inequality, or any other distributional change over time. Both the methods and the emerging results presented here are envisioned to contribute to the evidence base that governments can use in setting the policy agenda. Notes 1. For more information about the United Nations’ Millennium Development Goals (MDGs), see the website http://www.un.org/millenniumgoals/. 2. The lower-bound poverty line, being initially set at a 1990 baseline rate of $1 a day (at 1993 purchasing power), was increased after economists gathered a new set of global poverty measures that spanned 116 countries (Ravallion, Chen, and Sangraula 2008). The new international poverty line (of $1.25 a day in 2005 prices) was calculated from “the average of the 15 poorest countries’ own poverty lines in 2005 ­ prices, adjusted for differences in purchasing power” (Economist 2013). Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 12 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction 3. For more details about global changes in poverty and how poverty is measured, see Chen and Ravallion 2008 and World Bank 2012. 4. A “substantial” decline in poverty is defined as an average reduction of 1 percentage point per year over the data period. 5. “Moderate” poverty is a country-specific poverty line referring to the international poverty line that is closest to the country’s moderate poverty rate (in some cases $1.25 a day, in others $2.50, and in still others $4–$5 per day. 6. Note that this exercise does not take into account the payoff of increased access to many public services that are not part of household income, nor does it account for the poverty impact of improvements in the quality of public services. 7. Counterfactual distributions are obtained by changing one determining factor at a time while holding all the other factors fixed (a straight application of ceteris paribus variation). 8. The poverty headcount, poverty gap, and severity of poverty refer to the Foster, Greer, and Thorbecke (1984) measures. The poverty headcount index is the proportion of the population that is counted as poor because their consumption or income is below a certain poverty line. The poverty gap adds up the extent to which individuals on average fall below the poverty line and expresses it as a percentage of the poverty line. The severity of poverty is calculated as the poverty gap index squared, which implic- itly puts more weight on observations that fall well below the poverty line. 9. Our model takes into account the Roy (1951) model of choice and consequences (which stems from the optimization principle and applies to discrete choice prob- lems), using it to model individuals’ educational levels, sectors, and activity choices. We then adapt the Bourguignon, Ferreira, and Leite (2008) methodology to distin- guish between distributional changes on account of (a) changes in endowments and the returns to those endowments; (b) changes in occupational and sectoral choice; and (c) changes in geographical, age, and gender structure of the population, along with the nonlabor dimensions. Bibliography Azevedo, Joao Pedro, Minh Cong Nguyen, and Viviane Sanfelice. 2012a. “Adecomp: Stata Module to Estimate Shapley Decomposition by Components of a Welfare Measure.” Statistical Software Components S457562, Boston College, Department of Economics. ———. 2012b. “Shapley Decomposition by Components of a Welfare Aggregate.” Policy Research Working Paper 6414, World Bank, Washington, DC. Barros, Ricardo Paes de, Mirela de Carvalho, Samuel Franco, and Rosane Mendonça. 2006. “Uma Análise das Principais Causas da Queda Recente na Desigualdade de Renda Brasileira.” Revista Econômica 8 (1): 117–47. Blinder, Alan S. 1973. “Wage Discrimination: Reduced Form and Structural Estimates.” Journal of Human Resources 8 (4): 436–55. Bourguignon, François, and Francisco H. G. Ferreira. 2005. “Decomposing Changes in the Distribution of Household Incomes: Methodological Aspects.” In The Microeconomics of Income Distribution Dynamics in East Asia and Latin America, edited by François Bourguignon, Francisco Ferreira, and Nora Lustig, 17–46. Washington, DC: World Bank. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Opportunity Knocks: Deepening Our Understanding of Poverty Reduction 13 Bourguignon, François, Francisco H. G. Ferreira, and Phillippe G. Leite. 2008. “Beyond Oaxaca-Blinder: Accounting for Differences in Household Income Distributions.” Journal of Economic Inequality 6 (2): 117–48. Bourguignon, François, Francisco H. G. Ferreira, and Nora Lustig, eds. 2005. The Microeconomics of Income Distribution Dynamics in East Asia and Latin America. Washington, DC: World Bank. Chen, Shaohua, and Martin Ravallion. 2008. “The Developing World Is Poorer Than We Thought, But No Less Successful in the Fight against Poverty.” Policy Research Working Paper 4703, World Bank, Washington, DC. Datt, Gaurav, and Martin Ravallion. 1992. “Growth and Redistribution Components of Changes in Poverty Measures: A Decomposition with Applications to Brazil and India in the 1980s.” Journal of Development Economics 38 (2): 275–96. Economist. 2013. “Not Always with Us.” June 1–7. FAO (Food and Agriculture Organization of the United Nations). n.d. Rural Income Generating Activities (RIGA). Database, FAO, Rome; World Bank and American University, Washington, DC. http://www.fao.org/economic/riga/riga-database/en/. Ferreira, Francisco. 2010. “Distributions in Motion: Economic Growth, Inequality and Poverty Dynamics.” Policy Research Working Paper 5424, World Bank, Washington, DC. Foster, James, Joel Greer, and Erik Thorbecke. 1984. “A Class of Decomposable Poverty Measures.” Econometrica 52 (3): 761–65. Juhn, Chinhui, Kevin M. Murphy, and Brooks Pierce. 1993. “Wage Inequality and the Rise of Returns to Skill.” Journal of Political Economy 101 (3): 410–42. Oaxaca, Ronald L. 1973. “Male-Female Wage Differentials in Urban Labor Markets.” International Economic Review 14 (3): 693–709. Ravallion, Martin, and Shaohua Chen. 2007. “China’s (Uneven) Progress against Poverty.” Journal of Development Economics 82 (1): 1–42. Ravallion, Martin, Shaohua Chen, and Prem Sangraula. 2008. “A Dollar a Day Revisited.” Policy Research Working Paper 4620, World Bank, Washington, DC. Roy, Arthur D. 1951. “Some Thoughts on the Distribution of Earnings.” Oxford Economic Papers 3 (2): 135–46. SEDLAC (Socio-Economic Database for Latin America and the Caribbean). Various years. Statistical database produced by CEDLAS (Center for Distributional, Labor and Social Studies) of the Universidad Nacional de la Plata, Buenos Aires; and World Bank, Washington, DC. http://sedlac.econo.unlp.edu.ar/eng/. Shapley, Lloyd S. 1953. “A Value for n-Person Games.” In Contributions to the Theory of Games, Vol. 2, edited by H. W. Kuhn and A. W. Tucker, 307–17. Princeton, NJ: Princeton University Press. Shorrocks, Anthony F. 1999. “Decomposition Procedures for Distributional Analysis: A Unified Framework Based on Shapley Value.” Paper for the University of Essex and Institute for Fiscal Studies. World Bank. 2012. “An Update to the World Bank’s Estimates of Consumption Poverty in the Developing World.” Briefing note prepared by Shaohua Chen and Martin Ravallion, Development Research Group, World Bank, Washington, DC. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 CHAPTER 2 A Simple Approach to Understanding Changes in Poverty and Inequality Introduction The link between economic growth and poverty reduction has long been of interest to economists. The literature has proposed counterfactual decomposi- tion methods to identify the relative contributions of different factors to varia- tions in overall poverty.1 These decompositions include the Datt and Ravallion (1992) method, which decomposes observed changes in poverty into a distri- bution-neutral growth effect and a redistribution effect. Kolenikov and Shorrocks (2005) decompose changes in poverty into growth, distribution, and price components, while Ravallion and Huppi (1991) offer a way of decomposing changes in poverty over time into intrasectoral effects and ­population shifts. However, the usefulness of these decomposition methods is severely limited in policy making because they explain changes in poverty on the basis ­ of changes only in summary statistics that are hard to target with policy instruments. For instance, it is hard to see what role demographics played in reducing poverty—or what the roles of employment and labor income were—relative to the roles of remittances and public transfers. Unfortunately, methods such as Datt-Ravallion (1992) are unable to make these explicit links because growth, inequality, and poverty measures are actually just three different aggregations of information about individual income dynamics. Moreover, they are jointly determined, such that cross-country estimates are unlikely to shed much light on the fundamental factors underlying distribu- tional change (Ferreira 2012). In addition to methods that focus on aggregate summary statistics, this chapter reviews a simple method to generate entire counterfactual distributions, allowing us to quantify the contributions to poverty reduction stemming from changes in demographics, changes in the share of employed adults, changes in labor income, and changes in nonlabor income, such as public transfers and remittances. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7   15   16 A Simple Approach to Understanding Changes in Poverty and Inequality Although it follows the approach first discussed by Barros et al. (2006), the pro- posed method is new in three important respects: • It extends the approach to cases where poverty is measured by consumption, as opposed to income. • It calculates the cumulative effect of all of these changes and ensures that the sum of the components is equal to the total change in poverty. • To avoid path dependence, every possible path is considered, and the average contribution of each factor is computed over all possible paths, leading to what is known as Shapley-Shorrocks estimates of the contribution of each compo- nent (Shapley 1953; Shorrocks [1999] 2013). It is important to explain at the outset that these decompositions are essen- tially accounting exercises and do not allow for the identification of causal effects. For example, increases in cash transfers or noncontributory pensions may in some circumstances deter participation in the labor market, thus affecting labor incomes. Similarly, increases in labor income can make some households ineligible for transfer programs. For those reasons, we caution against interpreting changes in labor income (or, for that matter, changes in pensions or transfers) as “causing” changes in the poverty rate. Still, the decompositions are useful in identifying empirical regularities and, as accounting tools, can help focus attention on factors that are quantitatively more important in describing distributional changes. The rest of the chapter is organized as follows: The next section provides background on decomposition methods used to account for variation in poverty outcomes in terms of changes in the mean and in relative inequality of the under- lying outcome distribution. In particular, we review the Datt and Ravallion (1992) and Shapley (1953) decomposition methods. This is followed by a decomposition methodology that aims to quantify the contributions of labor income, transfers, and demographic effects to the observed changes in poverty, based on the Shapley approach. The last section reviews the contributions and limitations of the decomposition methods discussed in this chapter. The Size and Redistribution Effects This section first frames the decomposition problem by providing a unifying framework and a theoretical foundation for the decomposition methods com- monly used in the literature. In particular, we note that changes in the distribu- tion can be characterized in terms of the level of growth and the degree of relative inequality. The most common method stemming from this approach is the Datt and Ravallion (1992) decomposition, to which we turn first. However, as described in detail below, this method faces at least two important method- ological issues: whether to use the initial or end period as the reference period, and how to interpret the residual change in poverty that is not accounted for. Indeed, all decomposition methods seek to identify the contributions of fac- tors influencing the distribution, as measured by a particular statistic, such as Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 A Simple Approach to Understanding Changes in Poverty and Inequality 17 poverty or inequality. Ideally, these contributions should exhaust the observed distributional change, and it should not matter whether one chooses the initial or end period as a reference. However, this is not always the case, because a residual may be left unaccounted for, and the decomposition results could suffer from path dependence. Therefore, in the second part of this section, we present the Shapley (1953) method, which provides a unified framework to assess the relative importance of determining factors (Shorrocks [1999] 2013). The final part of this section considers application of the Shapley method to the decom- position of change in poverty over time. Framing the Decomposition Given that poverty measures are computed on the basis of a distribution of living standards that is fully characterized by its location parameter m (the mean of the distribution) and the associated Lorenz curve L, it is reasonable to express a poverty measure P as a function of these elements along with the poverty line, z, as follows: Pt = P(mt, Lt, Zt). The overall variation in poverty, as measured by Pt, from a base period (t = 0) to an end period (t = 1) can be written as follows:2 1 dP P ∆O = P ( µ1 , L1 , z1 ) − P ( µ0 , L0 , z0 ) = ∫ dt dt. (2.1) 0 Equivalently, we have 1 1 1 ∂P ∂ µ ∂P ∂L ∂P ∂ z P ∆ = O ∫0 ∂ µ ∂t dt + ∫ 0 ∂L ∂t dt + ∫ ∂z ∂t dt. (2.2) 0 Equation (2.2) clearly indicates that we can think of the variation in poverty over time as consisting of three basic components: the size effect associated with the change in the mean of the underlying distribution, the redistribution effect resulting from changes in the Lorenz curve (an indicator of relative inequality), and a third component linked to the variation in the poverty line. When working with real income (or expenditure) as an indicator of economic welfare, the poverty line is considered fixed so that we write the overall level of poverty as a function only of mean real income (or expenditure) and the Lorenz function. With this assumption, the overall change in poverty defined by equa- tion (2.2) can be written as 1 1 ∂P ∂ µ ∂P ∂L ∆ =P O ∫ 0 ∂ µ ∂t dt + ∫ ∂L ∂t dt , (2.3) 0 so that any variation in poverty consists only of the size and the redistribution effects. Note that these effects are defined in terms of partial derivatives of the poverty measure. For a differentiable function of several variables, it is well known that the partial derivative of that function at a particular point is the rate of change of the function near the point with respect to one of the variables with the other variables held constant. This notion of ceteris paribus variation that Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 18 A Simple Approach to Understanding Changes in Poverty and Inequality underlies the definition of the decomposition terms presented in equation (2.3) also suggests a clear strategy for the identification (and hence the estimation) of those effects. The size effect, for instance, is defined as a variation in the poverty outcome with respect to a variation in the average income, holding inequality constant. Similarly, the redistribution effect is defined under the assumption of size neutrality. The identification strategy underlying all decomposition methods designed to implement equation (2.3) empirically relies on these definitions. Decomposing changes in a variable over time can be viewed as a problem of integral approximation (Müller 2008).3 Therefore, equation (2.1) provides a unifying framework and a clear theoretical foundation for the decomposition methods commonly discussed in the literature. In particular, its expression by equation (2.3) provides an analytical framework for the study of the poverty implications of a growth pattern, given that such a pattern can be characterized in terms of the level of growth and the degree of relative inequality. For example, Kraay (2006) proposes a decomposition of changes in poverty that is consistent with the fundamental equation for dynamic decomposition that is equation (2.1). Consider the class of additive poverty measures defined by z ∫ P = y ( y | z ) f ( y ) dy , where y is the outcome variable (for example, a living- 0 standard indicator, such as income or consumption expenditure), z is the poverty line, and f(y) is the density function associated with the distribution of y. The term y ( y | z) is a convex and decreasing function measuring deprivation for an individual with a level of economic welfare equal to y. This function is equal to zero when the welfare indicator is greater than or equal to the poverty line. Applying Leibnitz’s rule of differentiation under the integral sign and rear- ranging terms, one gets the following expression for the proportionate change in poverty, z dP 1 P = P ∫ yy ′ ( y | z ) g ( y ) f ( y ) dy , (2.4) 0 where y  ' is the first-order derivative of the indicator of individual deprivation and g(y) is the growth incidence curve4 (GIC) as defined by Ravallion and Chen (2003). Equation (2.4) reveals that for the class of additively separable poverty measures, a change in poverty over time can be written as a weighted sum of points along the GIC.5 This fact implies that variation in poverty outcomes, as measured by the class of additively separable poverty measures, inherits the decomposability of the GIC. In particular, using the neutral element for addition, one can split the GIC into one component showing the growth rate of average income  γ = dµ  and another showing the deviation of each point on the curve   µ   from the overall growth rate. We therefore have g ( y) = g + [g ( y) − g ]. In fact, the first component is the rate of growth that would be experienced at every quan- tile if the growth process were distribution neutral. This is essentially the size effect. It can be shown that the second component is equal to the change in the Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 A Simple Approach to Understanding Changes in Poverty and Inequality 19 slope of the Lorenz curve between the base and end periods (Ravallion and Chen 2003). Thus, this component measures the redistribution effect. Equivalently, we can express equation (2.4) as follows: z z dP γ 1 P = P ∫ yy ′ ( y | z ) f ( y ) dy + 0 P ∫ yy ′ ( y | z )  0  g ( y) − γ   f ( y ) dy. (2.5) Equation (2.5) therefore shows that the proportionate change in poverty over time can be split into two components representing the size and redistribution effects.6 It is clear from this equation that when growth is distribution neutral— that is, g ( y) = g —the redistribution effect disappears. The size effect is a product of two terms: the growth rate of per capita income and the responsiveness of the chosen poverty measure to variations in incomes. Ultimately, this responsiveness depends on the value judgments underpinning poverty measurement. Such judgments are reflected in the specification of the individual deprivation function,7 y ( y | z). The size effect measures the extent to which poverty would have changed had the growth process been distribution neutral. Similarly, the redistribution effect measures the extent to which poverty would have changed had growth left per capita income unchanged (that is, had the growth process been size neutral). This effect, too, depends on the elasticity of poverty with respect to income. Economic growth is pro-poor if it leads to poverty reduction for some choice of poverty measure. On the basis of equation (2.5), Kraay (2006) identi- fies three potential sources of pro-poor growth: (a) growth in income per capita (g ); (b) the responsiveness of poverty to growth in average income (the coefficient of h P in the size effect; see endnote 4); and (c) the pattern of relative inequality. The Datt-Ravallion Method When the poverty line is held constant over time, the overall change in poverty from the base period to the end period is equal to P ∆O = P ( µ1, L1 ) − P ( µ0 , L0 ). (2.6) Datt and Ravallion (1992) propose a threefold decomposition procedure that allows an analyst to express that variation in poverty in terms of three components: the size effect, the redistribution effect, and a residual interpreted as an interaction effect. According to the ceteris paribus strategy, the identifica- tion of each of these effects entails a comparison of observed outcomes with counter­factual ones. For instance, the size effect is the change in poverty result- ing from a variation in the mean while the Lorenz curve is held at some refer- ence level. The identification of this effect requires that we compare the observed poverty outcome with a counterfactual based on the same level of inequality. In other words, the only difference between the two states is the Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 20 A Simple Approach to Understanding Changes in Poverty and Inequality mean income. Similarly, the redistribution effect is the change in poverty result- ing from a change in the Lorenz curve while holding the mean constant at some reference level. Both the observed and counterfactual outcomes are based on the same mean but different Lorenz curves. A key methodological issue here is this: Which period should be used as refer- ence for the factor that must be common to both the counterfactual and the observed state of affairs? In principle, one could choose either the base period or the end period as reference. However, Datt and Ravallion (1992) argue that the base period is a natural choice for the decomposition and conduct their analysis on that basis. Within that framework, the size effect is equal to the following expression: µ = P ( µ1 , L0 ) − P ( µ0 , L0 ) . (2.7) ∆P Similarly, the redistribution effect is L = P ( µ0 , L1 ) − P ( µ0 , L0 ) . (2.8) ∆P Note that these two expressions describe counterfactual outcomes. The size effect entails distribution neutral growth (the Lorenz curve does not change). The redistribution effect implies that growth is size neutral (the mean does not change). To obtain the Datt-Ravallion decomposition, we can add and subtract these counterfactual outcomes to and from the right-hand side of equation (2.6). Upon rearranging terms, we get the following: P ∆O  P ( µ1, L1 ) − P ( µ1, L0 )  −  P ( µ0 , L1 ) − P ( µ0 , L0 )   . (2.9) µ + ∆L +  = ∆P P     The third term in brackets on the right-hand side of equation (2.9) is the residual interpreted as the interaction effect. It is the difference between two ways of computing the redistributive effect depending on whether one fixes the end-period mean or the base-period mean. In other words, the residual is the difference between the redistribution effect computed on the basis of the end- period mean and the same effect evaluated at the initial mean (Datt and Ravallion 1992; Ravallion 2000). This is an indicator of the extent to which changes in per capita income matter to the responsiveness of poverty to inequality. Interestingly, we can rearrange terms within the residual and get the following equivalent expression: ∆P  P ( µ1, L1 ) − P ( µ0 , L1 )  R =   P ( µ1, L0 ) − P ( µ0 , L0 )  −  . (2.10) This expression reveals that the residual is also equal to the difference between the size effect computed on the basis of the end-period Lorenz curve and the same effect evaluated at the initial-period Lorenz curve. Thus the residual also shows the importance of inequality in determining the effect Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 A Simple Approach to Understanding Changes in Poverty and Inequality 21 of changes in per capita income on poverty. The structure of the residual revealed by equations (2.9) and (2.10) led Datt and Ravallion (1992) to interpret this residual as the interaction effect between the size and redistribu- tion effects. Indeed, if the size effect depends on the reference Lorenz curve, or the redis- tribution effect on the reference mean, the residual would not equal zero. Thus, the interaction term would vanish if the poverty measure is additively separable between m and L.8 The residual would also vanish if one were to use the initial year as the reference point in the computation of the size effect and switch to the final year for the redistribution effect. Finally, no residual would be involved if one performed the Datt-Ravallion decomposition twice and took the average result. The first decomposition uses the initial year as reference, while the second uses the end year (Ravallion 2000). As it turns out, this average Datt-Ravallion decomposition is precisely the pro- cedure proposed by Shorrocks ([1999] 2013) based on the Shapley (1953) value. Kakwani (2000) proposes the same procedure but does not refer to the Shapley value. Instead, he invokes a series of axioms that the decomposition must satisfy.9 The Shapley Decomposition In general, all decomposition methods used in distributional analysis seek to identify and assign contributions to factors influencing some distributional statis- tic. Ideally, the assignment is done in a manner that exhausts the quantity under consideration. The Shapley method provides a unified framework to deal not only with the identification and estimation of the size and redistribution effects but also with many other situations in applied economics where there is a need to assess the relative importance of determining factors (Shorrocks [1999] 2013). In this section, we first review the definition of the Shapley value that motivates the method. Then we consider its application to the decomposition of change in poverty over time. The Shapley Value The Shapley value provides a formula for dividing a joint cost or a jointly pro- duced output on the basis of a fair assessment of individual contributions to the formation of total cost or the production of a surplus. Thus, it can be viewed as an interpretation of the reward principle of distributive justice (Moulin 2003).10 Formally, the Shapley value is a solution to a cooperative game with transfer- able utility (Shapley 1953). The problem of the commons is used often to explain the nature of such games. A commons is a technology that is jointly owned and operated by a group of agents. Consider a fixed set of agents engaged in such a venture. Their problem is to share fairly the fruit of this collaboration. Starting from scratch, let the agents join the venture one at a time in some predetermined order. As each agent joins, the value (to be shared) increases. Thus the contribu- tion of a given agent is the value added when he or she joins the venture. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 22 A Simple Approach to Understanding Changes in Poverty and Inequality The Shapley value of a partner is her or his average contribution to value over all possible orderings of the partners. The Shapley allocation rule respects the following restrictions: (a) there must be symmetry or anonymity; (b) the result must be an exact and additive decomposition; and (c) the contribution of each factor is taken to be equal to its (first-round) marginal impact. Symmetry means that the value assigned to play- ers does not depend on their traits or identities. This property stems from the fact that the value of a coalitional game to a player depends only on the char- acteristic function that maps the set of all possible coalitions of players to a set of payoffs. This function determines the payoff a group of players can expect by forming a coalition. To illustrate the basic idea underlying the Shapley value, consider a coalition game with a set A of three players, A = {a, b, c}, and a characteristic (or value) function u. The value of the grand coalition to be distributed among the three players is equal to u (A). The number of all possible coalitions is equal to 23 = 8, the number of all possible subsets of A (including the empty set). Thus there are seven possible nonempty coalitions. By definition, the payoff to an empty coalition is zero (u (Ø) = 0). Table 2.1 shows how to derive the Shapley value of each player. Given an ordering, the computation of the marginal contribution depends on the rank of the player in that ordering. Take, for instance, the first ordering in table 2.1: (a, b, c). Since a is first, the marginal contribution of a is ma = u ({a}) − u (Ø) = u ({a}). This is what he or she can achieve alone. We interpret this situation as joining an empty coalition. Since b is in second position, the corresponding marginal contribution is what he or she can achieve in a coalition with a, minus what a can achieve alone. The same rea- soning applies to the case of c. The Shapley payoff to each player equals the arithmetic mean of her or his marginal contributions over the six possible ­ orderings. Thus, to obtain the Shapley value for each player, we add up the marginal contributions in that player’s column and divide the result by six. In the case of player a, the Shapley value is equal to the following expression: 1 1 Sa = 3 ( ) v { a , b, c } +  6 ( ) ( ) v {a , b} + v {a , c } − 2v ( b, c )   (2.11) 1 +  6 ( ) ( ) ( ) 2v {a } − v {b} − v {c }  . Table 2.1 Shapley Allocations for a Three-Player Game Ordering a b c (a, b, c) u ({a}) u ({a, b}) − u ({a}) u ({a, b, c}) − u ({a, b}) (a, c, b) u ({a}) u ({a, b, c}) − u ({a, c}) u ({a, c}) − u ({a}) (c, a, b) u ({a, c}) − u ({c}) u ({a, b, c}) − u ({a, c}) u ({c}) (c, b, a) u ({a, b, c}) − u ({b, c}) u ({b, c}) − u ({c}) u ({c}) (b, c, a) u ({a, b, c}) − u ({b, c}) u ({b}) u ({b, c}) − u ({b}) (b, a, c) u ({a, b}) − u ({b}) u ({b}) u ({a, b, c}) − u ({a, b}) Shapley value Sa Sb Sc Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 A Simple Approach to Understanding Changes in Poverty and Inequality 23 We have written equation (2.11) in a way that makes transparent the fact that it involves all nonempty coalitions that can be formed out of three players. It is consistent with the general Shapley formula involving combinatorial analy- sis. Let A be a fixed set of n players. Moulin (2003) explains that the Shapley value can be viewed as a translation of the reward principle of fairness into an explicit allocation of u (A) on the basis of (2n − 1) values u (C), for all non- empty coalitions of the n players involved. Let Bj be the set of coalitions that exclude player j, and Bj(k) the subset of Bj containing all coalitions of size k = 0, 1, 2, …, n−1. The Shapley value of player j is given by the following formula:11 k !( n − k − 1) ! n −1 Sj = ∑ ∑( ) n! (( ) ) v C ∪ { j} − v (C ) . (2.12) k = 0 C ∈Bj k The term mj = u (C ∪ { j}) − u (C) is the marginal contribution of player j if she joins coalition C. The coefficient of the marginal value in equation (2.12) repre- sents the probability that the coalition C of size k contains exactly all the players preceding j in a random ordering of the grand coalition A. All marginal contribu- tions involved in that expression are counterfactual outcomes. We now apply this logic to the decomposition of change in poverty over time. Application to Change in Poverty Over Time To see how the above principle translates into a decomposition procedure, con- sider a distributional statistic, such as the overall level of poverty or inequality. For instance, let the poverty be a function of m contributory factors, which together account for the value of the indicator. The m factors are thus analogous to the players in a cooperative game. The decomposition approach proposed by Shorrocks ([1999] 2013) is based on the marginal effect on the value of the indicator resulting from eliminating sequentially each of the contributory factors and computing the corresponding marginal change in the statistic. The method then assigns to each factor the (arithmetic) average of its marginal contributions in all possible elimination sequences. Consider again the problem of decomposing a change in poverty over time into a size and a redistribution effect using the Shapley method to implement equation (2.3). We rewrite the overall variation in poverty as a function, H, of two factors as follows: P ∆O = H ( ∆µ , ∆L ). (2.13) In other words, the overall change in poverty is fully determined by two ­ ontributory factors12—namely, the change in the mean of the distribution c Δm = m1 − m0 and the change in the Lorenz curve ΔL = L1 − L0. As seen in the Datt-Ravallion method, the value of any effect (size or redistribution) depends on the chosen period of reference. This path dependence violates the anonymity constraint that the Shapley method must respect. We therefore need to consider Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 24 A Simple Approach to Understanding Changes in Poverty and Inequality all possible sequences of elimination and the associated marginal contributions that must be averaged in the end. In this simple case, we have only two possible sequences: either we eliminate the size factor first by setting Δm = 0 and then the redistribution factor by setting ΔL = 0, or we start with the redistribution factor to end with the size factor. The Shapley contribution of the size factor to change in poverty is equal to the average (over the two possible elimination sequences) of the relevant mar- ginal contributions. That is, 1 Sµ =  P ( µ1, L1 ) − P ( µ0 , L1 )   P ( µ1, L0 ) − P ( µ0 , L0 )  +    . (2.14) 2  Similarly, the Shapley contribution of the redistribution factor to change in poverty is equal to 1 SL =  P ( µ1, L1 ) − P ( µ1, L0 )   P ( µ0 , L1 ) − P ( µ0 , L0 )  +    . (2.15) 2  P The overall change in poverty can therefore be expressed as ∆O = Sµ + SL , which depends on the contribution of growth and redistribution with no remain- ing residual. Beyond the standard Datt-Ravallion partitioning, the decomposition of a change in poverty over time in terms of the size and redistribution effects can be embedded in a broader context to account for the effect of popula- tion shifts or for the relative importance of components of an aggregate living- standard indicator. The flexibility of the Shapley method makes it a strong candidate for handling these integrated decompositions. Let the total population of a given country be partitioned exhaustively into m socioeco- nomic groups. For instance, these groups could represent different groups according to geographic location, ethnicity, or other socioeconomic dimen- sions. Let wkt be the share of population in group k at time t for t = {0, 1} and Pkt the level of poverty in that group at the same time. For additively ­ decomposable poverty measures, overall poverty at time t can be written as follows: m Pt = ∑w k =1 P . (2.16) kt kt The change in aggregate poverty over time can now be written as follows: m P ∆O = ∑[w k =1 P − w k 0 Pk 0 ]. (2.17) k1 k1 Suppose we are interested in accounting for the overall change in poverty P ∆O in terms of changes in within-group poverty, ΔPk = Pk1 − Pk 0, and the population shifts between groups, Δwk = wk1 − wk 0 . We note that the ­ Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 A Simple Approach to Understanding Changes in Poverty and Inequality 25 contribution of group k in the change of aggregate poverty is equal to the fol- lowing expression: Ck = wk1Pk1 − wk 0 Pk 0. (2.18) If the population share of this group were fixed at the baseline level, the con- tribution of this group to overall poverty change would be wk 0 ΔPk . We can add and subtract this counterfactual to equation (2.18), rearrange terms, and sum over k. We get the following decomposition presented in Bourguignon and Ferreira (2005):13 m m P ∆O = ∑ k =1 w k 0 ∆Pk + ∑P ∆w k =1 k1 k. (2.19) According to equation (2.19), the overall change in poverty can be split into two components: one representing the contribution of changes in within-group poverty and the other the contribution of population shifts. The decomposition presented in equation (2.19) is path dependent since changes in poverty are weighted by the base-year population shares while changes in population shares are weighted by the end-year poverty level. The Shapley principle leads to the following twofold decomposition (Shorrocks [1999] 2013):14 m m  w k 0 + w k1  Pk 0 + Pk1  P ∆ = O ∑k =1   2   ∆Pk + ∑  k =1 2   ∆w k. (2.20) Equation (2.20) therefore allows for a decomposition of changes in poverty on account of changes in within-group poverty and changes in population between groups. Accounting for the Contribution of Demographics and Income Components So far we have seen decompositions of changes in poverty on account of changes in growth and redistribution and decompositions of within-group changes in poverty as opposed to changes in population between groups. However, there is also interest in decomposing changes in poverty into the contributions that changes in demographics, employment, public transfers, and remittances could have made. In this section, we describe an approach to undertake these sorts of decompositions involving the Shapley method described above. As proposed by Azevedo et al. (2013), we begin with a household consump- tion identity whereby household consumption, Ch, per capita is defined by Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 26 A Simple Approach to Understanding Changes in Poverty and Inequality Y Ch = q h nh , (2.21) where Yh is total household income, n is the number of household members, and q h is the consumption-to-income ratio. Because poverty depends on the distribu- tion of consumption, changes in any of the factors on the right-hand side of equation (2.21) will lead to changes in poverty: demographic changes (n), growth in labor and nonlabor income (which make up Yh), and changes in con- sumption patterns (q h). Following Barros et al. (2006), household per capita income can be modeled as n ∑y . (2.22) Y 1 Y pc = nh = n i i =1 Income per capita is based on the sum of each individual’s income as well as the number of household members, n. If we recognize that only individuals 15 years and older contribute to family income, income per capita depends on the number of adults in the family, nA, so income per capita can be written as  1 n  ∑ nA Y pc =  yi  . (2.23) n   nA i =1   Income per adult includes labor income, yiL, and nonlabor income, yiNL, where nonlabor income includes public social transfers, pensions, remittances, and other private transfers. Specifying each type of income, we have  1 n n  ∑ ∑y nA 1 yiL +  . (2.24) NL Y pc =  i n   nA nA   i ∈A i ∈A Finally, not all adults in the household are occupied (working), and household labor income per capita depends on the income of employed adults. Therefore, we can decompose the labor income per occupied adult as nA    1  n n Y pc =  no  1 n  nA  n ∑ yiL  +   nA ∑ yiNL  , (2.25)    o i ∈A i ∈A  where no is the number of occupied adults. Note that official poverty rates in some countries are calculated on the basis of household income. In these cases, equation (2.25) is sufficient to decompose the contribution of demographic factors, labor income, and nonlabor income to observed poverty reduction. However, most countries measure the distribution of welfare, and poverty in particular, using household consumption. Therefore, we modify the Barros et al. (2006) approach by mapping consumption to income. In particular, we refer to the household consumption identity in (2.21). Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 A Simple Approach to Understanding Changes in Poverty and Inequality 27 Combining (2.21) and (2.25) above, we can express household consumption per capita, Cpc, as  n  1 n  1 n  ∑ ∑ n C pc = q h  A  o yiL  + yiNL   . (2.26)  n  nA  n   nA     o i ∈A i ∈A  With this framework, whether countries measure welfare by per capita house- hold income or consumption, we can separate the demographic, labor, and non- labor components discussed earlier. In addition, we can separate the contribution of changes in consumption patterns over time in poverty reduction. The deter- minants of per capita consumption are summarized in figure 2.1. Contributions of Determinants of Consumption to Poverty Reduction Let F(.) be the cumulative distribution function (CDF) of the distribution of welfare. Since the factors in equation (2.6) determine the changes in the CDF of consumption underlying changes in poverty outcomes, we can trace the effect of those factors on poverty. As a result, any poverty measure can be writ- ten as a function of each of these components. Therefore, the contribution of Figure 2.1  Determinants of Consumption per Capita Propensity to consume and measurement error = θh Number of Share of Consumption household occupied per capita members = n Share of adults = n0/nA adults = nA/n Labor income per adult Income Labor income per capita per occupied adult =1/n0∑yiL Income per adult Nonlabor income per adult =1/nA∑yiNL Source: Adaptation of Barros et al. 2006. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 28 A Simple Approach to Understanding Changes in Poverty and Inequality each component toward changes in poverty or distribution can be expressed as a­function of these indicators in the initial and end periods. Following Barros et al. (2006), we can then simulate the distribution of ­ welfare by changing each of these components, one at a time, to calculate its contribution to the observed changes in poverty. In particular, let v be a measure of poverty, inequality, or any other distributional statistic. Then, this measure will be a function of the cumulative density function, F(.), which in turn depends on each of the factors above, as follows:    n n NL    ϑ = Φ  F  C pc  q h , A , o , yPO L , yPA    , (2.27)    n nA   where n ∑y L 1 L yPO = i no i ∈A and n ∑y 1 NL yPA = NL i . nA i ∈A Given that the distribution of per capita consumption for period 0 and period 1 are known, we can construct counterfactual distributions for period 1 by substituting the observed level of the indicators in period 0, one at a time. For each counterfactual distribution, we can compute the poverty measure and inter- pret those counterfactuals as the poverty that would have prevailed in the absence of a change in that indicator. For example, to see the impact of the change in the share of occupied adults, we compute ϑ ˆ , where we substitute the value of no n observed in period 0 to the observed distribution in period 1 as follows, A   ϑˆ = Φ F  C pc  q h , n A , n ˆ0 L NL   , yPO , yPA      ,    n nA    (2.28) such that the contribution of the share of occupied adults is the difference between the observed ϑ in period 1 and the estimated counterfactual, ϑ ˆ. Similarly, each of the other components in the consumption per capita distribu- tion in period 1 can be substituted by its value in period 0 so that its contribution to changes in poverty can be computed. Since we don’t have panel data, we do not observe period 1 households in period 0. Therefore, we use a rank-preserving transformation to assign first- period characteristics to the second-period observations. This method uses an idea first proposed by Juhn, Murphy, and Pierce (1993), who decomposed Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 A Simple Approach to Understanding Changes in Poverty and Inequality 29 changes in wages by running Mincer-type ordinary least squares (OLS) regres- sions that make it possible to decompose labor income inequality, using any measure of inequality, into three parts: • Quantity effects, referring to the distribution of observable workers’ character- istics, such as education and labor market experience, and are included as regressors in the equation; • Price effects, which capture changes in returns to observed characteristics through the regression’s coefficients; • The regression residual (unobservables), which reflects changes in inequality within education and experience groups. Counterfactuals for the quantity effects can be created by assigning the mean observable characteristic from one period to the other, and the counterfactual for the price effects can be created by substituting regression coefficients from one period to another. However, to complete that analysis, the authors needed to assign a value to the residuals in each period. So they created a counterfactual by ordering households by their earnings in each period and then taking the average residual value in each quantile from the first period and assigning it to all house- holds in the same quantile in the second period. In this case, instead of running a Mincer regression, we create counterfactuals by ordering households by their level of welfare (measured by either household per capita consumption or income) and then taking the average value of each characteristic in equation (2.25) for each quantile in period 0 and assigning it to each household in that same quantile in period 1. For example, if we are decom- posing the effect of labor income, we order households into quantiles by their observed total household income in periods 0 and 1. Then, for every quantile in period 1, we replace the period 1 labor income with the average labor income in period 0 from households that were in the same quantile. Barros et al. (2006) compute each counterfactual simulation in a nested fash- ion (table 2.2). They identify the contribution that interactions between variables have in poverty reduction by first computing the joint impact of a subset of variables, and then subtracting the marginal impact of each variable, one at a time. For instance, in step 2 in table 2.2, they first compute the joint impact of inserting both the share of adults and the income per adult from the first period into the distribution of the second period. They then compute the impact of changing only the share of adults and take the difference of these two simulations to approximate the marginal impact that changing the share of adults had on the distribution. However, in step 4, instead of computing the impact of income per adult on its own, they compute the impact of changing both the labor and non- labor income per adult. This is done because the sum of labor and nonlabor income should be equivalent to changing total income per adult. The results of these two simulations are different, however, and the simulation of labor income is not done explicitly, but rather ends up being a “residual” in step 8 to ensure that the cumulative effect adds up to the total distributional change. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 30 A Simple Approach to Understanding Changes in Poverty and Inequality Table 2.2 Application of Barros Methodology to Measure Contributions of Variables to Change in Poverty Step Estimate Variable or interaction being measured 1. Initial poverty rate is J0.   n n NL    ϑ 0 = Φ  F  Y pc  A , o , yPO L , yPA       n n A   2.   Contribution of the interaction between share n  ϑ a1 = Φ  F  Y pc  A , yPA    of adults and income per adult is ϑ a1 − ϑ 0 .     n   3.   Contribution of share of household adults is n  ϑ nA = Φ  F  Y pc  A , yPA    ϑ nA − ϑ a1.     n   4.   Contribution of the interaction between labor n n NL   ϑ a 2 = Φ  F  Y pc  A , o , yPO L , yPA   and nonlabor income is ϑ a 2 − ϑ nA.    n nA  5.   n n NL   Contribution of nonlabor income is ϑ NL − ϑ a1. ϑ NL = Φ  F  Y pc  A , o , yPO L , yPA      n nA  6.   Contribution of the interaction between labor n n  income and the share of occupied adults is ϑ a 3 = Φ  F  Y pc  A , o , yPO L NL , yPA      n nA   ϑ a 3 − ϑ NL. 7.   Contribution of the share of occupied adults is n n  ϑ no = Φ  F  Y pc  A , o , yPO L NL , yPA  ϑ no − ϑ a 3.     n nA   8. Final poverty rate is JF. The contribution of   n n NL    L labor income, y PO, is calculated as a ϑ F = Φ  F  Y pc  A , o , yPO L , yPA    n nA     residual: ϑ F − ϑ a 3. Azevedo et al. (2013) modify this procedure in three important ways: • They focus on consumption as a measure of welfare. • They compute a cumulative counterfactual distribution by adding one vari- able at a time. • They compute Shapley-Shorrocks estimates of each component. The first change—the focus on consumption—is made because most develop- ing countries use a consumption aggregate to measure poverty. Second, in contrast to the Barros et al. (2006) approach, the proposed method does not separately identify the contribution of the interaction between variables in the observed distributional changes; doing so is partial at best, given that changing any variable Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 A Simple Approach to Understanding Changes in Poverty and Inequality 31 can potentially affect all other variables. Instead, the impact of changes in each variable and its interactions with all other variables is calculated as the difference between the cumulative counterfactuals. Table 2.3 shows an example for one pos- sible path, taking into account the fact that nonlabor income is made up of pen- sions, transfers, capital income, and other income. The third methodological change—computing Shapley-Shorrocks estimates of each component—addresses the fact that this methodology suffers from path dependence, described in the previous section. In other words, the order in which the cumulative effects are calculated matters.15 The best-known remedy for this is to calculate the cumulative decomposition in every possible order and then Table 2.3 Proposed Methodology to Decompose Change in Poverty along One Possible Path Step Estimate Variable measured 1. Initial poverty rate is ϑ 0 .    n n NL    ϑ 0 = Φ  F  C pc  q h , A , o , yPO L , yPA    n nA     2. Contribution of share of    n n  ϑ1 = Φ  F  C pc  q h , A , o , yPO L NL , yPA  household adults is ϑ1 − ϑ 0 .     n nA   3. Contribution of the share of    n n  ϑ 2 = Φ  F  C pc  q h , A , o , yPO L NL occupied adults is ϑ 2 − ϑ1.  , yPA     n nA   4. Contribution of pensions is    n n  ϑ 3 = Φ  F  C pc  q h , A , o , yPO L Pens , yPA Trans , yPA , yCap Oth NL PA , y PA  ϑ 3 − ϑ 2.     n nA   5. Contribution of transfers is    n n  ϑ 4 = Φ  F  C pc  q h , A , o , yPO L Pens , yPA Trans , yPA , yCap Oth NL PA , y PA  ϑ 4 − ϑ 3.     n nA   6. Contribution of capital income is    n n  ϑ 5 = Φ  F  C pc  q h , A , o , yPO L Pens , yPA Trans , yPA , yCap PA , y Oth NL PA  ϑ 5 − ϑ 4.     n nA   7. Contribution of other nonlabor    n n  ϑ 6 = Φ  F  C pc  q h , A , o , yPO L Pens Trans , yCap Oth NL income is ϑ 6 − ϑ5 .  , yPA , yPA PA , y PA     n nA   8.    Final poverty rate is ϑ F .  n n NL   ϑ F = Φ  F  C pc  q h , A , o , yPO L , yPA Contribution of labor income is    n nA     ϑ F − ϑ 6. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 32 A Simple Approach to Understanding Changes in Poverty and Inequality average the results for each component to get the Shapley-Shorrocks estimate of the contribution of each component, as described earlier (Shapley 1953; Shorrocks [1999] 2013). Summary and Conclusions This chapter provides a unifying framework and a theoretical foundation for the decomposition methods commonly used in the literature. We began with the simplest decompositions, noting that changes in poverty can be characterized in terms of the level of growth and the degree of relative inequality. The most common method stemming from this view is the Datt and Ravallion (1992) decomposition. Ideally, the contribution of growth and inequality should exhaust the observed change in poverty, and the results should be the same regardless of the reference period. However, this is not the case, because a residual is typically left unaccounted for in the standard Datt- Ravallion method, and the choice of reference period can affect the results. As described in this chapter, the Shapley method provides a unified framework to assess the relative importance of determining factors (Shorrocks [1999] 2013) and addresses both of these concerns. Use of the Shapley method can be extended to more complex decompositions, such as one that accounts for changes to poverty resulting from changes within socioeconomic groups as opposed to population shifts between groups. Although these decompositions are interesting, analysts often want to go beyond these summary statistics to decompose the contributions that changes in demographics, employment, public transfers, and remittances could have made toward poverty reduction. We described an approach to undertake these sorts of decompositions, as proposed by Azevedo et al. (2013), that involves the Shapley method described above. In contrast to the simpler methods, this approach rec- ognizes that poverty is a function of total household per capita consumption, which can be written as an accounting identity that depends on the number of household members, the consumption-to-income ratio, and household income. Based on these identities, we can simulate changes in the distribution of welfare by changing each component, one at a time, to calculate its contribution to the observed changes in poverty. Assuming that only cross-sectional data are available, counterfactuals can be created nonparametrically, by ordering households according to their total income, creating quantiles for the initial and end periods, and then taking the average value of each component for each quantile in one period and assigning it to each household in that same quantile in the other period. When the cumula- tive impact of each of the components is analyzed, the methodology suffers from path dependence. Therefore, the proposed method calculates the Shapley- Shorrocks estimates of each component to find the contribution of each component. With chapter 2 having described a set of relatively simple decompositions, chapter 3 will apply the proposed methods to a large set of countries that have Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 A Simple Approach to Understanding Changes in Poverty and Inequality 33 seen significant declines in poverty over the past decade. However, before pro- ceeding, it is important to point out two remaining caveats in this approach, the first of which is addressed later in the book. First, although the decomposition method proposed here is useful to distin- guish the main contributors to poverty reduction, its main limitation is the fact that it cannot shed light on whether the decline in poverty was the result of changes in the endowments of the population (such as higher educational levels or increases in other productive assets) or the result of changes in returns to those endowments. For this, one must turn to alternative decomposition techniques that impose an underlying labor model and greater structure (such as the meth- ods proposed in chapters 4 and 6), compared with the nonparametric approach adopted here. The second caveat to this approach is that the counterfactual income distri- butions on which these decompositions rely suffer from equilibrium inconsis- tency. Because the decomposition modifies only one element at a time, the counterfactuals do not result from an economic equilibrium, but rather from a ceteris ­paribus exercise in which we assume that we can, in fact, modify one fac- tor at a time and keep everything else constant. To address this concern, one would need to employ general equilibrium modeling, which is outside the scope of this book. Notes 1. For a recent review of micro-decomposition methods, see Fortin, Lemieux, and Firpo 2011; Essama-Nssah 2012; and chapter 6 of this volume. 2. By the fundamental theorem of calculus, we know that if a primitive function F of b b another function f is known for a ≤ x ≤ b , then (Kaplan 1991). ∫ a ∫ f ( x ) dx = F ′ ( x ) dx = F ( b ) − F ( a ) a 3. Let Q(t) = Q(x1(t), x2(t), …, xm(t)) be a quantity of interest that is a function of m time-dependent variables xk(t), k = 1, 2, …, m. The fundamental equation for decomposition analogous to equation (2.1) or (2.2) can be written as m 1 ∂Q ∂ x k ∆Q = ∑ ∫ ∂x k =1 0 k ∂t dt. Any component of this expression that contains the deriva- tive with respect to xk is taken to represent the contribution of changes in this factor to the overall change in Q. A successful implementation of this decomposition requires the ability to solve the integrals involved or to approximate them. Müller (2008) explains that terms in this expression can be approximated by their values at the upper boundary, computing each derivative as the slope of the straight line joining the endpoints. He further points out that even though static decomposition of cross-sectional variations is formally equivalent to dynamic decomposition, for static decomposition to be meaningful there would need to be a continuous range of the variables involved between spatial or socioeconomic groups. Thus, the framework of integral approximation may not be appropriate for static decomposi- ­ tion. The notion of a path connecting socioeconomic groups does not necessarily make sense. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 34 A Simple Approach to Understanding Changes in Poverty and Inequality 4. Suppose that y is continuously distributed over the population of interest. Denote by Ft(y) the cumulative distribution function (CDF) of income showing the proportion, y ∫ τ = f ( y ) dy , of the population with income less than y at time t. The income level at 0 the t th quantile is given by the inverse of the CDF: yt (τ ) = Ft (τ ). The growth rate −1  y1 (τ )  of income at the t th quantile between t = 0 and t = 1 is equal to g (τ ) =  − 1 .  y0 (τ )  The growth incidence curve is obtained by letting t   vary from zero to one and plot- ting against the corresponding values of g(t ). The quantiles involved are based on the ranking of individuals in an increasing order of their baseline income. 5. See Essama-Nssah and Lambert (2009) for an alternative derivation of this result. 6. Kakwani (1993) proposes a similar decomposition of a proportionate change in pov- erty based on the responsiveness of the chosen poverty measure to changes in mean income and to variation in the Gini coefficient. 7. Members of the additively separable poverty measures include, among others, the Watts (1968) index (W) and the Foster, Greer, and Thorbecke (1984) family (FGT). The associated deprivation functions are y W ( y | z ) = ln ( z y ) for the Watts index, and α  y y FGT ( y | z ) =  1 −  , α ≥ 0, for the FGT family. When α  = 0, the deprivation leads  z to the headcount index: the proportion of individuals with living standards below the poverty line. When α  = 1, we get the normalized poverty deficit. Finally, when the same parameter is equal to 2, we get the “squared poverty gap.” 8. Ravallion (2000) clarifies this point by noting that, in general, if a variable v is a func- tion of two variables x and y and if this function is additively separable in x and y, then we can write: v = g(x) + h(y). In these circumstances, the change in v when x changes holding y constant depends only on the initial and final values of x. Without this addi- tive separability, we should expect the variation in v to depend on the particular value of y chosen. 9. In particular, Kakwani (2000) stipulates the following three axioms: First, the size and redistribution effects must exhaust the total change in poverty. Second, if both the size and the redistribution effects have the same sign (either [a] less than or equal to zero, or [b] greater than or equal to zero), then the overall change in poverty must have the same sign; otherwise, the total change in poverty must depend on the mag- nitude of the size and the redistribution effects. Third, both the size and the redistri- bution effects must be symmetric with respect to the base and end years. The latter axiom means that if changes in per capita income, for instance, induce poverty reduc- tion as we go from the base to the end year, we must accept that moving from the end state to the initial state would increase poverty. A similar logic applies to the redistri- bution effect. 10. Moulin (2003) argues that the concept of fairness can be interpreted in terms of four basic principles: exogenous rights, compensation, reward, and fitness. An exogenous right is a normative postulate that dictates how a resource must be distributed among claimants. Equal treatment of equals is an example of such a postulate. In general, exogenous rights set claims to resources independently of the use of such resources and of the contribution to their production, while compensation and reward relate Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 A Simple Approach to Understanding Changes in Poverty and Inequality 35 fairness to individual characteristics relevant to the use or production of the resources under consideration. The compensation principle advocates giving extra resources to people who find themselves in unfortunate circumstances for which they cannot be held (morally) responsible. The reward principle bases allocation on individual ­ behavior to the extent that it affects the overall burden or advantage under distribu- tion. Finally, according to the fitness principle, resources must go to the person who can make the best use of them. 11. The Shapley value of player j can be equivalently expressed as k !( n − k − 1) ! Sj = ∑{ } n! (( ) ) v C ∪ { j} − v (C ) , where the sum is taken over all possible C⊆ A \ j coalitions (including the empty one) that can be built on the basis of the members of A. 12. Thus H(0,0) = 0. 13. It is possible to further transform this twofold decomposition as follows. Consider a counterfactual situation in which within-group poverty does not change. On the basis of equation (2.19), the contribution of group k to change in poverty can be written as Ck = w k 0 ( Pk1 − Pk 0 ) + Pk1 ( w k1 − w k 0 ) . Fixing group-level poverty at the base level reduces this contribution to Pk 0 ( w k1 − w k 0 ). We can add and subtract this cou­ nterfactual outcome to and from Ck, rearrange terms, and sum up over k to get the threefold decomposition proposed by Ravallion and Huppi (1991): m m m P ∆O = ∑ k =1 w k 0 ∆Pk + ∑ k =1 Pk 0 ∆w k + ∑∆w ∆P . This k =1 k k expression shows that change in aggregate poverty over time can be decomposed into three components representing, respectively, within-group effects, the effect associated with population shifts, and interaction effects. This is analogous to the Datt-Ravallion decomposition for the size and redistribution effects. 14. Son (2003) proposes a similar expression in percentage change: P m m ∆ Pk 0  w k 0 + w k1  ∆Pk w k 0  Pk 0 + Pk1  ∆w k O P0 = ∑P k =1 0   2   Pk 0 + ∑P k =1 0   2   wk0 . 15. Path dependence is common in the micro-decomposition literature. For recent reviews of the literature, see Chapter 6 of this volume; Essama-Nssah 2012; Fortin, Lemieux, and Firpo 2011; and Ferreira 2012. Bibliography Azevedo, João Pedro, Gabriela Inchauste, Sergio Olivieri, Jaime Saavedra, and Hernan Winkler. 2013. “Is Labor Income Responsible for Poverty Reduction? A Decomposition Approach.” Policy Research Working Paper 6414, World Bank, Washington, DC. Barros, Ricardo Paes, Mirela de Carvalho, Samuel Franco, and Rosane Mendonça. 2006. “Uma Análise das Principais Causas da Queda Recente na Desigualdade de Renda Brasileira.” Revista Econômica 8 (1): 117–47. Bourguignon François, and Francisco H. G. Ferreira. 2005. “Decomposing Changes in the Distribution of Household Incomes: Methodological Aspects.” In The Microeconomics of Income Distribution Dynamics in East Asia and Latin America, edited by François Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 36 A Simple Approach to Understanding Changes in Poverty and Inequality Bourguignon, Francisco H. G. Ferreira, and Nora Lustig, 17–46. Washington, DC: World Bank. Datt, Gaurav, and Martin Ravallion. 1992. “Growth and Redistribution Components of Changes in Poverty Measures: A Decomposition with Applications to Brazil and India in the 1980s.” Journal of Development Economics 38 (2): 275–96. Essama-Nssah, B. 2012. “Identification of Sources of Variation in Poverty Outcomes.” Policy Research Working Paper 5954, World Bank, Washington, DC. Essama-Nssah, B., and Peter J. Lambert. 2009. “Measuring Pro-Poorness: A Unifying Approach with New Results.” Review of Income and Wealth 55 (3): 752–78. Ferreira, Francisco H. G. 2012. “Distributions in Motion: Economic Growth, Inequality, and Poverty Dynamics.” In The Oxford Handbook of the Economics of Poverty, edited by Philip N. Jefferson, 427–62. New York: Oxford University Press. Fortin, Nicole, Thomas Lemieux, and Sergio Firpo. 2011. “Decomposition Methods in Economics.” In Handbook of Labor Economics, Vol. 4A, edited by Orley Ashenfelter and David Card, 1–102. Amsterdam, the Netherlands: North-Holland. Foster, James, Joel Greer, and Erik Thorbecke. 1984. “A Class of Decomposable Poverty Measures.” Econometrica 52 (3): 761–65. Juhn, Chinhui, Kevin M. Murphy, and Brooks Pierce. 1993. “Wage Inequality and the Rise of Returns to Skill.” Journal of Political Economy 101 (3): 410–42. Kakwani, Nanak. 1993. “Poverty and Economic Growth with Application to Côte d’Ivoire.” Review of Income and Wealth 39 (2): 121–39. ———. 2000. “On Measuring Growth and Inequality Components of Poverty with Application to Thailand.” Journal of Quantitative Economics 16 (1): 67–79. Kaplan, Wilfred. 1991. Advanced Calculus. Redwood City, CA: Addison-Wesley. Kolenikov, Stanislav, and Anthony Shorrocks. 2005. “A Decomposition Analysis of Regional Poverty in Russia.” Review of Development Economics 9 (1): 25–46. Kraay, Aart. 2006. “When Is Growth Pro-Poor? Evidence from a Panel of Countries.” Journal of Development Economics 80 (1): 198–227. Moulin, Hervé. 2003. Fair Division and Collective Welfare. Cambridge, MA: MIT Press. Müller, Adrian. 2008. “Clarifying Poverty Decomposition.” Conference Paper 30, Proceedings of the German Development Economics Conference, Zurich. Ravallion, Martin. 2000. “On Decomposing Changes in Poverty into ‘Growth’ and ‘Redistribution’ Components.” Journal of Quantitative Economics 16 (1): 105–18. Ravallion, Martin, and Monika Huppi. 1991. “Measuring Changes in Poverty: A Methodological Case Study of Indonesia during an Adjustment Period.” World Bank Economic Review 5 (5): 57–82. Ravallion, Martin, and Shaohua Chen. 2003. “Measuring Pro Poor Growth.” Economic Letters 78 (1): 93–99. Shapley, Lloyd. S. 1953. “A Value for n-Person Games.” In Contributions to the Theory of Games, Vol. 2, edited by H. W. Kuhn and A. W. Tucker, 307–17. Princeton, NJ: Princeton University Press. Shorrocks, Anthony. F. (1999) 2013. “Decomposition Procedures for Distributional Analysis: A Unified Framework Based on Shapley Value.” Journal of Economic Inequality 11 (1): 1–28. doi: 10.1007/s10888-011-9214-z. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 A Simple Approach to Understanding Changes in Poverty and Inequality 37 Son, Hyun Hwa. 2003. “A New Poverty Decomposition.” Journal of Economic Inequality 1 (2): 181–87. Watts, Harold. 1968. “An Economic Definition of Poverty.” In On Understanding Poverty: Perspectives from the Social Sciences, edited by Daniel P. Moynihan, 316–29. New York: Basic Books. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Chapter 3 What Accounts for Changes in Poverty over the Past Decade? Introduction The reduction in poverty observed during the 2000s throughout the developing world provides an opportunity to study the most significant factors at work in favor of the poor. Did poverty decrease because of • Demographic changes that led to lower dependency ratios; • Labor market improvements that boosted employment or labor income; • Improved and more effective social policies; or • Increased remittances to poorer countries? To answer these questions, and to contribute to the evidence base for future policy, this chapter focuses on a subsample of 21 countries where poverty declined substantially in the decade from 2000 to 2010. Particularly in some Latin American countries, debate focuses on whether better job opportunities or improved transfer policies can best explain the observed reductions in poverty and inequality. In some South Asian and Eastern European countries, observers question whether it was better job opportunities or higher remittances that reduced poverty. As for several East Asian countries—where poverty reduction has coincided with strong growth and job creation—questions arise about whether social policy should focus more on redistribution. This chapter quantifies, based on a series of counterfactual simulations, the contribution of labor income to changes in poverty across countries. Based on the “simple” methodology described in chapter 2—which improved on methods that focus on aggregate summary statistics—this chapter generates entire counterfac- tual distributions, allowing us to quantify the relative contributions to poverty reduction as a result of changes in labor income, nonlabor income, and demo- graphic characteristics. Because most countries measure welfare through house- hold expenditures or consumption (as opposed to income), this chapter modifies Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7   39   40 What Accounts for Changes in Poverty over the Past Decade? existing methods and proposes a decomposition methodology for consumption- based measures of poverty. The next section, “Growth and Poverty Reduction,” describes the evolution of poverty across our 21-country sample, highlighting the links between poverty, growth and redistribution outcomes. “The Forces behind Poverty Reduction” discusses four potentially influential factors: demographic change, increased labor income, increased nonlabor income, and changed consumption patterns. We then present the data and the results for each country, highlighting similarities and differences. The concluding section summarizes the findings and assesses the decomposition methodology and its limitations. Annex 3A lists the specific data sources for each country in the sample. Growth and Poverty Reduction We focus here on 21 countries that exhibited substantial declines in moderate poverty (defined below) using comparable consumption or income data in the decade from 2000 to 2010. The countries included in this analysis are Argentina, Bangladesh, Brazil, Cambodia, Chile, Colombia, Costa Rica, Ecuador, Ghana, Honduras, Moldova, Mongolia, Nepal, Panama, Paraguay, Peru, the Philippines, Romania, Sri Lanka, Thailand, and Vietnam. Data Sources and Distinctions The analysis focuses on reductions in poverty during the 2000s. Most Latin American countries in the sample use income-based measures of poverty. For these countries, data come from national household surveys that have been har- monized and compiled in the Socio-Economic Database for Latin America and the Caribbean (SEDLAC).1 Other countries in the sample use consumption-based measures of poverty, with data provided by national household surveys. For Bangladesh, Moldova, Peru, the Philippines, Romania, Sri Lanka, and Thailand, household surveys were standardized by the World Bank. For Ghana’s and Nepal’s consumption- based measures, we use the Rural Income Generating Activities (RIGA) datasets, a harmonized database of household surveys compiled jointly by the ­ Food and Agriculture Organization of the United Nations (FAO) and the World Bank (FAO n.d.).2 Table 3A.1 (in annex 3A) provides more detail about the countries, exact years, and surveys included in this study. Regarding Cambodia, Mongolia, Vietnam, and the Philippines, household surveys were harmonized by the World Bank to generate comparable income data and income-based poverty measures. The official national poverty measurements in Cambodia, Mongolia, and Vietnam are based on the consumption welfare aggregate. Poverty Reduction in Sample Countries All countries in our sample had substantial poverty-reduction episodes, defined as an average decline in moderate poverty of 1 percentage point or more per year over a period of four years or more. Because the national moderate poverty line Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 What Accounts for Changes in Poverty over the Past Decade? 41 varies from country to country, we base the analysis on the international poverty line that is closest in magnitude to the national moderate poverty line in that country. For example, the moderate poverty line in Bangladesh is closer to the $1.25-a-day poverty line, while the moderate poverty line in Peru is closer to the $4-a-day poverty line, as shown in table 3.1.3 GDP Growth and Poverty Reduction Poverty reduction in each of the sample countries was accompanied by strong economic growth (figure 3.1), albeit at different rates, ranging from an average of 3 percent in real gross domestic product (GDP) in Paraguay to an average of 8.4 percent in Mongolia. The 2008–09 global financial crisis increased volatility and vulnerability in middle-income countries, such as Romania, Thailand, and several countries in Latin America, while other countries, such as Bangladesh, enjoyed continued, almost uninterrupted real GDP growth of about 6 percent a year throughout the decade. For the countries whose moderate poverty lines came closest to the $1.25-a-day level, the poverty reduction rate varied from an average of percentage points a year in the Philippines to 2.9 percentage points a year 1.3 ­ in Nepal (figure 3.2). Among countries whose national moderate poverty lines approach the $4-a-day level, the decline varied from an average of 1 percentage point per year in Paraguay to an average of 2.8 percentage points per year in Colombia. The link between economic growth and poverty reduction has long inter- ested economists. As detailed in Ferreira (2012), the cross-country literature has found considerable evidence that economic growth is strongly and nega- tively correlated with changes in poverty (Ravallion and Chen 2007). In addi- tion, the higher a country’s initial level of inequality, the higher the growth rate needed to reduce poverty by a given amount (World Bank 2005; Ravallion and Chen 2007). One common way to assess these relations is by using the Datt and Ravallion (1992) decomposition, which splits the change in poverty into distribution-neutral growth and redistribution effects. Using this method, we ­ found that growth explains most of the observed reduction in moderate ­ poverty for 17 of the 21 countries in this study (as shown in figure 3.2). Redistribution, which can be thought of as a reduction in inequality, was found to be more important in the cases of Argentina, Mongolia, Paraguay, and the Philippines. Poverty Effects beyond Aggregate Economic Growth In the places where most of the poverty reduction was the result of growth, some obvious questions arise: How did growth lead to poverty reduction? Were redis- tributional changes associated with the introduction of public transfers, or were they a result of market forces? Unfortunately, the Datt-Ravallion (1992) method cannot make these explicit links because growth, inequality, and poverty mea- sures are just three different aggregations of information about individual income Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 42 Table 3.1 Poverty Headcount Rates, by Benchmark, in Selected Developing Countries, 2000s a. Income-based poverty headcount ratea $4.00-a-day PPP c $2.50-a-day PPP $1.25-a-day PPP Initial Final Total Annual Initial Final Total Annual Initial Final Total Annual period period reduction change period period reduction change period period reduction change (%) (%) (ppts) (%) (%) (%) (ppts) (%) (%) (%) (ppts) (%) Argentina, 2000–10 27.5 14.6 −13.0 −6.2 14.2 6.4 −7.8 −7.7 5.1 1.8 −3.3 −9.8 Brazil, 2001–09 43.1 27.6 −15.5 −5.4 27.4 15.1 −12.3 −7.2 11.8 6.1 −5.7 −7.9 Cambodia, 2007–10b 75.1 75.7 0.5 0.2 57.3 60.1 2.8 1.6 34.0 29.6 −4.4 −4.5 Chile, 2000–09 23.2 11.8 −11.4 −7.2 9.0 4.3 −4.7 −7.9 2.3 1.3 −0.9 −5.6 Colombia, 2002–10 61.6 39.5 −22.1 −5.4 42.3 22.0 −20.3 −7.8 20.7 8.2 −12.6 −11.0 Costa Rica, 2000–08 29.2 18.9 −10.2 −5.3 14.7 7.6 −7.1 −7.9 5.5 2.4 −3.1 −9.8 Ecuador, 2003–10 51.5 33.4 −18.1 −6.0 31.5 15.9 −15.6 −9.3 12.2 4.6 −7.6 −13.0 Honduras, 1999–2009 66.1 52.1 −14.1 −2.4 47.9 36.2 −11.6 −2.7 24.9 17.8 −7.1 −3.3 Mongolia, 2007–11b 56.6 44.3 −12.3 −6.0 35.7 22.5 −13.2 −10.9 13.1 6.0 −7.1 −17.8 Panama, 2001–09 43.4 29.9 −13.5 −4.6 28.7 16.1 −12.6 −6.9 15.4 4.6 −10.8 −14.0 Paraguay, 1999–2010 43.3 32.8 −10.6 −2.5 26.7 18.4 −8.3 −3.3 14.0 7.2 −6.8 −5.9 Philippines, 2006–09b 78.3 77.9 −0.4 −0.2 62.2 60.3 −1.9 −1.0 31.7 27.6 −4.1 −4.5 Vietnam, 2004–10b 79.9 58.9 −21.0 −5.0 56.4 33.2 −23.2 −8.5 18.1 8.7 −9.4 −11.5 table continues next page Table 3.1  Poverty Headcount Rates, by Benchmark, in Selected Developing Countries, 2000s (continued) b. Consumption-based poverty headcount ratec $4.00 or $5.00-a-day PPP d $2.50-a-day PPP $1.25-a-day PPP Initial Final Total Annual Initial Final Total Annual Initial Final Total Annual period period reduction change period period reduction change period period reduction change (%) (%) (ppts) (%) (%) (%) (ppts) (%) (%) (%) (ppts) (%) Bangladesh, 2000–10 — — — — 89.2 84.0 −5.2 −0.6 57.7 40.3 −17.4 −3.5 Ghana, 1998–2005 — — — — 71.8 58.3 −13.5 −2.9 38.2 23.5 −14.7 −6.7 Moldova, 2001–10 93.8 58.7 −35.1 −5.1 71.4 12.9 −58.5 −17.3 27.5 0.5 −27.0 −35.4 Nepal, 1996–2003 — — — — 94.3 84.9 −9.5 −1.5 54.0 25.9 −28.2 −10.0 Peru, 2004–10 45.8 30.0 −15.8 −6.8 22.9 11.7 −11.2 −10.6 3.5 0.8 −2.6 −21.1 Romania, 2001–09 75.3 33.2 −42.1 −9.7 23.7 4.2 −19.5 −19.6 2.6 0.0 −2.6 −100.0 Sri Lanka, 2002–09 84.7 78.09 −6.6 −1.2 61.9 45.1 −16.8 −4.4 14.8 4.7 −10.1 −15.1 Thailand, 2000–09 31.3 16.6 −14.7 −6.8 7.9 2.5 −5.3 −11.8 3.7 1.4 −2.3 −10.3 Sources: Data for Ghana and Nepal from FAO n.d. Data for Bangladesh, Moldova, Peru, Romania, and Thailand from national household surveys. Data for Cambodia, Mongolia, the Philippines, and Vietnam from the World Bank’s East Asia and Pacific region harmonized household surveys. Note: PPP = purchasing power parity; — = not available. Latin American countries typically measure poverty using a household income aggregate, while most other countries around the world use a consumption aggregate. Because these measures are not comparable, we present them separately. a. The decomposition analysis for countries listed in panel a use income-based poverty estimates. b. The income-based figures for Cambodia, Mongolia, the Philippines, and Vietnam are not the official poverty figures because these countries (except the Philippines) use consumption-based poverty estimates. However, the analysis was undertaken using income measures of poverty because of the large discrepancy between consumption and income in these countries. c. The decomposition analysis for countries listed in panel b use consumption-based poverty estimates. d. Moldova and Romania measure moderate poverty at rates close to $5-a-day, while Peru, Sri Lanka, and Thailand measure moderate poverty at rates close to $4-a day. 43 44 What Accounts for Changes in Poverty over the Past Decade? Figure 3.1 Average Real GDP Growth in Selected Developing Countries, 2000s 9 8 Average annual growth (%) 7 6 5 4 3 2 1 0 0 0 11 Ho Ch 200 0 ur , 2 09 99 9 nt 200 9 Ph pal, 00 9 p 96 10 lo , 2 03 ua 20 9 st r, 2 –10 an 20 0 8 i L , 2 09 la , 2 09 na 20 0 Pe 00 0 na 200 9 on m, 2 –10 , 2 10 d 200 5 m a, 2 –1 01 Th , 19 0–0 0 Ne ina, 0–0 Ec ia, 6–0 Gh ica, 3–1 –0 Pa sh, 7–1 2 1 –0 M ia, 200 7– nd ile 1– Ar land –20 ilip 19 0– Co ines –20 Sr ova 1– ng dia 02– – lia 4– Ca nk 001 Co do 02 00 m 00 1 4 az –2 00 as 00 00 0 de 00 go 00 an 8– Br 99 aR 0 2 m 99 9 il, , a, Vi ru, ,1 Ro a, 1 b ay Ba bo m a ai et gu ol ge ra M Pa Source: World Bank 2013. Note: GDP = gross domestic product. dynamics. Moreover, they are jointly determined, such that cross-country esti- mates are unlikely to shed much light on the fundamental factors underlying distributional change (Ferreira 2012). Therefore, instead of relying on summary measures of poverty, one could better understand distributional changes by using full distributions of income or consumption expenditures from representative household surveys. Instead of focusing on economic growth—which can also be thought of as the propor- tional change in the mean of the income distribution—it is best to analyze how the entire distribution changes over time. Moreover, given the richness of data available in household income and expenditure surveys, one can further disag- gregate the observed distributional changes by decomposing the factors that underlie these distributions. The rest of the chapter focuses on applying the method discussed in detail in chapter 2 to further disaggregate these distribu- tional changes. Forces behind Poverty Reduction We begin by noting that at least four factors could have influenced poverty reduction: • Demographic change, particularly the share of adults per household • Growth in labor income, either because more people are employed or because their earnings have increased • Growth in nonlabor income, in the form of public or private transfers • Changes in consumption or savings patterns Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 What Accounts for Changes in Poverty over the Past Decade? 45 Figure 3.2 Contribution of Growth and Redistribution to Poverty Reduction in Selected Developing Countries, by Poverty Line, 2000s Romania, 2001–09 (poverty−5.3 ppts/yr) Moldova, 2001–10 (poverty−3.9 ppts/yr) Costa Rica, 2000–08 (poverty−1.3 ppts/yr) Countries, by poverty line, and average poverty reductions per year, ppts Honduras, 1999–2009 (poverty−1.4 ppts/yr) Thailand, 2000–09 (poverty−1.6 ppts/yr) Peru, 2004–10 (poverty−2.6 ppts/yr) Colombia, 2002–10 (poverty−2.8 ppts/yr) Ecuador, 2003–10 (poverty−2.6 ppts/yr) Panama, 2001–09 (poverty−1.7 ppts/yr) Chile, 2000–09 (poverty−1.3 ppts/yr) Brazil, 2001–09 (poverty−1.9 ppts/yr) Paraguay, 1999–2010 (poverty−1.0 ppts/yr) Argentina, 2000–10 (poverty−1.3 ppts/yr) Vietnam, 2004–10 (poverty−1.6 ppts/yr) Nepal, 1996–2003 (poverty−2.9 ppts/yr) Ghana, 1998–2005 (poverty−2.1 ppts/yr) Bangladesh, 2000–10 (poverty−1.7 ppts/yr) Sri Lanka, 2002–09 (poverty−1.4 ppts/yr) Philippines, 2006–09 (poverty−1.3 ppts/yr) Mongolia, 2007–11 (poverty−1.8 ppts/yr) –40 0 40 80 120 160 Contributions to total poverty reduction (%) Growth Redistribution Sources: Data from SEDLAC, various years; FAO n.d.; and national household surveys. Note: ppts = percentage points; PPP = purchasing power parity. Countries are listed in order of growth’s contribution to the decline of poverty. “Growth” refers to the distribution neutral mean growth of household consumption (also known as the size effect, in which the Lorenz curve does not change), and the “redistribution” effect measures the change in poverty resulting from a change in the Lorenz curve while holding the mean constant. Shapely-Shorrocks estimates are used, see chapter 2 for a full explanation. Demographic Change Demographic change could play a role by affecting the dependency ratio: the number of earners relative to the number of consumers in a household. Among the countries considered here, the population of Bangladesh grew by 25 percent between 2000 and 2010, adding 19 million people to its total, while Brazil has added 18 million (a 16 percent increase) during the same time period. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 46 What Accounts for Changes in Poverty over the Past Decade? Figure 3.3 Change in Age-Dependency Ratio of Selected Developing Countries, 2000s 100 90 Dependents per 100 working-age 80 70 60 people (%) 50 40 30 20 10 0 n 200 0 20 09 on , 2 10 Ch 20 9 a R , 20 11 an 00 9 B , 20 08 lo l, 2 09 , 2 09 Ba nam 00 0 de 200 0 Pe 200 9 20 10 Pa bod 200 0 gu ia, 2 –10 Ho ppi 99– 0 ur , 2 10 an 99 9 pa 98 9 03 6– 5 d, 1–1 0 0 Pa na, 2–1 a, 0–1 0 –1 19 –1 Gh , 19 6–0 Ne , 19 200 99 00 Ro am, 0– M nia 04– lia 1– ile 07– Sr ica, 0– ka 0– Co razi 02– Ar bia 01– sh 1– – nd es 20 20 0 Ca ado 04 3 Ph ay, 007 l, 1 –2 00 go 00 0 00 as 00 – 0 ,2 2 2 , , Ec u, m r, va r n n do i a la a nt m m ai et u iL la ol ge st Th Vi ng ili M ra Co Initial Final Source: World Bank 2012. Note: The age-dependency ratio is the ratio of dependents (people younger than 15 or older than 64) to the working-age population (those aged 15–64 years). Data are shown as the proportion of dependents per 100 working-age population. Despite these increases in population, the rate of population growth has deceler- ated enough to begin shrinking the proportion of dependents relative to the working-age population across almost all countries in our sample, as shown in figure 3.3. The exception is Sri Lanka, which has seen higher births after the end of many years of conflict in 2009. Similarly, taking into account the fact that the elderly often continue to work beyond age 64, the share of adults (ages 15 and above) per household has increased in all countries in the sample (table 3.2). However, this overall similar- ity still masks the heterogeneity across households within each country. Most important, the share of adults per poor household decreased in Mongolia, Peru, Romania, Colombia, Panama, and Moldova—potentially pointing to an unequal- izing force in these countries. Growth in Labor Income Growth in labor income could be the main driver in the observed poverty reductions—either because of higher employment rates or because of increased ­ earnings. The share of occupied (working) adults per household increased in 12 of the 21 countries in our sample, as table 3.3 illustrates. In some countries, increased female employment was an important factor. For example, in Costa Rica, Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 What Accounts for Changes in Poverty over the Past Decade? 47 Table 3.2 Share of Adults per Household, by Poverty Level, Selected Developing Countries, 2000s Poor households Poor households All households (≤ $1.25-a-day PPP) (≤ $2.50-a-day PPP) Annual Annual Annual Initial Final average Initial Final average Initial Final average year year change year year change year year change Country and years of data (%) (%) (%) (%) (%) (%) (%) (%) (%) Countries measuring poverty based on income Argentina, 2000–10 72.3 76.2 0.5 51.5 62.5 2.0 53.5 57.7 0.8 Brazil, 2001–09 71.3 75.7 0.8 50.9 56.8 1.4 55.0 55.7 0.2 Chile, 2000–09 72.6 78.0 0.8 57.5 68.4 1.9 58.8 65.6 1.2 Colombia, 2002–10 68.0 71.1 0.6 62.1 59.6 −0.5 61.4 59.1 −0.5 Costa Rica, 2000–08 67.1 73.3 1.1 58.1 64.3 1.3 56.3 60.0 0.8 Ecuador, 2003–10 66.2 72.1 1.2 56.4 61.5 1.2 56.8 60.4 0.9 Honduras, 1999–2009 57.2 63.5 1.1 48.7 53.5 0.9 50.3 55.3 1.0 Panama, 2001–09 68.1 70.0 0.3 53.7 52.2 −0.3 56.0 54.0 −0.5 Paraguay, 1999–2010 59.8 68.2 1.2 46.3 57.2 1.9 48.6 56.6 1.4 Countries measuring poverty based on consumption Bangladesh, 2000–10 60.4 65.3 0.8 55.4 58.4 0.5 58.9 63.6 0.8 Cambodia, 2007–10 66.3 68.6 1.1 60.8 61.0 0.1 62.2 64.3 1.1 Ghana, 1998–2005 56.1 60.1 1.0 49.5 51.3 0.5 52.3 54.2 0.5 Moldova, 2001–10 78.8 81.8 0.4 73.1 68.1 −0.8 76.4 73.5 −0.4 Mongolia, 2007–11 72.5 72.9 0.1 64.9 60.4 −1.8 66.0 62.0 −1.5 Nepal, 1996–2003 57.9 61.1 0.8 55.1 55.0 0.0 57.0 58.6 0.4 Peru, 2004–10 68.3 69.2 0.2 51.5 51.2 −0.1 55.0 50.8 −1.3 Philippines, 2006–09 65.4 67.5 1.1 55.1 57.2 1.3 59.7 61.8 1.2 Romania, 2001–09 82.2 84.8 0.4 60.9 — — 71.9 67.1 −0.9 Sri Lanka, 2002–09 74.2 76.3 0.4 65.3 68.8 0.7 71.3 73.1 0.4 Thailand, 2000–09 74.2 77.8 0.5 56.9 53.6 −0.7 61.4 65.6 0.7 Vietnam, 2004–10 73.4 76.3 0.7 64.6 67.6 0.8 69.6 70.9 0.3 Sources: Data from SEDLAC, various years; FAO n.d.; World Bank East Asia and Pacific regional unit household surveys and national household surveys. Note: — = not available; PPP = purchasing power parity. both labor force participation and employment of women increased by about percent between 2000 and 2008 (World Bank 2012). 23 ­ However, this trend is not homogeneous across countries or within them. Indeed, the share of working adults (15 years of age or older) per household declined (in order of most to least) in Mongolia, Sri Lanka, Ghana, and Honduras across the distribution. Such a change could be positive if the main breadwinners were earning higher incomes, thus enabling the youths to continue in school and the older adults to retire. However, even within countries, the data show some important differences across the distribution in how the share of working adults has changed over time. For example, the share of working adults declined signifi- cantly among the poor in Brazil, Chile, and Costa Rica, even though these Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 48 What Accounts for Changes in Poverty over the Past Decade? Table 3.3 Share of Working Adults per Household, by Poverty Level, in Selected Developing Countries, 2000s Average of all Poor households Poor households households (≤ $1.25-a-day PPP) (≤ $2.50-a-day PPP) Annual Annual Annual Initial Final average Initial Final average Initial Final average Year year change Year year change Year year change Country and years of data (%) (%) (%) (%) (%) (%) (%) (%) (%) Countries measuring poverty based on income Argentina, 2000–10 48.8 55.7 1.3 26.3 27.0 0.3 32.8 34.7 0.6 Brazil, 2001–09 60.4 62.7 0.5 42.8 34.8 −2.6 50.9 46.7 −1.1 Chile, 2000–09 49.4 49.6 0.1 14.9 6.9 −8.3 27.4 15.7 −6.0 Colombia, 2002–10 55.1 60.5 1.2 40.2 39.1 −0.3 46.0 46.2 0.1 Costa Rica, 2000–08 53.7 56.9 0.7 22.5 16.5 −3.8 31.4 26.3 −2.2 Ecuador, 2003–10 61.5 59.4 −0.5 49.4 50.7 0.4 53.7 51.7 −0.5 Honduras, 1999–2009 63.2 59.6 −0.6 55.1 41.3 −2.8 57.7 50.3 −1.4 Panama, 2001–09 51.7 59.7 1.8 45.7 50.3 1.2 44.6 51.8 1.9 Paraguay, 1999–2010 61.7 64.1 0.3 51.2 49.1 −0.4 53.6 53.8 0.0 Countries measuring poverty based on consumption Bangladesh, 2000–10 46.9 48.2 0.3 49.7 50.5 0.2 47.8 49.1 0.3 Cambodia, 2007–10 81.3 85.1 1.5 81.9 84.6 1.1 81.8 85.0 1.3 Ghana, 1998–2005 41.4 39.2 −0.8 38.1 32.0 −2.5 39.3 35.6 −1.4 Moldova, 2001–10 65.3 66.1 0.1 64.7 76.0 1.8 64.1 71.0 1.1 Mongolia, 2007–11 62.8 54.9 −3.3 55.7 45.9 −4.7 61.4 52.7 −3.8 Nepal, 1996–2003 32.7 33.8 0.5 32.7 34.0 0.6 32.7 34.2 0.6 Peru, 2004–10 69.4 72.5 0.7 82.5 78.3 −0.9 79.1 80.1 0.2 Philippines, 2006–09 59.5 58.7 −0.4 64.1 63.6 −0.3 62.1 61.4 −0.4 Romania, 2001–09 83.2 82.1 −0.2 79.5 n.a. n.a. 83.6 74.1 −1.5 Sri Lanka, 2002–09 53.7 49.6 −1.1 53.1 45.0 −2.3 53.8 49.4 −1.2 Thailand, 2000–09 74.7 74.4 −0.1 60.6 72.0 1.9 78.2 71.3 −1.0 Vietnam, 2004–10 79.1 78.5 −0.1 50.8 52.2 0.5 54.7 54.9 0.1 Sources: Data from SEDLAC, various years; FAO n.d.: World Bank East Asia Pacific regional unit harmonized household surveys and national household surveys. Note: “Working adults” are defined as household members (aged 15–64 years) who are occupied in work for pay. PPP = purchasing power parity. ­ ountries had a higher share of working adults on average—indicating that the c increasing share of working adults was occurring mostly at the top end of the distribution. In most of the countries, however, the rise of working-adult populations might not only indicate an increase in workers per household but also reflect evidence that labor incomes per adult increased at the bottom of the distri- bution in many of these countries. Unfortunately, we cannot determine whether the poor are earning more because of higher hourly wages or because of more hours worked. In any case, labor incomes have usually increased among the poor. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 What Accounts for Changes in Poverty over the Past Decade? 49 Figure 3.4 Change in Subsidies and Other Social Transfers in Selected Developing Countries, 2000s 25 Subsidies and transfers, % of GDP 20 15 10 5 0 09 a 09 a 09 a 9a 08 a 09 a 9 09 11 0 09 9 5 –0 –1 –0 00 2– 7– –0 0– 06 0– 20 4– 2– 07 01 1– –2 00 00 02 00 00 20 00 00 9– 20 20 00 98 ,2 ,2 20 ,2 ,2 99 ,2 ,2 ,2 19 s, a, il, ka lia ile a, ne az sh di ru ia va ,1 a, an go bi Ch an bo Pe Br pi de do ay an m iL on ilip m m gu la ol lo Gh Sr Ro M ng Ca M Co Ph ra Ba Pa Initial Final Source: World Bank 2012. Note: GDP = gross domestic product. a. The reported subsidy and transfer data are for a year that is one year earlier than the household survey. Growth in Nonlabor Income A third major factor in poverty reduction could have been strongly related to growth in nonlabor incomes. For example, for countries where data is readily available, figure 3.4 shows that public subsidies and other social transfers have increased in several countries over the past decade. Government spending for subsidies and transfers increased more than sixfold in Ghana and by more than 60 percent as a share of GDP in Bangladesh, Moldova, Mongolia, and Romania. In addition to public sources of transfers, private transfers, such as remittances, have grown strongly in many of the countries (figure 3.5), as these cases exemplify: • In Nepal, remittances grew from 1 percent of GDP in 1996 to 12 percent in 2003. • In Moldova, they increased from 14 percent of GDP in 2001 to 22 percent in 2010. • In Honduras, they nearly tripled, going from 6 percent of GDP in 1999 to 17.8 percent in 2009. How important were these increased transfers—whether public or private— to poverty reduction? For instance, if remittances mostly reached higher-income Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 50 What Accounts for Changes in Poverty over the Past Decade? Figure 3.5 Change in International Remittances to Selected Developing Countries, 2000s 25 20 Remittances, % of GDP 15 10 5 0 10 0 0 na 0 0 Ba Lan , 20 –09 Ph lade , 20 10 pi , 20 –09 nd al, 006 0 9 do 9 3 00 9 Br , 20 –09 la 0 0 na , 20 –09 Ca na, 200 9 Co od 98– 9 Co e 200 10 M Ric 000 0 Pa g 20 –10 a 2 08 Ro dor 9–2 1 m 20 05 ua 99 –1 m , 2 01 et , 2 –1 Ho p , 2 –1 ur 199 –0 ol 99 00 , 2 00 ai l, 2 –1 –0 0 2 1 1– – m 19 1– a, 7– st ru, 2– – lo ia, 20 in 00 Th azi 00 Pa nd 01 Gh ma 00 ra oli 00 Ec y, 1 007 Vi nia 03 Sr m 01 ng ka 04 ilip sh 02 Ne nes 00 M s, 1 6–2 va –2 bi 0 nt 20 ge le, , on a, gu a, a Ar Chi a P a b a a i Initial Final Source: World Bank 2012. Note: GDP = gross domestic product. households, one would not expect poverty to decline. As table 3.4 shows, most countries in our sample did see an increase in transfers as a share of total household income, but the impact of these among the poor varied. Transfers ­ were especially important for poor households in Argentina, Brazil, Colombia, Moldova, and Peru. However, the share of transfers in total household income actually declined among poor households in some countries (Cambodia, Ghana, Honduras, and Sri Lanka), partly reflecting relatively weaker public social protec- tion programs, but also highlighting the fact that remittances do not always help the poor (table 3.4). Changes in Consumption or Savings Patterns Finally, in the absence of measurement error, changes in consumption-based poverty could also be related to changes in consumption and savings patterns. In the context of growing incomes, households could either increase consumption proportionately or they could increase their savings. However, given measure- ment errors in income and expenditure aggregates in household surveys, it is difficult to differentiate between household consumption changes resulting from real behavioral shifts and those resulting from measurement errors. Whatever the cause—or causes—of apparent household consumption changes, table 3.5 shows a full range of patterns. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 What Accounts for Changes in Poverty over the Past Decade? 51 Table 3.4 Share of Transfers in Total Household Income, by Poverty Level, in Selected Developing Countries, 2000s Poor households Poor households All households (≤ $1.25-a-day PPP) (≤ $2.50-a-day PPP) Annual Annual Annual Initial Final average Initial Final average Initial Final average Year year change Year year change Year year change Country and years of data (%) (%) (%) (%) (%) (%) (%) (%) (%) Countries measuring poverty based on income Argentina, 2000–10 4.7 6.5 3.3 12.7 48.9 14.4 8.7 32.9 14.3 Brazil, 2001–09 1.2 5.8 21.3 4.9 47.0 32.6 2.8 24.8 31.1 Chile, 2000–09 — 6.4 — — 42.3 — — 27.7 — Colombia, 2002–10 4.7 9.2 8.6 9.2 30.8 16.4 6.8 20.7 14.9 Costa Rica, 2000–08 — 4.5 — — 28.6 — — 19.8 — Ecuador, 2003–10 9.0 10.6 2.3 24.8 35.3 5.1 15.1 24.4 7.1 Honduras, 1999–2009 9.1 7.1 –2.5 11.9 3.7 –11.0 10.1 2.8 –12.0 Panama, 2001–09 10.1 12.3 2.4 26.1 41.2 5.9 21.8 32.3 5.0 Paraguay, 1999–2010 8.4 9.0 0.7 8.3 16.9 6.7 10.4 16.3 4.2 Countries measuring poverty based on consumption Bangladesh, 2000–10 2.7 3.5 2.5 1.8 2.0 0.8 2.5 3.1 2.1 Cambodia, 2007–10 2.6 1.7 –12.6 3.2 2.6 –7.4 3.0 2.1 –11.7 Ghana, 1998–2005 5.1 5.1 0.1 3.6 2.8 –3.2 3.8 3.8 –0.2 Moldova, 2001–10 4.5 24.0 20.5 7.2 22.5 13.5 6.2 19.0 13.2 Mongolia, 2007–11 25.7 29.3 3.4 49.4 69.9 9.1 35.4 48.1 8.0 Nepal, 1996–2003 3.0 4.9 7.5 2.7 3.7 4.5 2.9 4.7 7.0 Peru, 2004–10 7.6 5.4 –5.4 4.2 10.4 16.3 3.9 8.5 14.0 Philippines, 2006–09 21.1 22.5 2.2 23.0 25.1 2.9 19.9 21.3 2.3 Romania, 2001–09 8.1 8.7 0.8 29.7 … — 19.4 33.8 7.2 Sri Lanka, 2002–09 2.2 2.1 –0.2 3.2 1.8 –8.0 2.3 1.8 –3.6 Thailand, 2000–09 9.9 10.7 0.9 18.6 19.1 0.3 11.7 14.3 2.2 Vietnam, 2004–10 11.1 9.6 –2.5 9.8 10.8 1.6 9.7 10.6 1.6 Sources: Data from SEDLAC, various years; FAO n.d.: World Bank’s East Asia Pacific regional unit harmonized household surveys and national household surveys. Note: — = not available; … = negligible; PPP = purchasing power parity. • In Bangladesh, Ghana, and Peru, the consumption-to-income ratio increased among households at the bottom of the income distribution, while it fell among those at the top. • In Nepal, Sri Lanka, and Thailand, this ratio remained more or less flat across the distribution. • In Moldova and Romania, the consumption-to-income ratio fell more among households at the bottom of the income distribution than it did among those at the top. Although we cannot differentiate between measurement error and changing behavior as drivers of change in the consumption-to-income ratios, we can show Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 52 Table 3.5 Change in Household Consumption-to-Income Ratio in Selected Developing Countries, 2000s Bangladesh Ghana Moldova Nepal Peru Romania Sri Lanka Thailand 2000–10 1998–2005 2001–10 1996–2003 2005–09 2001–09 2002–09 2000–09 Annual Annual Annual Annual Annual Annual Annual Annual Initial Final average Initial Final average Initial Final average Initial Final average Initia Final average Initial Final average Initial Final average Initial Final average Income year year change year year change year year change year year change year year change year year change year year change year year change decile (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) (%) 1 1.8 2.3 3 22.6 34.8 6 15.3 18.4 2 3.3 2.9 –2 1.6 1.9 5 4.51 2.37 –8 3.1 3.0 0 1.5 1.2 –3 2 1.2 1.5 2 5.9 8.3 5 4.0 1.9 –8 1.9 1.6 –2 1.3 1.4 2 1.89 1.16 –6 1.5 1.5 0 1.1 1.0 –2 3 1.0 1.3 2 3.3 4.6 5 2.9 1.5 –7 1.5 1.4 –1 1.2 1.2 1 1.44 0.99 –5 1.3 1.3 0 1.0 0.9 –1 4 1.0 1.1 1 2.5 3.4 5 2.2 1.3 –6 1.2 1.2 0 1.2 1.1 –1 1.26 0.88 –4 1.2 1.2 1 0.9 0.9 –1 5 1.0 1.0 0 2.2 2.5 2 1.8 1.2 –5 1.1 1.1 0 1.1 1.0 –1 1.10 0.82 –4 1.1 1.1 –1 0.9 0.8 –1 6 1.0 0.9 –1 1.7 2.2 3 1.6 1.1 –4 1.0 0.9 –1 1.1 1.0 –2 1.01 0.74 –4 1.0 1.0 0 0.8 0.8 0 7 1.0 0.8 –2 1.5 1.6 0 1.3 1.0 –3 1.0 1.0 0 1.0 0.9 –1 0.92 0.71 –3 1.0 0.9 –1 0.8 0.8 0 8 0.9 0.7 –2 1.5 1.2 –2 1.1 0.9 –2 0.9 0.9 0 0.9 0.9 –2 0.85 0.65 –3 0.9 0.9 –1 0.7 0.7 0 9 0.9 0.6 –4 1.3 1.0 –3 0.9 0.9 –1 0.9 0.8 –1 0.8 0.8 –1 0.77 0.60 –3 0.8 0.8 –1 0.6 0.6 0 10 0.8 0.5 –5 0.8 0.5 –6 0.7 0.7 0 0.8 0.8 –1 0.7 0.7 0 0.64 0.49 –3 0.7 0.5 –3 0.5 0.5 0 Sources: FAO n.d.; national household surveys. Note: The eight countries measured represent those out of the 21-country sample set that measure poverty by consumption rather than by income. What Accounts for Changes in Poverty over the Past Decade? 53 how changes in this ratio affect overall changes in poverty. In short, each source of change described above could have contributed to the observed reductions in poverty over the past decade. How large of a contribution each of these forces made is the next question. Results Main Driver of Poverty Reduction: Labor Income Growth Which factor—demographics, labor income, public transfers, or remittances— contributed the most to observed reductions in poverty? One key result stands out: the most important contributor to poverty reduction has been the growth in earnings, as a result of higher employment and higher labor incomes. In 12 of the 21 countries with substantial declines in poverty, the combined effect of higher labor income and higher employment rates explain more than half of the poverty reduction; in another 6 countries, those two factors account for more than 40 percent of the reduction (as shown in figure 3.6 and table 3.6). This result holds true regardless of the decomposition path taken, as these results are an average of every possible decomposition path, as described in chapter 2, following Shapley (1953) and Shorrocks (1999). Interestingly, in most cases, the greatest poverty reducer throughout the 2000s was labor income growth, rather than an increase in the share of working adults. Indeed, such growth alone cut poverty by more than half in 10 out of the 21 countries. In contrast, growth in the share of employed adults cut poverty by more than 20 percent in only 4 countries. Importance of Demographic Changes Although increases in labor income are the main contributors to reductions in poverty in most countries, demographics also mattered. In particular, a higher share of working-age adults in the household made the largest contribution to poverty reduction in Costa Rica, Paraguay, and the Philippines, but it was also important in Bangladesh, Cambodia, Chile, and Honduras. Changes in the share of adults per household were also relatively important in explaining declines in moderate poverty in Bangladesh, Cambodia, Chile, Costa Rica, Ecuador, Honduras, the Philippines, and Paraguay (as shown in and figure 3.6 and table 3.6). In contrast, in Mongolia, the share of adults per house- hold among the poor decreased, therefore increasing poverty and pointing to an unequalizing force there (table 3.6). In general, increased percentages of working-age adults contributed positively to poverty reduction. However, the magnitude of this effect is small relative to the effect of labor income growth. Roles of Employment Growth and Labor Income Earnings growth, resulting from higher employment and higher labor incomes, was the most important contributor to poverty reduction. However, of these two elements, it was the growth in labor incomes that made most of the difference. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 54 What Accounts for Changes in Poverty over the Past Decade? Figure 3.6  Decomposition of Changes in Moderate Poverty, by Level, in Selected Developing Countries, 2000s 140 120 Contribution to change in poverty (%) 100 80 60 40 20 0 –20 –40 1 0 03 9 09 0 09 10 8 10 10 9 9 0 –09 0 9 05 –10 09 0 1 0–1 4–1 0–0 200 1–0 201 1–0 7–1 6–0 4–1 07– –20 02– 00– 02– 01– 03– –20 01– 000 000 200 , 200 , 200 200 , 200 0 200 99– 99– , 200 a, 20 996 a, 20 e, 20 a, 20 a, 20 r, 20 0 998 il, 20 d, 2 ia, 2 na, 2 s, 19 y, 19 esh, ica, nes, ania nam ama Peru al, 1 na, 1 ado goli ank mbi dov Chil Braz ilan bod enti ta R dura glad ippi gua Nep Rom Pan Viet Ecu Sri L Mon Tha Mol Gha Colo Cam Arg Cos Phil Para Ban Hon ≤$1.25-a-day PPP $4.00-a-day PPP $5.00-a -day PPP Countries, by poverty line Nonlabor income Share of working-age family members Employment + earnings Consumption-to-income ratio Sources: Data from SEDLAC, various years; FAO n.d.; and national household surveys. Note: PPP = purchasing power parity. “Nonlabor income” refers to public and private transfers (including remittances), pensions, capital, and other nonlabor income. “Employment + earnings” refers to the combination of increased employment among working-age adults (aged 15–64 years) and increases in their earnings. Consumption-based measures of poverty are used in Bangladesh, Ghana, Nepal, Peru, Thailand, Moldova, and Romania. The remaining countries use income-based measures of poverty. Although higher employment typically contributed to poverty reduction, lower employment among the poor partially offset poverty reduction in some countries (table 3.6). For instance, as shown in table 3.3, employment declined among the poor in more than one-third of the countries in our sample: Ecuador, Ghana, Honduras, Mongolia, the Philippines, Sri Lanka, Thailand, and Vietnam. It is no wonder that reductions in employment actually offset poverty reduction in these countries (table 3.6). Overall, the increase in workers’ earnings was relatively more important in reducing poverty than the increase in the number of workers or in the number of jobs. Although we cannot disentangle whether earnings increased because of improvements in the quality of jobs, changes in productivity, or simply Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Table 3.6 Contributions to Declines in Moderate Poverty, by Level, in Selected Developing Countries, 2000s ≤ $1.25-a-day PPP ≤$4.00-a-day PPP ≤$5.00-a-day PPP Honduras, 1999–2009 Paraguay, 1999–2010 Bangladesh, 2000–10 Philippines, 2006–09 Cambodia, 2007–10 Costa Rica, 2000–08 Argentina, 2000–10 Colombia, 2002–10 Mongolia, 2007–11 Ghana, 1998–2005 Romania, 2001–09 Sri Lanka, 2002–09 Thailand, 2000–09 Moldova, 2001–10 Panama, 2001–09 Vietnam, 2004–10 Nepal, 1996–2003 Ecuador, 2003–10 Brazil, 2001–09 Chile, 2000–09 Peru, 2004–10 Poverty rate Initial period (%) 57.7 34.0 38.2 13.1 73.7 31.7 14.8 18.1 27.5 43.1 23.2 61.6 29.2 51.5 66.1 43.4 43.3 45.8 31.4 93.8 75.3 Final period (%) 40.3 29.6 23.5 6.0 53.1 27.6 4.7 8.7 14.6 27.6 11.8 39.5 18.9 33.4 52.1 29.9 32.8 30.0 16.6 58.7 33.2 Total change (ppts) –17.4 –4.4 –14.7 –7.1 –20.6 –4.1 –10.1 –9.4 –13.0 –15.5 –11.4 –22.1 –10.2 –18.1 –14.1 –13.5 –17.3 –15.8 –14.8 –35.1 –42.2 Contributions to poverty reduction Consumption-to- income ratio (%) –25.6 n.a. 17.7 n.a. –6.9 n.a. –0.19 n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. –0.4 –26.4 –20.4 16.0 Share of adults in the household (%) 37.2 34.9 21.4 –1.0 14.2 47.6 19.5 15.9 22.0 16.4 31.0 12.1 34.4 27.1 32.0 13.5 59.5 1.8 22.8 6.9 25.1 Share of occupied (working) adults (%) 20.5 33.3 –3.6 –18.2 13.4 –0.9 –21.8 –4.3 16.7 10.9 –0.1 15.8 14.2 –3.3 –4.1 29.1 11.6 17.0 –9.7 –0.4 21.7 Labor income (earnings) per adult (%) 60.2 46.4 49.6 62.6 50.4 23.2 62.9 75.4 35.2 41.6 48.2 38.3 17.7 53.3 55.8 30.2 33.2 67.5 80.9 44.2 –10.9 Capital (%) 7.8 — 5.0 — 5.9 — 0.0 — –5.4 –0.7 –4.2 4.3 3.9 –0.7 3.8 –0.2 0.0 3.4 1.5 1.0 21.6 Pension (%) 0.0 –5.2 0.0 3.2 0.0 2.2 1.5 2.9 14.9 17.9 15.8 4.6 23.6 6.2 3.2 10.4 –3.0 16.0 36.8 23.0 6.3 Transfers (%) 15.7 –8.1 10.0 52.2 23.0 27.6 –1.6 8.0 7.3 9.1 41.8 15.6 22.4 13.6 3.4 16.4 –1.0 –0.9 2.3 35.0 9.7 Other nonlabor income (%) –15.9 –1.5 0.0 1.2 0.0 0.2 39.8 2.1 9.3 4.8 –32.5 9.4 –16.1 3.8 6.0 0.5 –0.3 –4.3 –8.2 10.7 10.6 Total contributions (%) 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 Sources: SEDLAC, various years; FAO n.d.; World Bank harmonized household surveys for East Asia and Pacific countries and national household surveys. Note: PPP = purchasing power parity; ppts = percentage points; — = not available; n.a. = not applicable. “Occupied (working) adults” is defined as those 15–64 years of age. Consumption-based measures of poverty are used in Bangladesh, Ghana, Moldova, Nepal, Peru, Romania, and Thailand. Income-based measures of poverty are used in Argentina, Brazil, Cambodia, Chile, Colombia, Costa Rica, Ecuador, Honduras, Mongolia, Panama, Paraguay, the Philippines, and Vietnam. 55 56 What Accounts for Changes in Poverty over the Past Decade? longer hours, we can conclude that it was workers’ labor income growth that made the difference rather than higher employment rates. Roles of Nonlabor Income and Consumption Although nonlabor income, such as public and private transfers, was also impor- tant, its contribution toward declines in moderate poverty in most of the sample countries was relatively small. The exceptions were Moldova, Mongolia, and Romania, where transfers contributed relatively more to reductions in poverty than they did elsewhere. In Romania, this was related to changes in transfers and capital income; in Mongolia, to a significant increase in social transfers with the introduction of the Human Development Fund; and in Moldova, mostly to increased international remittances. Finally, for countries where poverty is measured by consumption, these decompositions suggest that reductions in the consumption-to-income ratio gen- erally helped to reduce poverty in Ghana and Romania, where the consumption- income ratio increased at the bottom of the distribution. However, in all other instances, decreases in the consumption-to-income ratio during the past decade did not reduce poverty as much as it would have if consumption had remained a constant share of income.4 Further Decompositions by Poverty Line Annex 3B presents more-detailed decompositions of poverty reductions in the sample countries according to different international poverty lines ($1.25 a day, in table 3B.1; $2.50 a day, in table 3B.2; and $4.00–$5.00 a day, in table 3B.3). Moreover, each of the annex 3B tables includes decompositions along three dimensions defined by Foster, Greer, and Thorbecke (1984): • The poverty headcount rate (the proportion of the population that is poor), represented as FGT0 • The poverty gap (the distance between the incomes of the poor and the pov- erty line), represented as FGT15 • The poverty severity (a measure that gives greater weight to those furthest away from the poverty line), represented as FGT26 For middle-income countries, the $2.50-a-day poverty line is close to national extreme poverty lines. In such cases, nonlabor incomes are relatively more impor- tant (table 3B.1) because transfers play a larger role in poverty reduction.7 For instance, transfers account for about 87 percent in Chile; 58 percent of poverty reduction in Thailand; 40 percent in the Philippines; and 20–30 percent in Colombia, Costa Rica, Ecuador, Moldova, and Panama. Regardless of which poverty line is used, transfers play a more important role for those who live the furthest below the poverty line, the extreme poor. Transfers account for a greater share of the declines in both the poverty gap (FGT1) Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 What Accounts for Changes in Poverty over the Past Decade? 57 and poverty severity (FGT2), as the data show in tables 3B.1, 3B.2, and 3B.3. Particularly in Argentina, Brazil, Chile, Costa Rica, Moldova, the Philippines, Thailand, and Vietnam, increases in cash transfers and pensions jointly account for a larger share of the decline in poverty severity than do changes in labor income (table 3B.2). This finding is consistent with the improvements those countries have made in their social protection systems, which are typically tar- geted at the bottom of the distribution and have increased in performance over the past decade (World Bank 2013).8 Summary and Conclusions This chapter has implemented a distinct approach to account for the ­ relative contributions of demographics, labor income, and nonlabor income to the signifi- cant poverty reductions observed in 21 countries during the past decade. In contrast to methods that focus on aggregate ­ summary statistics as detailed in chapter 2, the method adopted here generates entire counterfactual distributions, allowing us to identify the contributions of these factors to observed distribu- tional changes. Another contribution is the chapter’s ­ application of the best-known remedy for path dependence, which is to calculate the decomposi- ­ ­ verage among them. tion across all possible paths and then take the a From Useful Findings, More Questions For most of the 21 countries in our sample, the most important contributor to reductions in moderate poverty has been the growth in labor income. In particu- lar, among 12 of them with substantial declines in poverty, changes in labor income and employment explain more than half of the change in poverty; in another 6 countries, the same changes account for more than 40 percent of reduced poverty. Demographic changes had their role: the swelling numbers of working-age adults translated into larger numbers of occupied adults per household, and the increased employment reduced poverty. As the data confirmed, however, it was not so much increased employment but increased earnings per occupied adult that made the largest contribution to poverty reduction. Although we cannot distinguish whether the earnings increased because of higher hourly wages, better-quality jobs, higher productivity, or greater number of hours worked, the ­ point is that higher labor incomes appear to be the key factor behind reductions in poverty observed in the past decade. Declining dependency ratios also pointed to the importance of demographic changes in alleviating poverty, especially in Bangladesh, Cambodia, Chile, Costa Rica, Honduras, Paraguay, and the Philippines. In most cases, however, these effects were smaller than the effect of labor income growth. As for employment rates, we find that overall employment gains typically contributed to poverty reduction, but in places where employment decreased Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 58 What Accounts for Changes in Poverty over the Past Decade? specifically among the poor, poverty naturally increased. Even in cases where employment growth helped to reduce poverty, the increase in workers’ earnings had relatively more impact on reducing poverty than the increase in the share of employed adults. Finally, both public and private transfers contributed significantly to reduction of moderate poverty, albeit less so than labor income growth. They became far more important when accounting for changes in extreme ­ poverty. From decom- position of the extreme-poverty headcount, poverty gap, and poverty severity (table 3B.1), we find that transfers and pensions contributed a relatively higher share than labor income growth. These results point to the crucial role that social protection systems play in reaching the extreme poor. Limitations and Next Steps The decomposition method applied here is quite useful for distinguishing the main contributors to poverty reduction. Its main limitation is that it cannot shed light on why workers’ earnings increased. Any number of alternatives arise: Did earnings increase because of changes in the endowments of the population, such as higher educational levels or increases in other productive assets? Did marketplace premiums rise for workers with those endowments? In many developing countries, poverty reduction has coincided with the labor force’s increasing education and health—as well as, in some cases, more equitable dis- tribution of land or other productive assets. Therefore, such distinctions as the effects of changing endowments—and the returns from those endowments— are important if we are to fully understand changes in poverty and how to further reduce it. To resolve this issue, we must consider alternative decomposition techniques that impose an underlying labor model and greater structure than the nonpara- metric approach adopted here (Juhn, Murphy, and Pierce 1993; Bourguignon, Ferreira, and Lustig 2005; Bourguignon, Ferreira, and Leite 2008). It is to this task that the remainder of the book is dedicated. Annex 3A: Data Sources For the data on Latin American countries, we use the SEDLAC dataset, which covers all countries in mainland Latin America and four of the largest countries in the Caribbean. Most household surveys included in the sample are nationally representative. For comparability purposes, this dataset com- putes income using a common method across countries and years. In particu- lar, it constructs a common household income variable that includes all the ordinary sources of income and estimates of the imputed rent from home ownership. (For further methodological details, see the “Methodology” link on the SEDLAC website: http://sedlac.econo.unlp.edu.ar/eng/.) Only the Latin Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 What Accounts for Changes in Poverty over the Past Decade? 59 American countries have available data on hours of work, allowing for further decomposition in the report. For the data on Bangladesh, Moldova, Peru, Romania, Sri Lanka, and Thailand, we use the national Household Income and Expenditure Survey (HIES) for each year. We make temporal and spatial adjustments for comparability reasons. For Ghana and Nepal, we use the RIGA dataset (FAO n.d.). Table 3A.1 Survey Sources of Data for Poverty Reduction Analysis in Selected Developing Countries, 2000 Sampled countries Initial period and survey Final period and survey Countries that use income-based poverty measures Argentina 2000 EPH-C 2010 EPH-C Brazil 2001 PNAD 2009 PNAD Chile 2000 CASEN 2009 CASEN Colombia 2002 GEIH 2010 GEIH Costa Rica 2000 EHPM 2008 EHPM Ecuador 2003 ENEMDU 2010 ENEMDU Honduras 1999 EPHPM 2009 EPHPM Panama 2001 EH 2009 EH Paraguay 1999 EPH 2010 EPH Countries that use consumption-based poverty measures Bangladesh 2000 HIES 2010 HIES Cambodia 2007 CSES 2010 CSES Ghana 1998 RIGA 2005 RIGA Moldova 2001 HBS 2010 HBS Mongolia 2007 HSES 2011 HSES Nepal 1996 RIGA 2003 RIGA Peru 2004 ENAHO 2010 ENAHO Romania 2001 HBS 2009 HBS Sri Lanka 2002 HIES 2009 HIES Thailand 2000 SES 2009 SES Philippines 2006 FIES 2009 FIES Vietnam 2004 VHLSS 2010 VHLSS Note: EPH-C = Encuesta Permanente de Hogares-Continua (Argentina); PNAD = Pesquisa Nacional por Amostra de Domicilios (Brazil); CASEN = Encuesta de Caracterización Socioeconómica Nacional (Chile); GEIH = Gran Encuesta Integrada de Hogares (Colombia); EHPM = Encuesta de Hogares de Propósitos Múltiples (Costa Rica); ENEMDU = Encuesta de Empleo, Desempleo y Subempleo (Ecuador); EPHPM = Encuesta Permanente de Hogares de Propósitos Múltiples (Honduras); EH = Encuesta de Hogares (Panama); EPH = Encuesta Permanente de Hogares (Paraguay); HIES = Household Income and Expenditure Survey (Bangladesh); CSES = Cambodia Socio-Economic Survey; RIGA = Rural Income Generating Activities (Nepal); HBS = Household Budget Survey (Romania); HSES = Household Socio-Economic Survey (Mongolia); ENAHO = Encuesta Nacional de Hogares (Peru); SES = Household Socio-Economic Survey (Thailand); FIES = Family Income and Expenditure Survey (Philippines); VHLSS = Vietnam Household Living Standards Survey. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Annex 3B: Complementary Tables Table 3B.1 Contributions to the Decline in the $1.25-a-Day (PPP) Poverty Headcount in Selected Developing Countries, 2000s Consumption-based measure of welfare Bangladesh, 1998–2005 1996–2003 Sri Lanka, Moldova, 2000–10 2002–09 2004–10 2001–10 Ghana, Nepal, Peru, Poverty headcount rate (FGT0)a Initial period (%) 57.7 14.8 38.2 73.7 3.5 27.5 Final period (%) 40.3 4.7 23.5 53.1 0.8 0.5 Total change (ppts) −17.4 −10.1 −14.7 −20.6 −2.6 −27.0 Decomposition of FGT0 a Consumption-to-income ratio (%) −25.6 −0.2 17.7 −6.9 −9.3 −20.2 Adult population (%) 37.2 19.5 21.4 14.2 −14.9 5.7 Occupation share (%) 20.5 −21.8 −3.6 13.4 −3.1 −1.9 Labor income (%) 60.2 62.9 49.6 50.4 115.7 27.7 Capital (%) 7.8 0.0 5.0 5.9 1.4 0.0 Pension (%) — 1.5 — — −4.7 35.8 Transfers (%) 15.7 −1.6 10.0 23.0 10.8 46.1 Other nonlabor income (%) −15.9 39.8 — — 4.1 6.7 Total change (%) 100.0 100.0 100.0 100.0 100.0 100.0 Decomposition in FGT1 b Consumption-to-income ratio (%) −60.6 −37.4 0.8 −10.7 −44.0 — Adult population (%) 47.2 24.7 28.0 12.4 −40.5 — Occupation share (%) 25.3 −76.3 −20.9 17.0 −12.5 — Labor income (%) 99.1 93.2 70.9 54.0 176.4 — Capital (%) 4.9 0.0 6.5 4.8 2.4 — Pension (%) — 2.7 — — −9.6 — Transfers (%) 16.7 −3.7 14.6 22.5 23.8 — Other nonlabor income (%) −32.6 96.8 — — 4.1 — Total change (%) 100.0 100.0 100.0 100.0 100.0 — Decomposition in FGT2 c Consumption-to-income ratio (%) −107.9 −112.6 −20.7 −17.8 −86.2 — Adult population (%) 59.8 36.9 36.6 10.3 −64.7 — Occupation share (%) 30.4 −181.4 −40.2 17.9 −27.7 — Labor income (%) 151.8 128.1 98.4 60.2 234.1 — Capital (%) 1.5 0.0 6.0 4.7 4.4 — Pension (%) — 6.6 — — −14.7 — Transfers (%) 20.0 −3.2 19.9 24.7 53.5 — Other nonlabor income (%) −55.7 225.7 — — 1.2 — Total change (%) 100.0 100.0 100.0 100.0 100.0 — Sources: Data on Ghana and Nepal from FAO n.d. Data on Bangladesh, Moldova, Peru, Romania, Sri Lanka, and Thailand from household surveys. Latin American data from SEDLAC, various years. Data on Cambodia, Mongolia, the Philippines, and Vietnam from World Bank harmonized surveys for the East Asia and Pacific region. Note: ppts = percentage points; PPP = purchasing power parity; — = not available; n.a. = not applicable. a. FGT0 refers to the Foster, Greer, and Thorbecke (1984) measure of the poverty headcount index, which measures the proportion of the population that is counted as poor using the $1.25-a-day standard. b. FGT1 refers to the measure of the poverty gap index, which adds up the extent to which individuals on average fall below the poverty line, expressed as a percentage of the poverty line (Foster, Greer, and Thorbecke 1984). c. FGT2 refers to the measure of poverty severity, calculated as the poverty gap index squared, which implicitly puts more weight on observations that fall well below the poverty line (Foster, Greer, and Thorbecke 1984). 60 Income-based measure of welfare Philippines, 1999–2009 1999–2010 Cambodia, Costa Rica, Argentina, Honduras, Colombia, Mongolia, Paraguay, Panama, Vietnam, Ecuador, 2000–10 2001–09 2002–10 2000–08 2003–10 2001–09 2007–10 2007–11 2006–09 2004–10 Brazil, 5.1 11.8 20.7 5.5 12.2 24.9 15.4 14.0 34.0 13.1 31.7 18.1 1.8 6.1 8.2 2.4 4.6 17.8 4.6 7.2 29.6 6.0 27.6 8.7 −3.3 −5.7 −12.6 −3.1 −7.6 −7.1 −10.8 −9.3 −4.4 −7.1 −4.1 −9.4 n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. 20.0 11.2 5.2 7.1 19.0 41.4 4.0 34.7 34.9 −1.0 47.6 15.6 −5.7 −3.7 8.7 −2.8 −15.3 3.5 14.1 6.4 33.3 −18.2 −0.9 −4.3 14.3 44.7 48.7 26.7 50.3 51.5 39.9 47.8 46.4 62.6 23.2 75.4 −19.7 −4.4 0.4 10.7 −1.7 7.7 0.5 −1.3 — — — — 29.2 6.2 −2.2 61.3 5.2 6.7 10.4 −1.4 −5.2 3.2 2.2 2.9 37.7 37.3 31.0 55.2 36.0 −20.8 31.8 9.8 −8.1 52.2 27.6 8.0 24.2 8.8 8.2 −58.2 6.5 10.0 −0.7 3.9 −1.5 1.2 0.2 2.1 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. 16.5 7.9 −1.5 −2.0 13.3 52.6 2.3 30.8 16.0 −7.7 44.2 8.5 −7.9 −11.4 5.2 −23.2 −20.2 1.0 8.0 3.3 23.4 −14.0 −5.3 1.9 8.4 28.1 51.0 6.6 41.6 41.9 42.4 43.9 74.9 58.6 23.0 39.0 −26.9 −9.0 −3.3 24.0 −4.4 15.9 −0.8 −0.8 — — — — 24.5 0.6 −6.7 130.3 5.0 16.6 10.9 −0.4 −3.4 2.9 2.8 34.2 54.5 68.1 45.6 114.4 55.0 −42.7 42.0 17.6 −8.5 59.6 33.5 12.0 31.0 15.6 9.7 −150.1 9.7 14.7 −4.8 5.7 −2.4 0.6 1.8 4.4 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. 11.8 6.0 −4.4 −7.4 9.3 78.6 0.7 30.7 10.7 −12.1 39.7 −112.6 −7.2 −14.4 3.0 −39.8 −23.1 −9.6 3.8 −0.5 19.1 −10.3 −7.1 278.4 6.5 14.2 49.5 −12.8 35.0 21.6 42.4 39.1 82.3 52.6 20.6 −696.3 −30.4 −11.2 −5.1 35.5 −7.0 32.2 −1.4 0.3 — — — — 20.0 −2.3 −8.9 188.3 5.0 33.7 11.7 −0.3 −3.1 3.0 3.2 543.6 66.0 88.2 54.4 166.9 68.3 −78.7 50.4 23.7 −7.4 66.7 39.3 60.1 33.2 19.5 11.4 −230.8 12.5 22.2 −7.7 7.0 −1.7 0.1 4.3 26.9 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 61 Table 3B.2 Contributions to the Decline in the $2.50-a-Day (PPP) Poverty Headcount in Selected Developing Countries, 2000s Consumption-based measure of welfare Bangladesh, 1998–2005 1996–2003 Romania, Sri Lanka, Thailand, Moldova, 2000–10 2002–09 2004–10 2000–09 2001–10 2001–09 Ghana, Nepal, Peru, Poverty headcount rate (FGT0)a Initial period (%) 89.2 61.9 71.8 94.3 22.9 7.9 71.4 23.7 Final period (%) 84.0 45.1 58.3 84.9 11.7 2.5 12.9 4.2 Total change (ppts) −5.2 −16.8 −13.5 −9.5 −11.2 −5.3 −58.5 −19.5 Decomposition of FGT0 a Consumption-to-income ratio (%) −56.1 7.4 18.5 −30.9 4.8 −47.0 −2.9 15.3 Adult population (%) 46.4 14.5 21.1 18.7 7.4 35.8 7.2 48.4 Occupation share (%) 23.3 −7.7 −0.9 6.2 5.6 −10.1 6.6 24.8 Labor income (%) 85.6 51.1 52.2 62.3 70.1 61.0 26.2 −33.0 Capital (%) 5.3 0.0 1.6 9.7 1.5 5.9 0.4 38.3 Pension (%) — 1.9 — — −0.4 — 25.5 −20.2 Transfers (%) 24.8 2.0 7.3 34.0 10.0 57.8 30.1 16.2 Other nonlabor income (%) −29.3 30.9 — — 1.0 −3.4 7.0 10.2 Total change (%) 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 Decomposition in FGT1b Consumption-to-income ratio (%) −46.3 3.4 14.0 −14.0 0.3 −131.5 −15.9 51.3 Adult population (%) 43.9 17.6 22.7 14.9 −0.1 58.2 4.9 138.0 Occupation share (%) 22.4 −14.6 −6.1 13.5 1.8 −39.8 6.0 70.9 Labor income (%) 81.4 54.3 55.1 53.8 85.8 67.8 22.9 −154.8 Capital (%) 6.2 0.0 4.3 6.5 1.4 13.6 0.2 117.1 Pension (%) — 1.7 — — −2.0 — 29.5 −120.9 Transfers (%) 17.9 0.5 10.0 25.3 10.9 126.7 46.8 14.8 Other nonlabor income (%) −25.6 37.0 — — 1.8 5.0 5.6 −16.4 Total change (%) 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 Decomposition in FGT2c Consumption-to-income ratio (%) −54.5 −4.2 8.2 −12.7 −7.4 −264.8 −31.2 148.6 Adult population (%) 45.8 19.3 25.0 13.4 −8.2 95.2 2.8 320.2 Occupation share (%) 23.9 −26.2 −12.1 15.3 −1.5 −95.6 5.3 175.7 Labor income (%) 91.6 61.0 61.8 54.3 103.2 49.5 16.2 −387.5 Capital (%) 5.5 0.0 5.1 5.6 1.6 28.1 −0.2 280.8 Pension (%) — 1.9 — — −3.4 — 32.7 −336.5 Transfers (%) 17.4 −0.3 12.0 24.0 13.3 253.4 70.1 −14.5 Other nonlabor income (%) −29.6 48.5 — — 2.4 34.3 4.3 −86.7 Total change (%) 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 Sources: Data on Ghana and Nepal from FAO n.d. Data on Bangladesh, Moldova, Peru, Romania, Sri Lanka, and Thailand from household surveys. Latin American data from SEDLAC, various years. Data on Cambodia, Mongolia, the Philippines, and Vietnam from World Bank harmonized surveys for the East Asia and Pacific region. Note: ppts = percentage points; PPP = purchasing power parity; — = not available; n.a. = not applicable. a. FGT0 refers to the Foster, Greer, and Thorbecke (1984) measure of the headcount index, which measures the proportion of the population that is counted as poor using the $2.50-a-day standard. b. FGT1 refers to the measure of the poverty gap index, which adds up the extent to which individuals on average fall below the poverty line, and expresses it as a percentage of the poverty line (Foster, Greer, and Thorbecke 1984). c. FGT2 refers to the measure of poverty severity, calculated as the poverty gap index squared, which implicitly puts more weight on observations that fall well below the poverty line (Foster, Greer, and Thorbecke 1984). 62 Income-based measure of welfare Philippines, 1999–2009 1999–2010 Cambodia, Costa Rica, Argentina, Honduras, Colombia, Mongolia, Paraguay, Panama, Vietnam, Ecuador, 2000–10 2001–09 2000–09 2002–10 2000–08 2003–10 2001–09 2007–10 2007–11 2006–09 2004–10 Brazil, Chile, 14.2 27.4 9.0 42.3 14.7 31.5 47.9 28.7 26.7 57.3 35.7 62.2 56.4 6.4 15.1 4.3 22.0 7.6 15.9 36.2 16.1 18.4 60.1 22.5 60.3 33.2 −7.8 −12.3 −4.7 −20.3 −7.1 −15.6 −11.6 −12.6 −8.3 2.8 −13.2 −1.9 −23.2 n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. 20.6 16.5 31.9 10.5 25.3 24.5 37.4 9.2 56.8 53.0 5.4 71.2 16.0 10.4 6.9 −18.4 14.0 9.3 −6.0 −3.1 22.5 6.5 29.0 −22.0 −18.8 3.0 29.5 44.8 46.9 40.7 24.5 53.2 57.8 33.5 43.8 −162.6 75.0 8.1 68.6 −9.1 −1.1 −11.3 3.0 4.7 −1.1 3.8 0.0 −2.4 — — — — 19.9 10.7 31.9 2.7 31.5 4.7 3.7 9.8 −3.8 1.8 3.3 2.7 4.3 16.1 16.7 87.4 20.1 28.3 20.2 −6.9 24.5 −0.5 −18.6 36.4 40.7 5.2 12.7 5.4 −68.4 9.0 −23.6 4.5 7.2 0.5 −0.4 −2.6 1.9 −4.0 2.9 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 −100.0 100.0 100.0 100.0 n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. 18.7 12.7 42.6 5.4 15.1 21.5 43.8 5.3 41.0 54.1 0.9 49.1 14.8 1.1 0.4 −50.2 9.5 −0.8 −12.2 −1.5 14.5 6.7 47.6 −18.3 −5.3 0.2 20.9 41.7 17.2 45.9 20.2 50.3 54.3 38.4 44.3 24.9 67.4 21.4 66.7 −15.6 −3.4 −32.2 0.4 10.1 −2.2 7.4 −0.2 −1.5 — — — — 23.6 7.3 72.1 −1.4 61.5 4.7 7.4 10.3 −1.5 −4.5 3.5 2.9 8.0 31.4 32.8 191.6 31.2 53.0 32.0 −20.8 33.3 8.1 −16.9 45.0 32.1 7.4 19.8 8.5 −141.1 9.2 −59.1 6.0 9.3 −1.6 2.9 −5.2 1.5 −0.1 2.8 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. 17.2 10.4 64.2 1.8 7.8 18.1 48.9 3.5 35.7 27.1 −2.6 45.6 8.0 −3.3 −4.5 −95.7 7.0 −10.5 −15.9 −0.9 10.7 5.0 27.8 −16.8 −4.7 12.7 15.0 35.9 −26.9 48.3 14.3 46.8 48.5 40.4 43.8 62.1 63.8 22.1 27.7 −20.9 −5.7 −65.9 −1.5 16.0 −3.2 11.7 −0.5 −1.1 — — — — 24.1 4.4 129.3 −4.2 91.3 4.8 11.8 10.7 −1.0 −3.7 3.2 2.9 36.7 43.0 48.0 348.1 39.1 79.6 41.9 −31.7 38.7 13.1 −10.1 51.2 32.8 10.8 24.9 11.4 −253.2 9.6 −98.5 7.5 11.7 −3.5 4.4 −3.1 1.2 1.2 4.1 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 63 64 Table 3B.3 Contributions to the Decline in the $4.00–$5.00-a-Day (PPP) Poverty Headcount in Selected Developing Countries, 2000s Consumption-based measure of welfare Income-based measure of welfare $4.00-a-day poverty line $5.00-a-day poverty line $4.00-a-day poverty line Costa Paraguay, Peru, Sri Lanka, Thailand, Moldova, Romania, Argentina, Brazil, Chile, Colombia, Rica, Ecuador, Honduras, Panama, 1999– 2004–10 2002–09 2000–09 2001–10 2001–09 2000–10 2001–09 2000–09 2002–10 2000–08 2003–10 1999–2009 2001–09 2010 Poverty headcount rate (FGT0) Initial period (%) 45.8 84.7 31.4 93.8 75.3 27.5 43.1 23.2 61.6 29.2 51.5 66.1 43.4 50.3 Final period (%) 30.0 78.1 16.6 58.7 33.2 14.6 27.6 11.8 39.5 18.9 33.4 52.1 29.9 33.0 Total change (ppts) −15.8 −6.6 −14.8 −35.1 −42.2 −13.0 −15.5 −11.4 −22.1 −10.2 −18.1 −14.1 −13.5 −17.3 Decomposition of FGT0 a Consumption-to- income ratio (%) 5.1 −9.0 −11.8 −20.9 15.8 n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. Adult population (%) 9.0 9.7 24.2 3.5 24.1 22.0 16.4 31.0 12.1 34.4 27.1 32.0 13.5 59.5 Occupation share (%) 10.0 −24.3 4.0 6.5 20.4 16.7 10.9 −0.1 15.8 14.2 −3.3 −4.1 29.1 11.6 Labor income (%) 62.5 75.1 47.5 37.3 1.9 35.2 41.6 48.2 38.3 17.7 53.3 55.8 30.2 33.2 Capital (%) 2.1 0.0 2.8 0.6 21.0 −5.4 −0.7 −4.2 4.3 3.9 −0.7 3.8 −0.2 0.0 Pension (%) 0.6 4.3 — 25.1 −2.8 14.9 17.9 15.8 4.6 23.6 6.2 3.2 10.4 −3.0 Transfers (%) 10.0 6.5 33.1 37.2 8.7 7.3 9.1 41.8 15.6 22.4 13.6 3.4 16.4 −1.0 Other nonlabor income (%) 0.7 37.7 0.3 10.6 11.0 9.3 4.8 −32.5 9.4 −16.1 3.8 6.0 0.5 −0.3 Total change (%) 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 table continues next page Table 3B.3  Contributions to the Decline in the $4.00–$5.00-a-Day (PPP) Poverty Headcount in Selected Developing Countries, 2000s (continued) Consumption-based measure of welfare Income-based measure of welfare $4.00-a-day poverty line $5.00-a-day poverty line $4.00-a-day poverty line Costa Peru, Sri Lanka, Thailand, Moldova, Romania, Argentina, Brazil, Chile, Colombia, Rica, Ecuador, Honduras, Panama, Paraguay, 2004–10 2002–09 2000–09 2001–10 2001–09 2000–10 2001–09 2000–09 2002–10 2000–08 2003–10 1999–2009 2001–09 1999–2010 Decomposition in FGT1 b Consumption-to-​ ­ncome ratio (%) i 3.4 2.8 −35.9 −10.8 20.0 n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. Adult population (%) 5.9 15.0 31.8 5.6 44.0 20.5 14.8 33.9 8.7 25.8 24.2 38.0 8.0 49.8 Occupation share (%) 6.0 −14.3 −5.8 6.6 27.0 9.3 5.5 −15.8 12.3 7.9 −7.7 −2.1 19.9 8.1 Labor income (%) 72.3 56.9 53.7 27.5 −25.6 28.3 42.4 41.7 42.2 19.2 52.1 55.6 35.2 41.2 Capital (%) 1.7 0.0 4.9 0.3 36.5 −9.9 −2.0 −11.9 2.1 6.5 −1.5 5.2 −0.1 −1.3 Pension (%) −0.5 2.3 — 26.5 −20.7 19.2 11.7 31.6 1.4 40.1 5.1 5.1 10.3 −2.6 Transfers (%) 10.1 2.1 51.5 36.9 11.7 18.4 20.9 85.7 24.0 35.6 22.9 −9.5 27.3 3.8 Other nonlabor income (%) 1.2 35.1 −0.2 7.5 7.1 14.3 6.8 −65.1 9.3 −35.0 5.0 7.7 −0.7 1.1 Total change (%) 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 Decomposition in FGT2 c Consumption-to-​ ­ncome ratio (%) i 0.9 1.9 −68.4 −13.0 30.5 n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. Adult population (%) 2.1 16.8 41.1 5.4 72.8 19.1 13.2 39.5 5.9 18.6 22.0 42.3 5.8 43.3 Occupation share (%) 3.6 −16.5 −18.2 6.3 40.6 4.0 1.6 −34.3 10.0 1.5 −10.9 −1.6 15.4 6.6 Labor income (%) 80.8 56.4 57.1 24.6 −64.3 23.1 40.9 28.2 44.9 18.6 50.4 53.7 37.8 43.1 Capital (%) 1.6 0.0 8.1 0.2 61.1 −14.1 −3.3 −23.3 0.6 9.5 −2.1 7.3 −0.2 −1.3 Pension (%) −1.4 2.0 — 27.8 −51.5 21.7 8.5 53.2 −1.0 57.1 4.8 7.3 10.4 −1.9 Transfers (%) 10.8 1.1 78.0 42.3 11.6 27.8 30.7 143.6 30.2 49.8 29.9 −18.1 32.7 7.6 Other nonlabor income (%) 1.6 38.3 2.4 6.5 −0.8 18.3 8.3 −106.9 9.4 −55.2 5.9 9.1 −1.8 2.5 Total change (%) 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 100.0 Sources: Data on Ghana and Nepal from FAO n.d. Data on Bangladesh, Moldova, Peru, Romania, Sri Lanka, and Thailand from household surveys. Latin American data from SEDLAC, various years. Data on Cambodia, Mongolia, the Philippines, and Vietnam from World Bank harmonized surveys for the East Asia and Pacific region. Note: ppts = percentage points; PPP = purchasing power parity; — = not available; n.a. = not applicable. a. FGT0 refers to the Foster, Greer, and Thorbecke (1984) measure of the headcount index, which measures the proportion of the population that is counted as poor. b. FGT1 refers to the measure of the poverty gap index, which adds up the extent to which individuals on average fall below the poverty line and expresses it as a percentage of the poverty line (Foster, Greer, and Thorbecke 1984). 65 c. FGT2 refers to the measure of poverty severity, calculated as the poverty gap index squared, which implicitly puts more weight on observations that fall well below the poverty line (Foster, Greer, and Thorbecke 1984). 66 What Accounts for Changes in Poverty over the Past Decade? Notes 1. SEDLAC is a joint effort of the Centro de Estudios Distributivos Laborales y Sociales (CEDLAS) of the Universidad Nacional de La Plata in Buenos Aires and the World Bank’s Latin American Poverty and Gender Group. For more information about SEDLAC, see its website: http://sedlac.econo.unlp.edu.ar/eng/. 2. For more information about RIGA, see its page on the FAO website: http://www.fao​ .org/economic/riga/riga-database/en/. 3. For a more comprehensive treatment of how global poverty measures have developed historically, see Chen and Ravallion (2010). The World Bank’s interactive website, PovcalNet (developed by the Bank’s Development Research Group), also allows users to replicate calculations made by World Bank researchers to estimate the extent of absolute poverty in the world as well as “to calculate poverty measures under different assumptions” (PovcalNet online poverty analysis tool, http://iresearch.worldbank​ .org​ /PovcalNet/index.htm). 4. Note that the consumption-to-income ratio is the ratio of measured consumption to measured income. To the extent that there is measurement error in both of these, interpretations about changes in this ratio must be treated with caution. 5. FGT1 refers to the Foster, Greer, and Thorbecke (1984) measure of the poverty gap index, which adds up the extent to which individuals on average fall below the poverty line, and expresses it as a percentage of the poverty line. ­ 6. FGT2 refers to the Foster, Greer, and Thorbecke (1984) measure of poverty severity, calculated as the poverty gap index squared, which implicitly puts more weight on observations that fall well below the poverty line. 7. We do not report decompositions for Chile and Thailand using the $1.25-a-day poverty line because only 1 percent or less of the population in those countries ­ experiences poverty at that level. ­ 8. Also, see Fiszbein et al. (2009) for a review of conditional cash transfer programs. Bibliography Bourguignon, François, Francisco H. G. Ferreira, and Nora Lustig, eds. 2005. The Microeconomics of Income Distribution Dynamics in East Asia and Latin America. Washington, DC: World Bank. Bourguignon François, Francisco H. G. Ferreira., and Phillippe G. Leite 2008. “Beyond Oaxaca-Blinder: Accounting for Differences in Household Income Distributions.” Journal of Economic Inequality 6 (2): 117–48. Chen, Shaohua and Martin Ravallion. 2010. “The Developing World Is Poorer Than We Thought, but No Less Successful in the Fight Against Poverty.” Quarterly Journal of Economics 125 (4): 1577–625. Datt, Gaurav, and Martin Ravallion. 1992. “Growth and Redistribution Components of Changes in Poverty Measures: A Decomposition with Applications to Brazil and India in the 1980s.” Journal of Development Economics 38: 275–96. FAO (Food and Agriculture Organization of the United Nations). n.d. Rural Income Generating Activities (RIGA). Database, FAO, Rome; World Bank and American University, Washington, DC, http://www.fao.org/economic/riga/riga-database/en/. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 What Accounts for Changes in Poverty over the Past Decade? 67 Ferreira, Francisco H. G. 2012. “Distributions in Motion: Economic Growth, Inequality, and Poverty Dynamics.” In The Oxford Handbook of the Economics of Poverty, edited by Philip N. Jefferson, 427–62. New York: Oxford University Press. Fiszbein, Ariel, Norbert Schady, Francisco H. G. Ferreira, Margaret Grosh, Pedro Olinto, and E. Skoufias. 2009. Conditional Cash Transfers: Reducing Present and Future Poverty. Washington, DC: World Bank. Foster, James, Joel Greer, and Erik Thorbecke. 1984. “A Class of Decomposable Poverty Measures.” Econometrica 52 (3): 761–65. Juhn, Chinhui, Kevin M. Murphy, and Brooks Pierce. 1993. “Wage Inequality and the Rise of Returns to Skill.” Journal of Political Economy 101 (3): 410–42. Ravallion, Martin, and Shaohua Chen. 2007. “China’s (Uneven) Progress against Poverty.” Journal of Development Economics 82 (1): 1–42. SEDLAC (Socio-Economic Database for Latin America and the Caribbean). Various years. Statistical database produced by CEDLAS (Center for Distributional, Labor and Social Studies) of the Universidad Nacional de la Plata, Buenos Aires; and World Bank, Washington, DC. http://sedlac.econo.unlp.edu.ar/eng/. Shapley, Lloyd. 1953. “A Value for n-Person Games.” In Contributions to the Theory of Games, Vol. 2, edited by H. W. Kuhn and A. W. Tucker, 307–17. Princeton, NJ: Princeton University Press. Shorrocks, Anthony F. 1999. “Decomposition Procedures for Distributional Analysis: A Unified Framework Based on Shapley Value.” Unpublished manuscript, University of Essex and Institute for Fiscal Studies. World Bank. 2005. World Development Report 2006: Equity and Development. Washington, DC: World Bank and Oxford University Press. ———. 2012. World Development Indicators 2012. Washington, DC: World Bank. http:// data.worldbank.org/data-catalog/world-development-indicators. Online database. ———. 2013. World Development Indicators 2013. Washington, DC: World Bank. http:// data.worldbank.org/data-catalog/world-development-indicators. Online database. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Chapter 4 Counterfactual Decomposition of Changes in Poverty Outcomes Introduction This chapter reviews decomposition methods commonly used to identify key factors that drive changes in the observed poverty outcomes. The review focuses on a variety of microeconometric methods and delves into the identification strategy underlying each of these methods. Macro-decomposition methods, such as those discussed in chapter 2, explain changes in poverty in terms of changes in aggregate statistics (such as the mean), relative inequality, subgroup popula- tion shares, and within-group poverty. The usefulness of such macro methods in policy making is severely limited because these methods identify determining factors that are hard to target with policy instruments. Ravallion (2001) explains that a better understanding of the heterogeneity of policy impact requires a deeper empirical analysis of distribu- tional change at the micro level. Micro-decomposition methods thus go beyond the summary statistics that are the focus of macro methods and attempt to link distributional changes to fundamental elements that drive these changes, such as individual or household characteristics that facilitate policy targeting. The logic underpinning all these methods (including the macro ones discussed in chapter 2) can be organized around the following terms: • Domain: the distributional change a method seeks to decompose on the basis of a model that links the outcome of interest to its determining factors. • Outcome model: the assumed relationship between the outcome of interest and its determining factors, the specification of which determines the potential scope of the decomposition. • Scope: the set of explanatory factors that decomposition methods seek to identify. This chapter adapts a previous work by the same author (Essama-Nssah 2012). Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7   69   70 Counterfactual Decomposition of Changes in Poverty Outcomes • Identification: the assumptions needed to recover, in a meaningful way, the terms of the decomposition that affect the outcome. • Estimation: the computation of the relevant parameters on the basis of sample data. The point of departure for micro-decomposition methods is the fact that a poverty measure is a functional1 of a distribution of living standards. An individual’s living standard is an outcome of interaction between opportunities ­ offered by society and the individual’s ability to identify and exploit such ­ opportunities. In other words, an individual’s living standard is a payoff from participation in the life of society. One can thus think of life in society as a game defined by a set of rules govern- ing various interactions of the parties involved (players). These rules spell out what the concerned parties are allowed to do and how these allowable actions determine outcomes. An environment within which a game is played consists of three basic elements: a set of potential participants, a set of possible outcomes, and a set of possible participant types (players). Player types are characterized by their preferences, capabilities, information, and beliefs (Milgrom 2004). The operation of a game can be represented by a function that maps environments to potential outcomes. Thus an individual payoff is a function of participation and type. This paradigm leads us to consider an individual’s living standard to be a func- tion of endowments, behavior, and the circumstances that determine the returns to these endowments from any social transaction. These elements span the scope of most micro-decomposition methods and represent some of the deep structural drivers of the distributional changes underlying the observed variations in ­poverty outcomes. Although macro- and micro-decomposition methods differ in their scope, they share the same fundamental identification strategy based on the notion of ceteris paribus variation. Attribution of outcomes to policy is the hallmark of policy impact evaluation. Variations in individual outcomes associated with a policy’s implementation are not necessarily the result of the policy in question. These variations could be driven by changes in confounding factors in the socio- economic environment. At the most fundamental level, all identification strate- gies seek to isolate an independent source of variation in policy and link it to the outcome of interest to ascertain impact. Similarly, macro- and micro-decomposition methods also identify the deter- minants of differences across living-standard distributions by comparing counter- factual distributions with the observed ones. Counterfactual distributions are obtained by changing one determining factor at a time while holding all the other factors fixed (a straight application of ceteris paribus identification strategy). The linchpin of the whole process is the estimation of credible counterfactu- als. In the context of micro-decomposition methods, for instance, one must carefully estimate a key counterfactual: the distribution of outcomes in the base ­ state (t = 0) assuming the distribution of individual characteristics prevailing in the end state (t = 1). Put another way, such a counterfactual represents the Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 71 distribution of outcomes that would prevail in the end state if the characteristics in that state had been treated according to the outcome structure prevailing in initial state. Depending on the chosen functional form for the outcome equation, there are both parametric and nonparametric ways of estimating this counterfactual. The rest of the chapter is divided into three sections. The next section reviews methods to identify and estimate the composition (or endowment) effect and structural (or price) effect associated with variation in a general distributional statistic. Both aggregate and detailed decompositions are considered. This is fol- lowed by a section that focuses on proposed methods to account for behavioral responses to changes in the socioeconomic environment. These methods rely on the specification and estimation of a microeconometric model based on some theory of individual (or household) behavior and social interaction. The final section summarizes the chapter’s findings. As the chapter proceeds, the methods first reviewed are considered statistical, while those covered in the later section accounting for behavioral responses are structural in nature. One particular advantage of the statistical approach is that it gives the analyst semi- and nonparametric ways to identify the aggregate effects without having to impose a functional form on the relationship between the outcome and its determinants. However, the statistical framework cannot shed light on the mechanism underlying that relationship. The decomposition results therefore lack any causal interpretation. Because these methods are based on statistical models of conditional distributions, it is conceivable that the behav- ioral effect is mixed up with the price effect identified by these methods. Structural methods go a step further toward identifying factors associated with structural elements underpinning the observed changes in poverty outcomes. Both the statistical and structural approaches seek to model conditional outcome distributions. A key distinction between the two approaches is that the former relies entirely on statistics while the latter combines economics and statistics. The Composition and Structural Effects As noted earlier, an individual’s living standard is an outcome of participation in the life of society. This outcome is a function of the individual’s endowments, behavior, and the circumstances that determine the returns to these endowments from any socioeconomic transaction. In this section, we focus on the role of endowments and the returns to those endowments in driving the distributional changes2 that underlie changes in poverty outcomes. We consider changes in both distributional statistics and entire distributions. We also discuss the contri- bution of unobservable characteristics. All methods reviewed in this section are consistent with the logic of the basic Oaxaca-Blinder decomposition (Blinder 1973; Oaxaca 1973). The methods differ mainly in the ability to account for (a) heterogeneity in the composition ­ and structural effects along the entire outcome distribution and (b) the contribu- tion of observable or unobservable characteristics to both types of effects. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 72 Counterfactual Decomposition of Changes in Poverty Outcomes In particular, using a linear regression model to link the outcome variable to individual or household characteristics allows one to perform both aggregate and detailed decompositions of changes in distributional statistics. Decomposing ­ differences in density functions or across quantiles reveals how the composition and structural effects vary along the outcome distribution. Under some speci- fications of the outcome model (Juhn, Murphy, and Pierce 1993), it is possible to explicitly account for the contribution of unobservables to the structural effect. Finally, it is important to keep in mind the analogy between the Oaxaca- Blinder decomposition and treatment effect analysis. This analogy underlies the development of flexible methods for estimating the endowment and structural effects. Changes in Distributional Statistics In the context of assessing variations in individual and social outcomes, the com- position or endowment effect indicates the change in outcome that is due only to changes in the distribution of observable characteristics of agents. The struc- tural or price effect is the result of changes in the returns to those characteristics. Although we focus on changes in poverty outcomes, it is instructive to consider the more general approach that applies to all distributional statistics, including poverty and inequality measures. We frame the analysis of the underlying distributional changes within the logic of the standard Oaxaca-Blinder decomposition based on an outcome model that considers both individual and social outcomes (Blinder 1973; Oaxaca 1973). We discuss, in turn, the outcome model, the identification, and the estimation of the relevant effects. Our presentation relies heavily on Fortin, Lemieux, and Firpo (2011). Outcome Model Let q stand for the social outcome of interest. This is a distributional statistic that we view as a functional of the distribution of individual outcomes, Fy. As noted above, an individual outcome y is a function of endowments, behavior, and returns to endowments. We are interested in decomposing a change in the social out- come from the base period t = 0 to the end period t = 1. Let Fy0 |t = 0 stand for the outcome distribution observed in the initial period and Fy1|t = 1 for that observed in the final period. We can express distributional change between states 0 and 1 by the following variation in q (Fy): O = q ( Fy1|t = 1 ) − q ( Fy0 |t = 0 ) . (4.1) ∆q Equation (4.1) characterizes the domain of the decomposition methods con- sidered in this chapter. As far as the scope is concerned, most micro-decomposition­ methods seek to decompose this overall difference on the basis of the relation- ship between the outcome variable and individual or household characteristics. The following equation represents a general expression of that relationship: yt = jt (xt, et), t = 0,1. (4.2) Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 73 Equation (4.2) suggests that conditional on the observable characteristics, x, the outcome distribution depends only on the function jt(∙) and the distribution of the unobservable characteristics e. Thus there are four potential terms in the scope of micro-decomposition methods based on this model. Differences in out- come distributions between the two periods may be the result of (a) differences in the returns to observable characteristics given the functions defining the out- come structure; (b) differences in the returns to unobservable characteristics also defined by the structural functions; (c) differences in the distribution of observ- able characteristics; and (d) differences in the distribution of unobservable characteristics. The classic Oaxaca-Blinder method seeks to decompose the overall difference in unconditional mean outcome between two groups or time periods. In this case, q (Fy) = m(Fy) = E(y). The overall difference in the mean outcome between the µ two periods can therefore be written as ∆O = [E( y1 ) − E(y 0 )]. This framework assumes an additive linear relationship between the outcome variable y and its determinants. The equivalent of equation (4.2) can therefore be written as yt = xt bt + ¨t; t = 0, 1. Identification Given the potential scope implied by the outcome model (equation [4.2]), the next step is to impose enough restrictions to identify the factors of interest. In general, these restrictions are imposed on the form of the outcome functions, jt(∙), and on the joint distribution of the observable and unobservable character- istics, x and e. On the basis of the general outcome model represented by the definition of the distributional statistic q, along with equation (4.2), it is impos- sible to distinguish the contribution of the returns to observables from that of unobservables. These two terms can therefore be lumped into a single term: the structural effect, also called the price effect, noted ∆q q S. Let ∆ X stand for the com- position effect and ∆q ε for the effect associated with differences in the distribution of unobservables. The issue now is to identify these three effects so that they account for the overall difference described by equation (4.1). Just as in the case of the size and redistribution effects discussed in chapter 2, we rely on counterfactual decomposition to identify the composition and struc- tural effects. Let y0|t = 1 be the outcomes that would have prevailed in period 1 if individual characteristics in that period had been rewarded according to the reward regime prevailing in period 0, that is, according to ϕ0(∙). Let Fy0 |t = 1 stand for the corresponding distribution and q ( Fy0 |t = 1 ) for the corresponding value of the statistic of interest. By definition, the composition effect is given by the q ( Fy0 |t = 1 ) − q ( Fy0 |t = 0 )  . X =  ­ ollowing expression: ∆q f  This term is meaningful and identifiable only if it emerges from a ceteris ­ aribus variation of the distribution of observable characteristics. Given the scope p of the decomposition implied by the underlying outcome model and the fact that we are lumping together the returns to both observables and unobservables, we must restrict movements in the conditional distribution of unobservable characteristics (given observables) and the structure of individual outcomes. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 74 Counterfactual Decomposition of Changes in Poverty Outcomes We therefore assume that the conditional distribution of unobservables is the same in both states of the world. This is the so-called ignorability assumption usually made in the context of observational studies of treatment effect. We further assume that the outcome structure, ϕ(  ), remains stable as we adjust the distribution of observables to obtain the relevant counterfactual out- come. This assumption is sometimes referred to as simple treatment assumption or the assumption of no general equilibrium effects. Ignorability implies that ∆q ε = 0. Combining the assumption of ignorability with that of no general equilibrium effects secures the identification of both the composition and structural effects. S = q ( Fy1|t = 1 ) − q ( Fy0 |t = 1 )  . The overall The structural effect is identified by ∆q  ­ ifference in equation (4.1) can therefore be expressed as d q ( Fy0 |t = 1 ) − q ( Fy0 |t = 0 )  + q ( Fy1|t = 1 ) − q ( Fy0 |t = 1 )  ,(4.3) O =  ∆q    where the first term on the right-hand side is the endowment effect and the second is the structural effect. In the context of poverty analysis, if P stands for the poverty measure of interest, then equation (4.3) implies that observed changes in poverty can be decomposed as follows:  P ( Fy0 |t = 1 ) − P ( Fy0 |t = 0 )  +  P ( Fy1|t = 1 ) − P ( Fy0 |t = 1 )  .(4.4) = P ∆O    In addition to assuming a linear model for the individual outcome, the classic Oaxaca-Blinder decomposition assumes that the conditional mean of ε given the observables is equal to zero. This assumption, which is stronger than ignorability, implies that the conditional mean outcome can be written as follows: E(y|x) = xb. Therefore b is a measure of the effect of x on the conditional mean outcome. By the law of iterated expectations, we know that the unconditional mean outcome is E(y) = Ex[E(y|x)] = E(x)b. This result means that b also measures the effect of changing the mean value of x on the unconditional mean value of y. This is the interpretation underlying the original Oaxaca-Blinder decomposition. The domain of the standard Oaxaca-Blinder decomposition can therefore be  E ( x1 ) β1 − E ( x 0 ) β0  µ written as ∆O = . This overall difference in means is subject to counterfactual decomposition as follows: The average outcome for period 1 valued on the basis of the reward parameters for period 0 is equal to E(x1)b0. This is a counterfactual outcome for period 1. We can subtract it from, and add it back to, the above overall mean difference to get the following expression:  E ( x1 ) − E ( x 0 )   E ( x1 )( β1 − β0 ) µ ∆O =  β0 +  3 . Looking at the regression ­coefficients b as characterizing the returns to (or reward for) observable characteristics, this aggregate decomposition reveals that under the identifying assumptions, the overall µ µ mean difference can be expressed as ∆O = ∆µ µ X + ∆ S , where ∆ X is the composition µ (endowment) effect, and ∆ S is the structural (price) effect. Estimation Parametric and Nonparametric Approaches. There are both parametric and non- parametric approaches to estimating the counterfactuals involved in the Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 75 identification and hence estimation of the composition and structural effects. DiNardo, Fortin, and Lemieux (1996) show that the counterfactual distribution, Fy0 |t = 1, can be estimated by properly reweighing the distribution of covariates in period 0. One can express the resulting counterfactual distribution as follows:4 Fy0 |t = 1 ( y ) = ∫F y0 | x 0 ( y|x ) w ( x ) dFx ( x ) , (4.5) 0 dFx1 ( x ) P(t = 1| x ) 1 − π where the reweighing factor is equal to w ( x ) = = ⋅ . dFx0 ( x ) 1 − P(t = 1| x ) π These weights are proportional to the conditional odds of being observed in state 1. The proportionality factor depends on π, which is the proportion of cases observed in state 1. One can easily compute the reweighing factor on the basis of a probability model, such as logit or probit. Furthermore, if one is inter- ested only in the aggregate decomposition of the variation in a distributional statistic, then the only needs are an estimate of the relevant counterfactual dis- tribution and the corresponding value of the statistic in question. The decomposition presented in equation (4.3) suggests a nonparametric identification strategy and can be estimated by the inverse probability weighting (IPW) method implied by equation (4.5). Nonparametric methods allow ana- lysts to decompose changes in distributional statistics into endowment and struc- tural effects without having to assume a functional form for the outcome model. The downside is that one cannot separate the respective contributions of the observable and unobservable factors into the structural effect, nor can one account for changes in agents’ behavior. Later on, we consider a way of separating the contribution of unobservables from that of observables, and in the concluding section we review proposed methods to account for behavioral responses. A parametric approach to the estimation of the composition and structural effect requires a more explicit link between the distributional statistic of interest and individual or household characteristics (depending on the unit of analysis). This approach entails imposing more structure on the individual outcome equa- tion (4.2) and finding a way of expressing the distributional statistic, q, as an explicit function of the covariates of interest. Given the assumption that the function ϕ(∙) in equation (4.2) is linear and separable in observable covariates x and unobservable factors ε, the classic Oaxaca-Blinder decomposition relies on the law of iterated expectations to establish a direct link between the uncondi- tional mean of y (the distributional statistic of interest) and individual character- istics. The assumption that the conditional mean of the error term given the observables is zero ensures that the ordinary least squares (OLS) method of estimation will produce unbiased and consistent estimates of key parameters. Use of Influence Functions. Things are not so simple for general distributional statistics such as quantiles, poverty, and inequality measures. For instance, if one is interested in understanding changes in welfare distribution from one period to another, it is necessary to deal with the entire distribution. However, one can use Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 76 Counterfactual Decomposition of Changes in Poverty Outcomes influence functions to establish a direct link between the distributional statistic of interest and individual (or household) characteristics and make suitable assumptions that allow counterfactual decomposition à la Oaxaca-Blinder. The influence function of a functional q (F ) is basically its first-order direc- tional derivative (Hampel 1974). Let G(b) be a mixture of two distributions F and H such that G(b) = bH + (1 − b)F. This expression says that an observation under G(∙) is randomly sampled from H with probability b or from F with prob- ability (1 − b). The directional derivative of q at F in the direction of H tells us how the functional q changes as G gets closer and closer to F. Formally, we write ∇qG→F = lim ( ) q G (b ) − q ( F ) = ∂ ( ) q bH + (1 − b ) F |b = 0.(4.6) b→ 0 b ∂b Let H = ∆y, the distribution function for a probability measure that assigns mass 1 to y in the domain of F. In other words, ∆y(u) is equal to one if y ≤ u ; otherwise it is equal to zero.5 In this case, G(b) = b∆y + (1 − b)F, and the influence function of the functional q (F) can be written as6 IF ( y ; q , F ) = ∇q F →∆ y .(4.7) This is an indicator of the relative effect of a small perturbation in F on q (F). In that sense, it is a measure of robustness.7 The influence function defined in equation (4.7) measures the effect that a single observation has on a functional. It is useful at this stage to note that the directional derivative of the mean of F in the direction of H is equal to ∂   ∂b   ∫( ) v bh ( v ) + (1 − b ) f ( v ) dv  b = 0 = ∫ vh ( v ) dv − ∫ vf ( v ) dv. (4.8) In other words, the directional derivative of the mean of F at F in the direction of H is equal to ∇µF→H = µH − µF. Hence, the influence function of the mean of F is equal to IF ( y ; µ , F ) = ∇µF →∆ y = y − µF . (4.9) The expected value of the influence function of a distributional statistic is equal to zero in all cases in which the frequencies and the range of the y-values are bounded. Firpo, Fortin, and Lemieux (2009) define the recentered or rescaled influence function (RIF) as the leading two terms of a von Mises (1947) linear approximation of the associated functional.8 It is equal to the functional plus the corresponding influence function. Let IF(y; q  ) stand for the influence function of  q (Fy), then RIF(y; q ) = q (Fy) + IF(y; q ). The fact that the expected value of the influence function is equal to zero implies that the expected value of the RIF is equal to the corresponding distributional statistic. In other words, q (Fy) = E[RIF(y; q  )]. By the law of iterated expectations, the distributional sta- tistic of interest can be written as the conditional expectation of the recentered Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 77 influence function (given the observable covariates, x). This is the RIF regression that for q (Fy) can be expressed as E[RIF( y; q )|x]. The distributional statistic q (Fy) can therefore be expressed in terms of this conditional expectation as follows: q ( Fy ) = ∫ E  RIF ( y; q )|x  dF ( x ). (4.10) This expression suggests that to assess the impact of covariates on q (Fy), one needs to integrate over the conditional expectation E[RIF(y; q )|x]. This can be easily done using regression methods. At this point, one has a choice between linear and nonlinear models. Linear and Nonlinear Specifications. If one assumes linearity, the conditional expectation of the RIF can be written as a linear function of observable covariates as follows: E[RIF(y;q )|x] = xb. One can then apply OLS to the following equation: RIF( y;q ) = xb + e.(4.11) Fortin, Lemieux, and Firpo (2011) explain that the expected value of the linear approximation of the RIF regression is equal to the expected value of the true conditional expectation because the expected value of the approximation error is zero. This fact makes the extension of the standard Oaxaca-Blinder decomposition to RIF regressions both simple and meaningful. Interestingly, the influence function for the mean presented in equation (4.9) implies that the cor- responding recentered influence function is RIF(y; m, F ) = y. Hence, the ordinary linear regression of y on a set of covariates x is indeed an RIF regression. So the standard Oaxaca-Blinder decomposition is in fact based on RIF regression. Based on equation (4.11), we find that the endowment effect identified on the basis of an RIF regression can be written as follows: ∆q  E ( x|t = 1) − E ( x|t = 0 )  X =   ⋅ β0 . (4.12) The corresponding structural effect is S = E ( x|t = 1) ⋅ ( β1 − β 0 ) . (4.13) ∆q This decomposition may involve a bias, because the linear specification is only a local approximation that may not hold in the case of large changes in covari- ates.9 The solution to this problem is to combine the reweighing method described earlier with RIF regression.10 Given the analogy between the mean and the class of additively separable poverty measures, equation (4.9) implies that the influence function of any member of that class is IF( y; P, F ) = I( y ≤ z)y (y|z) − P(F; z),(4.14) Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 78 Counterfactual Decomposition of Changes in Poverty Outcomes where I( y ≤ z) is an indicator function and P(F; z) is the poverty measure ­ written in a way emphasizing that this distributional statistic is a functional of F (Cowell and Victoria-Feser 1996; Essama-Nssah and Lambert 2012). The corresponding recentered influence function is RIF( y; P, F ) = I( y ≤ z)y (y|z).(4.15) For these poverty measures, one can in fact use nonlinear specifications of the RIF regression (for example, logit or probit for the headcount index and tobit for the other poverty measures).11 Fairlie (2005) proposes an extension of the Oaxaca-Blinder decomposition to logit and probit models, while Sinning, Hahn, and Bauer (2008) explain how to extend this method to nonlinear models in general.12 There is also an indirect way of identifying (and hence estimating) the com- position and structural effects that account for the variation in poverty measures that are members of the additively separable class. As noted in chapter 2, varia- tion in poverty over time can be expressed as a weighted sum of points on the growth incidence curve (GIC). Since the GIC describes outcome variation across quantiles, one can use RIF regression to perform decompositions of differences across quantiles and thus decompose growth incidence into the composition and structural effects. One would need RIFs for the quantiles under consideration. Firpo, Fortin, and Lemieux (2009) note that the RIF of the τth quantile of the distribution of y is the following:13 τ − I ( y ≤ qτ )  RIF ( y ; qτ ) = qτ + IF ( y ; qτ ) = qτ +  , (4.16) f y ( qτ ) where I(∙) is an indicator function for whether the outcome variable y is less than or equal to the τth quantile and fy(qτ  ) is the density function of y evaluated at the τth quantile. One can use equation (4.16) repeatedly to decompose, for instance, the first 99 quantiles (percentiles) of the outcome distribution of interest. This means that we can decompose the GIC into a component associated with the composi- tion (or endowment) effect and a second one related to the structural (or the price) effect. Formally, we express this decomposition as follows: g( y) = gx( y) + gs( y).(4.17) Equation (4.17) implies that the elasticity of poverty with respect to the mean z 1 outcome (ζ P ( g ) = γP ∫ yy ′ ( y|z ) g ( y ) f ( y ) dy ) can also be decomposed into a 0 composition and a structural effect as follows: z z 1 1 ζP (g ) = γP ∫ yy ′ ( y|z ) g X ( y ) f ( y ) dy + 0 γP∫ 0 yy ′ ( y|z ) g S ( y ) f ( y ) dy. (4.18) Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 79 The first term on the right-hand side of equation (4.18) represents the endow- ment effect based on the corresponding effect for the GIC. Similarly, the second term is the structural effect based on the corresponding effect for the GIC. It is important to note that this indirect decomposition applies not only to this class of poverty measures but also to all additively separable social evaluation functions such as the Atkinson (1970) and the S-Gini welfare functions.14 This fact implies that the rate of growth of per capita income, γ, can also be decom- posed into two components reflecting the composition and structural effects. It can be shown that when there is no aversion to inequality, the Atkinson welfare function ranks social states on the basis of the average outcome (such as average income or expenditure). Thus, the rate of change in social welfare induced by a distributional change is captured by the per capita rate of growth, which can be expressed as a my ∆µ y weighted sum of points along the GIC. Indeed, γ = µ = ∫ µ g ( y ) dF ( y ), where 0 my stands for the maximum income or expenditure, and each point on the GIC is weighted by the slope of the Lorenz curve at that point. Clearly, this rate of growth can be decomposed on the basis of equation (4.17) into an endowment effect and a structural effect. Given that the level and pattern of growth depend on factor accumulation and productivity, we can interpret the endowment effect as an indicator of changes in factor accumulation and the structural effect as an indicator of changes in productivity. Some Advantages of Linearity. As noted earlier, one has the choice between non- linear and linear specifications of the RIF regression model. Linearity has the added advantage of making it possible to perform a detailed decomposition that can further decompose each of these effects in terms of the contributions of the relevant covariates. Fortin, Lemieux, and Firpo (2011) explain that a decomposi- tion approach provides a detailed decomposition when it allows one to apportion the composition effect or the structural effect into components attributable to each explanatory variable. The contribution of each explanatory variable to the composition effect is analogous to what Rothe (2010) calls a “partial composition effect.”15 Assuming a linear RIF regression model, let xk and bk stand, respectively, for the kth element of x and b. Then the endowment and price effects can be written in terms of sums over the explanatory variables. For the endowment effect, we have m ∆q X = ∑  E ( x |t = 1) − E( x |t = 0) β k =1 k k 0k . (4.19) Similarly, for the structural effect, we have the following expression: m ∆q S = ∑E ( x |t = 1)( β k =1 k 1k − β0 k ).(4.20) Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 80 Counterfactual Decomposition of Changes in Poverty Outcomes Expressions (4.19) and (4.20) provide a simple way of dividing the endow- ment and price effects into the contribution of a single covariate or a group of covariates as needed.16 Such detailed decompositions are not easy to obtain for nonlinear models. Changes along the Entire Outcome Distribution The decomposition of changes in distributional statistics generally produces information about the aggregate composition and structural effects. Although the linearity assumption can help identify the contribution of various covariates to these aggregate effects, it does not tell us how these effects vary along the entire outcome distribution. To obtain this information, we now consider the decomposition of differ- ences in density functions and across quantiles. The decomposition of changes in density functions relies on nonparametric methods. In the case of quantiles, we focus on the use of quantile regression (a parametric method). All the methods reviewed in this section are purely statistical in the sense that they all rely on models of the conditional distribution of outcomes given the covariates. Differences in Density Functions For decomposition purposes, one needs a model that links the outcome of inter- est to household characteristics. To focus on differences in density functions, we maintain that the outcome variable y has a joint distribution with characteris- tics,  x. This distribution is characterized by the following joint density function: Jt( y, x), t = 0, 1. For instance, poverty analysis relies on household consumption expenditure (y) as a measure of welfare. Thus data from a household income and expenditure survey characterize the joint distribution of expenditure and house- hold characteristics (x). Just as the standard Oaxaca-Blinder decomposition is based on the unconditional mean, the generalization of that method considered here requires the marginal distribution of y noted as ft( y). This marginal density function can be obtained by integrating the covariates x out of the joint density. Furthermore, the factorization principle allows one to write the joint density as a product of the distribution of y conditional on x, gt( y|x), and the joint distribution of characteristics, ht(x). These are the two factors underpinning the decomposition. Any change in the marginal outcome distribution induced by a variation in the distribution of observed character- ­ istics (ceteris paribus) represents the endowment effect, while any change in the distribution associated with a (ceteris paribus) variation in the condi- tional distribution is interpreted as the price-behavioral effect (Bourguignon and Ferreira 2005). To see clearly what is involved,17 we express the joint density function as a product of the two underlying functions: Jt( y, x) = gt( y|x)ht(x), t = 0, 1. On the basis of this factorization, we can write the marginal density of y in a way that facilitates the expression and interpretation of the decomposition results, that is, Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 81 ft ( y ) ≡ f gt ht ( y ). Thus the observed change in the outcome distribution between the two periods can be stated as follows: ∆f = f1 ( y ) − f0 ( y ) ≡ f gh11 ( y ) − f gh00 ( y ).  (4.21) We can add to and subtract from the difference defined in (4.21) the follow- 1 ing counterfactual:18 f gh0 ( y ). This is the marginal density function that would obtain if the conditional distribution were that of period 0 and if the joint distri- bution of characteristics were that prevailing in period 1. This transformation leads us to the following generalized decomposition of changes in the marginal density of y:  f g 0 ( y ) − f g 0 ( y ) ∆f =   f g1 ( y ) − f g 0 ( y ) + h1 h0 h1 h1  . (4.22) The configuration of the indices (subscripts and superscripts) for the marginal distributions involved in (4.22) suggests an interpretation of the various compo- nents of the decomposition. The first component on the right-hand side is the endowment effect (based on changes in the joint distribution of observed charac- teristics). The second component measures the price-behavioral effect (linked to the change in the conditional distribution of y, which, in fact, also includes the effect of unobservables). Kernel Density Approaches. In their study of the role of institutional factors in accounting for changes in the distribution of wages in the United States, DiNardo, Fortin, and Lemieux (1996) demonstrate how to implement empirically the above decomposition using kernel density methods to estimate the relevant den- sity functions. The histogram is the oldest and most common density estimator (Silverman 1986), and kernel methods may be viewed as ways of smoothing a histogram.19 The basic idea is to estimate the density f(y) by the proportion of the sample that is near y. One way of proceeding is to choose some interval or “band” and to count the points in the band around each y and normalize the count by the sample size multiplied by the bandwidth. The whole procedure can be viewed as sliding the band (or window) along the range of y, calculating the fraction of the sample per unit within the band, and plotting the result as an estimate of the density at the midpoint of the band (Deaton 1997).20 The kernel estimate of the density function ft( y) can be written as follows: nt yit − y  ∑K  1 ft ( y ) = , t = 0, 1,(4.23) hnt h   i =1 where h is the bandwidth representing the smoothing parameter, nt is the sample size for period t, y is the focal point where the density is estimated, and K(∙) is the kernel function. A kernel function is essentially a weighting function chosen to give more weight to points near y and less weight to those Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 82 Counterfactual Decomposition of Changes in Poverty Outcomes far away. In particular, it will assign a weight of zero to points just outside and just inside the band. As a weighting function, the kernel function should satisfy four basic proper- ties: (a) positive, (b) integrate to unity over the band, (c) symmetric around zero so that points below y get the same weight as those an equal distance above, and (d) decreasing in the absolute value of its argument. The most com- mon kernel functions used in empirical work are the Gaussian and Epanechnikov kernels.21 The counterfactual density function that is the linchpin of the decomposi- tion presented in equation (4.22) can be written in a manner analogous to the distribution functions underlying the decomposition presented in equation ­ (4.3).22 In other words, f gh0 1 ( y ) = f y0|t = 1. This density can be estimated by reweighing the kernel estimate for period 0 using the same function as the one underlying the counterfactual distribution defined in equation (4.5). The resulting expression is n0 yi 0 − y  ∑w ( x ) K  1 fˆy0 |t =1 ( y ) = . (4.24) hn0 h   i =1 A Semiparametric Approach. Machado and Mata (2005) propose a semiparamet- ric approach to estimating the density functions needed in the above decomposi- tion. Their approach is based on a two-step procedure to derive marginal density functions from the conditional quantile process that fully characterizes the con- ditional distribution of y given the covariates x. Specifically, these authors model the conditional distribution of y given x by a linear conditional quantile function as follows: qt ( yt|xt) = xt bt(t ), t ∈(0, 1), t = 0, 1. (4.25) The second step entails estimating the marginal density function of y that is consistent with the conditional quantile process defined by equation (4.25). This is achieved by running the following algorithm: 1. Draw a random sample of size m from a uniform distribution on [0, 1] to get tj for j = 1, 2, …, m. 2. For each tj, use available data to estimate the quantile regression model and get m estimates of coefficients β t (τ j ) , j = 1, 2, …, m. 3. Given that xt is a (nt x k) matrix of data on covariates, draw a random sample s of size m from the rows of xt and denote each such sample by x jt . 4. The corresponding values of the outcome variable are given by s y jt s ≡ x jt β t (τ j ) , j = 1, 2, …, m . The validity of this procedure stems from the probability integral transforma- tion theorem, which states that if u is a random variable uniformly distributed over [0, 1], then y = F −1(u) is distributed like F. Here tj is assumed to be a Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 83 realization­ of Fyt |xt . Given model (4.25), the corresponding conditional quantile regression model can be written as | xt (τ j , x t ) = x t β t (τ j ) , t = 0, 1. qτ j ( yt |x t ) = Fy−t1 (4.26) A modified version of the above algorithm leads to the critical counterfactual upon which the decomposition is based. Recall that the counterfactual of interest is the density function of the outcome in period 1, assuming that the character- istics of that period had been rewarded according to the system prevailing in period 0. This counterfactual can be estimated by applying the above algorithm to the data for period 0, except that at stage 3, covariates must be drawn from data for period 1. On the basis of equation (4.26), the conditional regression model associated with this counterfactual is the following: qτ j ( y0 |x1 ) = Fy−01|x0 (τ j , x1 ) = x1β0 (τ j ). (4.27) As noted by Fortin, Lemieux, and Firpo (2011), this approach is computa- tionally demanding. They suggest a simplification based on the estimation of a large number of quantile regressions (say, 99) instead of using the random pro- cess. The conditional quantile function can then be inverted to obtain the con- ditional cumulative distribution that must be averaged over the empirical distribution of the covariates to yield the unconditional distribution function. In fact, Machado and Mata (2005) acknowledge that this is a viable alternative to their method. Differences across Quantiles As discussed earlier in the context of RIF regression analysis, one can also work with quantiles, which are easier for detailed decompositions, instead of density functions to decompose changes along the entire outcome distribution. Because the decomposition must be based on marginal distributions, one needs to work with marginal quantiles, not conditional ones. There are multiple ways to go about it. An alternative to using RIF regression is to derive ­ marginal quantiles from equations (4.25) and (4.26)—based on the Machado and Mata (2005) procedure—or by numerical integration as proposed by Melly (2005). To link conditional quantiles to marginal quantiles, Angrist and Pischke (2009) start from the observation that the proportion of the population below qt condi- tional on x is equal to the proportion of conditional quantiles that are below qt. Let I(∙) be the indicator function that takes a value of one if its argument is true ) stand for the conditional cumulative distri- and zero otherwise. Again, let Fy|x(  bution function (CDF) of y given x. Thus the proportion of the population for 1 whom the outcome y is less than qt is equal to Fy|x ( qτ |x ) = I  ∫  Fy|x (τ | x ) < qτ  −1 0  dτ , where the term on the right-hand side is equal to the proportion of conditional quantiles that are below qt . Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 84 Counterfactual Decomposition of Changes in Poverty Outcomes On the basis of equation (4.25), we can rewrite this proportion as 1 ∫  xβ (τ ) < qτ  Fy|x ( qτ |x ) = I  0  dτ ), from which . The marginal distribution of y, Fy(  one derives marginal quantiles, is obtained by integrating the conditional distri- bution over the whole range of the distribution of the covariates (Melly 2005). 1  The resulting expression is Fy ( qτ ) =  I   0  x β (τ ) < ∫ ∫ q  τ dτ  dFx . The sample ana-   log of this expression—based on an estimation of quantile regressions at every percentile for a sample of size n—is given by the following expression (Angrist and Pischke 2009): n  1 1  ∑ ∑ 1 F y ( qτ ) =  I ( x i βτ < qτ ) .(4.28) n  100 τ = 0 i =1    The marginal quantile corresponding to the above estimator of the marginal distribution of the response variable is obtained by inverting equation (4.28). We ( ) { note these marginal quantiles as qτ x t , β t (τ ) = inf q : F y ( qτ ) . } The generalized Oaxaca-Blinder decomposition described by equation (4.3) can equivalently be stated in terms of these marginal quantiles. The observed change in the marginal distribution of the response variable is now written as ( ) ( ) ∆qτ = qτ x1 , β 1 (τ ) − qτ x 0 , β 0 (τ ) . To distinguish the endowment effect from the price effect, we subtract from and add to this expression the following coun- ( ) terfactual outcome: qτ x1 , β 0 (τ ) . This counterfactual involves the characteristics of period 1 evaluated with the prices (coefficients) of period 0. The correspond- ing decomposition analogous to expression (4.3) is the following: ∆qτ =   ( ) (  qτ x1 , β 0 (τ ) − qτ x 0 , β 0 (τ )  ) ( ) ( )  +  qτ x1 , β (τ ) − qτ x1 , β (τ )  .(4.29)    1 0   Consistent with equation (4.3), the first term on the right-hand side of equa- tion (4.29) is the endowment effect at the τth quantile, while the second term measures the price effect at the same location. Again, changes along the entire outcome distribution are obtained by performing this decomposition for the first 99 percentiles. Accounting for the Contribution of Unobservables Recall that based on equation (4.2), the contribution of unobservable characteristics into changes in the outcome distribution has at least two potential ­ components: the first relates to changes in the returns to unobservables and the second to the distribution of these characteristics. All the decomposition meth- ods discussed so far lump the first component together with the returns to observables in the structural effect. Furthermore, the contribution of changes in the distribution of unobservable characteristics is ruled out by either the ignor- ability assumption or the zero-conditional-mean assumption. The issue now is Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 85 this: Under what conditions can we identify these effects that up to now have been swept under the rug, so to speak? Further Decomposition of the Structural Effect Juhn, Murphy, and Pierce (1993) assume additive linearity for the outcome model and conditional rank preservation to decompose differences in outcome distributions in a way that accounts for the contribution of unobservables.23 Under additive linearity, the function defining the outcome variable is separable in x and e. We can therefore write the outcome model as follows: yt = xtbt + ut, t = 0, 1, (4.30) where ut = ζt(e), some function of unobservable characteristics. The assumption of conditional rank preservation means that a given individual has the same rank in the distribution of u0 as in the distribution of u1, conditional on observable characteristics. To see this formally, let Fu |x(ut|xt) stand for the dis- tribution of ut conditional on xt. Also, let τi0(xi) = Fu |x(ui0|xi) be the rank of indi- vidual i with observed characteristics xi in the conditional distribution of u0 given x, and let τi1(xi) = Fu |x(ui1|xi) be individual i’s rank in the conditional distribution of u1 given x. Conditional rank preservation says that τi0(xi) = τi1(xi). Fortin, Lemieux, and Firpo (2011) explain that one can secure conditional rank invari- ance by assuming ignorability and that the functions ut are strictly increasing in e. In other words, these functions are monotonic.24 As expected, separability allows the analyst to construct counterfactuals sepa- rately for observables and unobservables. To see what is involved, consider the case of a particular individual, i, with outcome yi1 = xi1b1 + ui1 in period 1. Let v ic0 represent what the residual part of the outcome would have been had the unobservable characteristics of this individual been treated as in the initial period, ceteris paribus. The corresponding counterfactual for the full outcome is yic0 = x i1β1 + v ic0. Comparing this counterfactual with the observed outcome reveals the contribution of changes in the returns to unobservable characteristics of individual i to the overall change in the individual’s outcome. We denote this as ∆ S c y ( ) (c ) c ,σ = y i1 − y i 0 = v i1 − v i 0 . Next, we replace b1 with b0 in the expression for yi 0. This operation yields the following counterfactual: yib0 = x i1β0 + v ic0. Let ∆S y ( ) ,β = y i 0 − y i 0 . This term is equivalent to ∆ S ,β = x i1 ( β1 − β 0 ) and clearly shows c b y the contribution of changes in the returns to observable characteristics. Thus, separability along with ignorability and monotonicity make it possible to split the structural effect into (a) one component resulting from changes in the returns to observables and (b) another linked solely to changes in returns to unob- y y y servables. In other words, the total structural effect25 is equal to ∆ S = ∆S , β + ∆S, σ . y The composition effect ∆ X can be identified residually from the following y expression: ∆O y − ∆Sy = ∆Xy + ∆ε y , where ∆O = ( yi1 − yi 0 ). The assumption of y conditional independence implies, however, that ∆ ε ­ = 0. Recall that this assumption implies that the conditional distribution of unobservables does not vary across groups (periods). Therefore, under the prevailing identifying Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 86 Counterfactual Decomposition of Changes in Poverty Outcomes assumptions, the difference between the overall outcome difference and the identifies the observable composition effect. structural effect ­ The question now is, how does one identify v ic0? This is where rank preserva- tion comes in. This assumption leads to the following imputation rule: v ic0 = Fv−1 ( 0 |x ) τ i1 ( x i ) . (4.31) This imputation rule says that for individual i in the end period, the counter- factual for the residual outcome is equal to the residual outcome associated with the individual located at the same rank in the conditional distribution of residual outcomes in the base period. In practice, one would estimate b0 and b1 using OLS. Bourguignon and Ferreira (2005) explain that empirical implementation of a rank-preserving transformation is complicated by the fact that both samples do not necessarily have the same number of observations. However, if one is willing to assume that both distributions are the same up to some proportional transfor- mation, then the rank-preserving transformation can be approximated by multi- plying residuals in the base period by the ratio of the standard deviation in the end period to the one in the initial period. Fortin, Lemieux, and Firpo (2011) point out that assuming constant returns to unobservables and homoskedasticity allows one to write the unobserved com- ponent of the outcome as ut = ste. Homoskedasticity implies that the conditional variance of e is constant (and can be normalized to one). Equation (4.30) can therefore be written as follows: yt = xtbt + ste, t = 0, 1. (4.32) Applications and Limitations of Juhn-Murphy-Pierce Model As it turns out, this is the version of the model used by Juhn, Murphy, and Pierce (1991) in their study of the evolution of the wage differential between blacks and whites in the United States. In that context, the standard deviation of the residuals in the wage equation stands both for within-group inequality in the wage distribution and for the price of unobserved skills (Yun 2009). The outcome model specified in equation (4.32) has also been used to study the gender pay gap. In that context, t = 1 is taken to represent males while t = 0 stands for females, and the wage regime for males is considered the nondiscrimi- natory one. The counterfactual used in the decomposition is the outcome that female workers would have experienced if they had been paid like their male counterparts. Care must be taken when applying this version of the model to decompose differences in mean outcome using OLS, because the OLS residuals sum up to zero. To see this, consider the following expression of standard Oaxaca-Blinder decomposition that explicitly shows the residuals:  β1 + E ( x 0 )( β1 − β0 )  E ( x1 ) − E ( x 0 )  µ ∆O = (4.33)  E (∈ +  σ 1 + E ( ε 0 )(σ 1 − σ 0 ). 1 ) − E (ε 0 ) Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 87 The terms associated with the unobservables in the right-hand side of equa- tion (4.33) will disappear if the decomposition is based on OLS applied to each equation separately. To get around this issue, Juhn, Murphy, and Pierce (1991) assume that the returns to observable characteristics are the same for both groups and apply OLS to only one group, constructing an auxiliary equation for the other group. In the context of gender wage gap studies, OLS is applied to the equation for males only. The equation for female workers is constructed as follows: y0 = x0 b1 + υ0. The implied decomposition is  β1 − E ( v 0 ) =   E ( x1 ) − E ( x 0 )   β1 − σ 1E (η0 ) , (4.34)  E ( x1 ) − E ( x 0 )  µ ∆O = v0 where η0 = . The above expression is computed on the basis of the sample σ1 analogs of the parameters of interest. The first term in the twofold decomposi- tion presented in equation (4.34) represents the predicted gap, while the second stands for the residual gap. As Yun (2009) points out, the residual gap is equal to the structural effect in the standard Oaxaca-Blinder decomposition. Yet, this structural effect represents returns to observable characteristics. It is therefore hard to see how the Juhn, Murphy, and Pierce (1991) procedure helps to identify the contribution of unob- servables. Yun (2009) proposes instead the decomposition defined by equation (4.33), under the assumption that the expected value of unobservable terms is not equal to zero. However, that author does not provide an implementation procedure corresponding to this situation. Relationship to Treatment Effect Analysis As Fortin, Lemieux, and Firpo (2011) point out, there is a powerful analogy between the classic Oaxaca-Blinder decomposition method and treatment effect analysis.26 Treatment impact analysis seeks to identify and estimate the average effect of treatment (intervention) on the treated (those exposed to an interven- tion) on the basis of the difference in average outcomes between the treated and a comparison group. In that context, t indicates treatment status. It is equal to one for the treated and zero for the untreated (the comparison or control group). The expression,  E ( y1 ) − E ( y0 )  µ ∆O = , can therefore be interpreted as the difference in average outcomes between the treated and untreated. Under the assumptions underlying the basic Oaxaca-Blinder method,27 this difference is clearly the result of differ- ences in observable characteristics (the composition effect) and in treatment status. The part resulting from the difference in treatment status is known as the average treatment effect on the treated (ATET) and is in fact equal to the struc- tural or price effect. Countering Selection Bias Note that the conventional approach to impact evaluation also relies on ceteris paribus variation of treatment to identify its average effect on the treated. Within Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 88 Counterfactual Decomposition of Changes in Poverty Outcomes that logic, the composition effect is equivalent to selection bias that must be driven to zero by the use of randomization, propensity score matching, or similar methods. Randomization. To ensure that the distribution of observed and unobserved char- acteristics is the same for both the treated and the control groups, randomization is employed. By balancing observed and unobserved characteristics between the groups before the administration of treatment, randomization guarantees that the average difference in outcome between the two groups is the result of treat- ment alone, hence the causal interpretation given to this parameter under those circumstances. In other words, the first term on the right-hand side of equation (4.3) (that is, the endowment effect or selection bias) is equal to zero under random assignment to treatment and full compliance.28 Clearly, randomization is designed to implement a ceteris paribus variation in treatment. Conditioning by Stratification. In the context of observational studies where the investigator does not have control over the assignment of subjects to treatment, the determination of the causal effect of treatment hinges critically on the under- standing of the underlying treatment assignment or selection mechanism, which must explain how people end up in alternative treatment states. The assumption of selection on observables (also known as ignorability) is often invoked to imple- ment ceteris paribus identification of ATET through conditioning by stratification. Propensity Score Matching. Basically, conditioning by stratification entails compar- ing only those subjects with the same value of covariates x across the two groups (treated and untreated). This type of selection of individuals from the two groups is known as matching. A potential dimension problem is associated with match- ing when there are many observable characteristics taking many values. Insisting on conditioning based on exact values can lead to too few observations in each subgroup characterized by these observables. This dimensionality problem can be resolved by matching on the propensity score, that is, the conditional probabil- ity of receiving treatment given observable characteristics (Rosenbaum and Rubin 1983). Usefulness of Treatment Effect Analysis The analogy between treatment effect analysis and the Oaxaca-Blinder ­ decomposition method has been extremely useful for the development of flexi- ble estimation methods for endowment and structural effects. As noted earlier, selection on observables implies that the conditional distribution of unobservable factors is the same in both groups (treated and comparison). Although this assumption is weaker than the zero-conditional-mean assumption29 used in the standard Oaxaca-Blinder decomposition, it is enough to secure identification and µ consistent estimation of the ATET and hence the structural effect, ∆ S (in the Oaxaca-Blinder framework). Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 89 Fortin, Lemieux, and Firpo (2011) give the example of education and ­ nobservable ability. They explain that if education and ability are correlated, u this creates an endogeneity problem that prevents a linear regression of earnings on education to produce consistent estimates of the structural parameters mea- suring the return to education. Yet the aggregate decomposition remains valid as long as the correlation between ability and education is the same in both groups. A major implication of the difference in identification assumptions between the traditional Oaxaca-Blinder approach and treatment effect analysis is that consistent estimators of the ATET such as IPW and matching can be used to µ estimate the structural effect (∆ S ) even if the underlying relationship between the outcome and covariates is not linear. Given such an estimate, the composition effect can be calculated as a residual from the overall mean difference as follows: ∆µ µ µ X = ∆ O − ∆ S . In particular, decomposition methods based on this weighting procedure are known to be efficient. It is also worth noting that the generaliza- tion of the Oaxaca-Blinder decomposition to variation in other distributional statistics such as quantiles, poverty, and inequality measures enables an analyst to study the distributional and poverty impacts of an assigned intervention. Limitations of the Analogy with Treatment Effect Analysis Although treatment effect analysis can help with the identification and estima- tion of the structural effect, it is notable that this effect does not necessarily inherit the causal interpretation generally enjoyed by the ATET for two basic reasons: (a) In many cases, group membership is not the result of a choice or an exogenous assignment but is rather a consequence of an intrinsic characteristic, such as gender or race, and (b) many of the observable covariates are not equiva- lent to the pretreatment variables that are not supposed to be affected by the treatment. The standard Oaxaca-Blinder decomposition method has two other impor- tant limitations: First, each covariate’s contribution to the structural effect is highly sensitive to the choice of the omitted group when the explanatory vari- ables include a categorical variable. (Jann [2008] discusses possible solutions to this problem.) Second, the decomposition provides consistent estimates only under the assumption that the conditional expectation is linear. Under the linearity assumption, the counterfactual average when t = 1 is simply equal to E(x1|t = 1)·b0. This is estimated by the cross product of sample means of characteristics for t = 1 with the relevant OLS coefficients from t = 0. The corresponding estimate is x1 β 0. The counterfactual mean outcome will not be equal to this term when linearity does not hold. One possible solution is to reweigh the sample for t = 0 using the inverse probability method discussed earlier and to compute the counterfactual mean ­ outcome on the basis of statistics from the reweighed counterfactual sample. Let c c x0 be the vector of the means of adjusted covariates in t = 0 and β 0 the corre- sponding least squares coefficients. Then the correct counterfactual c mean out- come when the linearity assumption does not hold is x 0 c β 0. This is the term to Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 90 Counterfactual Decomposition of Changes in Poverty Outcomes add to and subtract from the empirical version of the overall difference in mean outcome to get the appropriate estimates of the endowment and structural effects when the linearity assumption fails. Accounting for Behavior A key limitation of the decomposition methods discussed so far is that they do not account for changes in agents’ behavior in response to changes in their socio- economic environments—whether those changes are the result of economic shocks, policy reform, or other causes. Given the maintained hypothesis—that the living standard of individuals in a given society depends crucially on what they do with their assets (innate and external) subject to the opportunities offered by that society—this section focuses on modeling agents’ behavior to account for their reactions to changes in their socioeconomic environment. Standard economic theory explains behavior in terms of the principles of optimization and market interaction. Modeling behavior entails the specification of the following elements (Varian 1984): • The actions a socioeconomic agent can take. • The constraints the agent faces. • The objective function used to evaluate feasible actions. The assumption that the agent seeks to maximize the objective function ­ subject to constraints implies that the outcome variables used to represent the consequences of behavior can be expressed as functions of parameters of the socioeconomic environment, embedded in the constraints facing the agent. We consider the Roy (1951) model of choice and consequences along with its inter- pretation in the context of modeling the determinants of the living standard. This model stems from the optimization principle and applies to discrete choice problems. We also discuss key considerations in simulating counterfactual distri- butions underlying any decomposition exercise. The Roy Model of Choice and Consequences Heckman and Honoré (1990) explain that the original Roy (1951) model was designed for the study of occupational choice and its implications for the distri- bution of earnings in an economy where agents are endowed with different sets of occupation-specific skills. In the two-skill Roy model, each income-maximizing agent has one skill usable only in one sector and a second skill usable in only another sector (Heckman and Honoré 1990). Therefore, the two-skilled agent can freely choose to work in only one of two activities (in this case, either fishing or hunting) on the basis of their productivity in each. Under this scenario, an agent with a given skill endowment will choose to work in the sector where the potential income is higher. There are no investment opportunities to augment sector-specific skills, nor are there costs associated with changing sectors. These authors also show that self-selection implies a lower level Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 91 of inequality in earnings compared with a benchmark case where workers are randomly assigned to jobs. The fact that occupational choice has significant implications for earnings distribution makes the Roy model a relevant framework for analyzing agents’ behavioral responses to changes in their socioeconomic environment. Heckman and Sedlacek (1985) discuss an extension of the basic framework by including nonmarket activity as an option in the choice set facing socioeco- nomic agents who are now assumed to maximize utility instead of income. The utility of participating in each of the sectors depends on both sector-specific attributes (such as the wage rate, employment risk, or job status) and individual characteristics. That we observe only sectoral choices and not the underlying util- ity function means it is possible to identify only parameters associated with differences in utility across sectors. These authors also consider the contribution ­ of self-selection to income inequality and find that in this general model, self- selection can increase both between- and within-sector inequality compared with a random allocation of workers to sectors. At the most fundamental level, the Roy model is characterized by two components: a selection mechanism and the associated potential outcomes. ­ These outcomes are possible consequences of the choice made through the selec- tion mechanism. The extended version of the Roy model is consistent with ­ discrete choice models to the extent that utility-maximizing agents face a dis- crete choice set. Discrete Choice Modeling Train (2009) characterizes a discrete choice model in terms of two fundamental elements: the choice set and the decision process (or the decision rule). The choice set is the collection of alternatives from which the decision maker chooses one. This set must be exhaustive in the sense that it must include all possible alterna- tives, the latter being mutually exclusive from the perspective of the decision maker. Finally, the number of alternatives must be finite. In the case of discrete models of labor supply, for instance, the choice set can be represented by a few options, such as not working, working part time, and working full time. Just as in the case of the consumption-leisure paradigm, the decision process assumes utility-maximizing behavior (Essama-Nssah 2012). It is therefore assumed that the decision maker chooses the alternative that provides the great- est net benefit or utility. Let uhj, j = 1, 2, ... m be the utility that agent h gets from alternative j. The decision rule implies that the agent chooses alternative k if and only if uhk > uhj ∀j ≠ k. This decision-making process is usually framed within the logic of the random utility model, in which utility has two parts: The first, known as the representative utility, is a function of some observable characteristics of the decision maker and of the alternatives (Train 2009). The second component is a set of unobservable random factors. Formally, the utility function is written as uhj = uhj + ehj, where u is the representative utility and ε represents the unobserved portion of utility that is treated as random. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 92 Counterfactual Decomposition of Changes in Poverty Outcomes Now, the statement that alternative k is chosen if, and only if uhk > uhj ∀j ≠ k can be equivalently expressed as follows: k is chosen if and only if (ehj − ehk) < (uhk − uhj) ∀j ≠ k. Because of the uncertainty implied by the random part of the utility function, one can make only probabilistic statements about the decision maker’s choice. The probability that agent h chooses option k is defined by the following expression:30 Phk = Pr[(ehj − ehk) < (uhk − uhj) ∀j ≠ k].(4.35) The type of discrete choice model derived from the above probability ­ tatement is determined by the assumptions made about the distribution of the s unobserved portion of the utility function. For instance, the common logit model assumes that the random factors are independently and identically distributed (iid) extreme value variables for all options. In other words, each choice is inde- pendent from the others.31 An Interpretation of the Roy Model Coulombe and McKay (1996) provide an interesting interpretation of the Roy model that is consistent with our maintained hypothesis that an individual’s liv- ing standard is a payoff from participation in the life of society. Using the house- hold as the unit of analysis, these authors argue that a household’s living standard depends fundamentally on the socioeconomic group to which it belongs (or its economic activity status). To frame this view within the logic of the Roy model, the authors further argue that one needs to explain the selection mechanism leading to the observed socioeconomic group and, conditional on that choice, the determinants of the living standard in that group. This logic leads to a two- equation model—one representing the selection mechanism and the second modeling the living standard conditional on the choice of a particular socioeco- nomic group. Modeling the Selection Mechanism. Modeling the selection mechanism boils down to modeling the probability defined in equation (4.35). Consistent with the ran- dom utility framework underlying this expression, and assuming that the random elements are generated independently by an extreme value distribution, the multinomial logit model can be used to explain the probability of choosing an option. Formally, we express that probability as exp ( zhkγ k ) Phk = ,(4.36)  ∑  m 1 + exp ( zhjγ j )   j=2  where zhj is the set of relevant explanatory variables, and m is the total number of socioeconomic groups. The probability defined in (4.36) is essentially the propensity score. The specification of the explanatory variables requires a good understanding of the determinants of the choice of a socioeconomic group. Three Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 93 technological factors affect this choice in the context of the general Roy model (Autor 2009): • The distribution of skills and abilities; • The correlations among these skills in the population; and • The technologies for applying these skills. Coulombe and McKay (1996) make a similar point in a case study of Mauritania. They define socioeconomic groups in terms of the income-­ generating opportunities available to households and their members. In particular, they con- sider four mutually exclusive and exhaustive groups of households: (a) house- holds working predominantly as employees (whether in the public or private sector); (b) those engaged mostly in agricultural self-employment; (c) those engaged mainly in nonfarm self-employment; and (d) those not in the labor force. In essence, socioeconomic groups are determined on the basis of the house- hold’s main economic activity or source of income. As to the determinants of the choice of socioeconomic group, these authors argue that the choice depends on variables (such as education, wages, or profit rates) that affect relative returns from economic activities and consumption pref- erences. In particular, they make the point that the extent to which household members choose either self-employment over wage employment or to stay out of the labor market depends on the interaction between (a) total household labor supply within and outside the household (a consumption decision) and (b) its total labor demand (a production decision) for both household members and hired labor. In other words, the household’s socioeconomic classification reflects both consumption parameters (such as its demographic composition and the characteristics of the head of household) and production parameters relevant to self-employment (such as fixed inputs and variable costs). Modeling the Living Standards. Equation (4.36) models the selection mechanism. We need an outcome equation to complete the model—the living standard conditional on the choice of socioeconomic group—within the logic of the Roy ­ framework. Following Coulombe and McKay (1996), we let yhk stand for the log of per capita expenditure for household h in socioeconomic group k, and hhk for a random disturbance. The outcome equation associated with equation (4.36) can be written by analogy to the standard Mincer equation (in labor economics) as follows: yhk = xhbk + hhk.(4.37) Equations (4.36) and (4.37) constitute a system designed to explain house- hold-level living standards. In their case study, Coulombe and McKay (1996) distinguish two categories of determinants: household-level demographic factors and group-level demographic factors. These demographic variables include household size, household composition, and characteristics of the economic head Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 94 Counterfactual Decomposition of Changes in Poverty Outcomes of the household (such as educational level, marital status, gender, and ethnicity). Group-specific factors include those affecting total household income. For those engaged in wage employment, such factors would include level of education, sector of employment, and numbers of hours worked in a year to account for seasonal work. Given that such variables are difficult to measure at the household level (the unit of analysis), one could either (a) define and measure these variables only for the economic head of household or (b) adopt some form of aggregation over household members. Naturally, this would entail some loss of the heterogeneity found at the individual level. In the case of agricultural self-employment, specific factors include land size and quality, tenure status, use of fertilizer, insecticides, hired labor, access to extension services, and commercialization. Similar consid- erations apply to nonagricultural self-employment. For households outside the labor market, possible sources of livelihood include asset holdings, borrowing, and public and private transfers. Another important consideration here is the classification of variables as exog- enous or endogenous. This classification hinges on the time horizon chosen. For instance, in the long run, the living standard can affect demographic variables, such as household size and composition (Coulombe and McKay 1996). But in the short run, it is reasonable to think of the direction of influence as running from demographic variables to the living standard. The Coulombe-McKay study adopts a short-to-medium time frame so that most of the variables listed above are considered exogenous with respect to the model described by equations (4.36) and (4.37). Further Extensions of the Roy Model The model presented in Inchauste et al. (2012) and later in chapter 6 of this volume expands this framework by modeling educational and sectoral choice as endogenous. For nonfarm workers, employment type is modeled endogenously, as individuals could be salaried, daily workers, nonfarm self-employed, farm workers, or not working at all. Similarly, because farm households are likely to be diversified, a separate model for employment type is specified for farm workers who engage in a secondary occupation. Bourguignon, Ferreira, and Leite (2008) go one step further and model changes in household demographics as endogenous. In that framework, socioeconomic group, per capita consumption, education, and household composition are endogenous. Variations in education and in household com- position are modeled within the discrete choice framework portrayed by equation (4.36). In that particular application, the demand for education is modeled on the basis of six alternatives: 0 years of schooling, 1–4 years, 5–6 years, 7–8 years, 9–12 years, and 13 or more. The highest level of education is the excluded category. The authors considered the following variables to be purely exogenous: number of adults in the household, region of residence, age, race, and gender. For household demographics, the options are 0, 1, 2, 3, 4, and 5 or more children. The last category is omitted in the estimation. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 95 Note that education is an explanatory variable in the demographic multilogit model. Leite, Sanchez, and Laderchi (2009) apply this extended framework to ­ analyze the evolution of urban inequality in Ethiopia. They, too, focus on the household as the unit of analysis and use per capita household expenditure as the outcome variable. Cogneau and Robilliard (2008) use the extended Roy model to study the implications of three targeted poverty reduction policies in Madagascar: (a) a direct subsidy on agricultural production prices, (b) a workfare program, and (c) a uniform untargeted per capita transfer program. While using the household as the unit of analysis and considering consumption as the ultimate welfare indi- cator, these authors model first the income-generating process at the level of individual household members and then link consumption to household income. Working-age individuals (aged 15–64 years) faced a choice set with three alterna- tives: family work, self-employment, and wage work. Household composition and location are exogenously given. For self-employment and wage work, an individual’s potential earnings are equal to a task price multiplied by a given idiosyncratic amount of efficient labor. “Efficient labor” is assumed to be a func- tion of some observable characteristics (such as age, experience, and location) and unobservable skills. Family work is rewarded by a reservation wage that is a function of individual and household characteristics.32 In the absence of labor market segmentation, the simple selection rule of the basic Roy (1951) model would base sector choice on a comparison of the reser- vation wage and potential wages in the other two sectors. To account for labor market segmentation, Cogneau and Robilliard (2008) define a segmentation variable in terms of the relative cost of entry between self-employment and wage work, and adjust the selection rule accordingly. For policy evaluation, these authors embed the occupational choice model into a broader microeconomic module that includes the demand system for con- sumption goods. To keep things simple, they assume that consumption or saving decisions are separable from labor supply decisions. They also assume a fixed common savings rate of 5.2 percent so that aggregate consumption is equal to the implied consumption propensity multiplied by disposable income. The latter is the sum of farm profits, labor income, earnings from self-employment, and nonlabor income, such as capital income and transfers. Total consumption is allocated to three composite goods (agricultural, informal, and formal) according to budget shares derived from available data. The three policies considered—subsidized agricultural production prices, the workfare program, and the uniform untargeted per capita transfer program— have the potential of inducing large macroeconomic effects because their ­ collective cost represents about 5 percent of Madagascar’s gross domestic prod- uct. To account for this, the authors link the micro module to a small three-­ sector (agriculture, informal, and formal) computable general equilibrium model. The integrated framework makes it possible to consider the macroeconomic impact of the policy options along with their impact on inequality and poverty. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 96 Counterfactual Decomposition of Changes in Poverty Outcomes Adding a general equilibrium model removes a key limitation of the decomposi- tion methods discussed up to this point. These methods rely on either a purely statistical or a microeconomic model of behavior that cannot account for general equilibrium effects. Simulating Counterfactual Distributions The simulation of counterfactual distributions needed for the decomposition of distributional changes requires estimation of some version of the Roy system (composed of a selection equation and an outcome equation) for the initial and end periods. Counterfactual distributions can then be simulated by switching parameters and variables between these two estimated models one element at a time, holding all the other factors constant. In general, parameters of sample selection models can be estimated with two- stage methods or the maximum-likelihood approach. We summarize here the basic ideas underlying two-step procedures that are also known as control ­ function methods or generalized residual methods (Todd 2008). These methods are commonly used in the context of an explicit model of the outcome process involving a selection mechanism as well as an outcome equation. The selection mechanism is usually modeled within a random utility framework, and identify- ing assumptions are based on functional form restrictions or exclusion restric- tions (analogous to the instrumental variable [IV] approach). In particular, the control function approach seeks to model conditional expec- tations of potential outcomes (given observable characteristics and occupational or socioeconomic status) in a way that relates unobservable determinants of outcomes to the observables, including the choice of a socioeconomic group. This is consistent with the view that the underlying endogeneity problem is the result of omitted variables. The control functions represent the omitted variables. The key assumption in this method is that the observable determinants of both selec- tion and outcomes are independent of the unobservable determinants (Heckman and Navarro-Lozano 2004). Combining Parametric and Nonparametric Techniques Once the model has been estimated, counterfactual decompositions are per- formed. Building on the statistical approaches previously discussed in “The Composition and Structural Effects” section, Bourguignon, Ferreira, and Leite (2008) propose the combination of parametric and nonparametric techniques in constructing the desired counterfactuals. To see clearly what is involved, recall that the density function characterizing the joint distribution of the outcomes and covariates can be written as a product of the two underlying density functions—one characterizing the conditional dis- tribution of outcomes given the covariates, and the other the joint distribution of covariates. Earlier, we expressed this relation as Jt ( y, x) = gt( y|x)ht(x), t = 0, 1. As noted earlier, this factorization suggests that counterfactual distributions can be obtained by combining the conditional outcome distribution from one period (such as the initial period) with the joint distribution of covariates from the other Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 97 period (such as the end period). An example of this type of combination would be the following: h1 Jg 0 ( y, x ) = g 0 ( y|x ) h1 ( x ). (4.38) A key distinction between the methods discussed in the section on composi- tion and structural effects and those reviewed in this section is that the methods in section 3 are based on statistical models of the conditional outcome distribu- tion, while the methods discussed here rely on economic modeling of this con- ditional distribution. Thus, equations (4.36) and (4.37) characterizing the basic Roy model must be seen as modeling the conditional outcome distribution, gt( y|x). The method of Bourguignon, Ferreira, and Leite (2008) as well as the model adopted in chapter 6 use the parametric approach to generate counterfactuals for the conditional outcome distribution and nonparametric sample-reweighting tech- niques to construct counterfactuals for the joint distribution of exogenous covari- ates. These authors argue that the parametric approach for the conditional distribution has the advantage of providing a clear economic interpretation of the parameter estimates along with great flexibility in exchanging parameters from one period to another (that is, from one state of the world to another). Application in Context of the Roy Framework To see how this works in the context of the Roy framework, use the estimated model to write the approximation to the conditional outcome distribution as follows: ( ) yt = s x t , zt ; γ t , βt , ε t , ηt . (4.39) Thus a change in the conditional outcome distribution as a result of a ceteris paribus change in the parameters of the multinomial logit model of selection can be computed easily as follows: ( ) ( ) ∆y = s x 0 , z0 ; γ 1 , β0 , ε 0 ,η0 − s x 0 , z0 ; γ 0 , β0 , ε 0 , η0 . (4.40) When a counterfactual requires a normalization of exogenous covariates for both periods, we can simply apply the DiNardo, Fortin, and Lemieux (1996) approach described earlier. The handling of the residuals in this process requires some care. In the case of the residuals associated with the outcome equations, for instance, one can resort to the rank-preserving transformation described earlier. Concluding Summary and Remarks The design and implementation of effective strategies for poverty reduction require relevant and reliable analytical input. The bedrock of this input is cer- tainly a rich and reliable dataset (both qualitative and quantitative) to be used in poverty measurement and analysis. In this context, there is a need for a sound Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 98 Counterfactual Decomposition of Changes in Poverty Outcomes understanding of the fundamental factors that account for observed variations in poverty either across space or over time. This chapter has reviewed some of the basic decomposition methods that are commonly used to identify sources of variation in poverty outcomes at both the macro and micro levels. It has focused on micro-decomposition approaches because aggregate methods fail to account for the heterogeneity of the factors that drive the observed changes in aggregate poverty. Decomposition as Social Impact Evaluation The decomposition of changes in poverty is an exercise in social impact evalua- tion that assesses changes in individual and social outcomes attributable to socio- economic shocks or policy implementation. Outcome models that underlie micro-decomposition methods are consistent with the view that an individual’s living standard is a payoff from one’s participation in the life of society. Accordingly, that payoff is a function of endowments, behavior, and the circum- stances that determine the returns to these endowments from any social transac- tion. These elements drive the distributional changes that define the potential scope of micro-decomposition methods. In general, the scope of a decomposition method is the set of explanatory factors the method tries to uncover by decom- position. The specification of an outcome model thus determines the potential scope of the corresponding decomposition method. Statistical and Structural Methods Micro-decomposition methods fall into two basic categories: statistical and struc- tural. All seek to model the joint distribution of the outcome variable and its determining factors. This joint distribution can be factorized into a product of (a) the conditional outcome distribution and (b) the marginal distribution of exogenous (independent) variables. Statistical methods rely uniquely on statistical principles to model the condi- tional outcome distribution, while structural methods rely on both economics and statistics to model this object. In particular, the structural methods considered here use utility maximization in a partial equilibrium setting to characterize individual behavior and social interaction. Statistical methods therefore are purely descriptive, while structural ones are considered predictive. Identification through Counterfactual Comparison Identification concerns the assumptions needed to recover, in a meaningful way, the factors of interest at the population level. These assumptions involve both the functional form of the outcome model and the joint distribution of fac- tors that determine the outcome. Although macro- and micro-decomposition methods differ in their scope, they share the same fundamental identification strategy based on the notion of ceteris paribus variation. The implementation of this idea entails the comparison of an observed outcome distribution with a counterfactual obtained by changing one factor at a time while holding all the other factors constant. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 99 A key counterfactual used in the identification of endowment and structural effects is the outcome distribution that would have prevailed in one state of the world had individual characteristics been rewarded according to the system applicable in the alternative state. The construction of this counterfactual relies critically on ignorability and the absence of general equilibrium effects. When the outcome model is separable in observables and unobservables, one can assume rank preservation to further split the structural effect into a component due to observables and another due to unobservables. An Analogy: Decomposition, Estimation, and Treatment Effect Analysis Estimation involves the computation of the relevant parameters on the basis of sample data. There is a powerful analogy between the decomposition methods reviewed here and treatment effect analysis. Both fields of inquiry rely on the same fundamental identification strategy, and the structural effect is known to be equivalent to the treatment effect on the treated. This analogy has led to the development of flexible estimation methods for endowment and structural effects. Nonparametric estimation methods, such as IPW, allow an analyst to decompose distributional changes without having to assume a functional form for the outcome model. The downside, however, is the inability to further decompose the structural effect and to account for behavior. Parametric methods are more suitable for these two tasks. Toward Fuller Causal Interpretations of Decomposition Results Although the analogy between decomposition methods and treatment effect analysis has helped with the development of estimation methods, it does not necessarily confer a causal interpretation to decomposition results. As noted by counterfactual Ferreira (2010), such an interpretation requires the construction of ­ outcome distributions that are fully consistent with a general equilibrium of the economy. One way of achieving this consistency is to base decomposition on a full structural model of behavior and social interaction. Such a model can be built by embedding a behavioral model, such as the Roy (1951) model of choice and consequences, in a general equilibrium framework. Finally, we note that the generalization of the Oaxaca-Blinder decomposition to the analysis of variation in other distributional statistics such as quantiles, poverty, and inequality measures enables an analyst to study the distributional and poverty impacts of an assigned intervention. Notes 1. Roughly speaking, a functional is a function of a function. In this particular context, it is a rule that maps every outcome distribution in its domain into a real number (Wilcox 2005). 2. In particular, Bourguignon and Ferreira (2005) argue that the configuration of income distribution at one point in time is determined by the following factors: (a) the distri- bution of factor endowments and sociodemographic characteristics among the Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 100 Counterfactual Decomposition of Changes in Poverty Outcomes population; (b) the returns to these assets and characteristics; and (c) the behavior of socioeconomic agents with respect to resource allocation subject to prevailing institu- tional arrangements. 3. An alternative expression is based on this counterfactual: E(x0)b1. The corresponding decomposition is ∆O µ  β1 + E ( x 0 )   E ( x1 ) − E ( x 0 )  =  β1 − β 0  . 4. To further appreciate the importance of the identifying assumptions, note that the process of reweighing adjusts the distribution of the covariates x in period t = 0 so that it becomes similar to that in period t = 1. For this adjustment to help us identify the terms of the decomposition, it must be a ceteris paribus adjustment. Because y0 = j0(x, e), the ceteris paribus condition would be violated if changing the distribution of x also changed either the function ϕ0(∙) or the conditional distribution of ε given x. This would confound the impact of the adjustment, and the decomposition would be meaningless. Changes in the structural function are ruled out by the simple treatment assumption (no general equilibrium effects), while those in the conditional distribu- tion of ε are ruled out by the ignorability assumption. Under these circumstances, we expect the conditional distribution of y0 given x to be invariant with respect to adjustments in the distribution of the observable factors x. See Fortin, Lemieux, and Firpo (2011) for a more formal presentation of this argument. 5. This can be expressed with an indicator function as follows: Dy(u) = I( y < u). Recall that an indicator function is equal to one when its argument is true and equal to zero ∞ ∞ v otherwise. In particular, ∫∆ 0 y ( v ) f ( y ) dy = ∫I ( y ≤ v ) f ( y ) dy = ∫ f ( y ) dy = F ( v ) . 0 0 6. Essama-Nssah and Lambert (2012) show how to derive the influence function of a functional from the associated directional derivative. They present a collection of influence functions for social evaluation functions commonly used in assessing the social impact of public policy. 7. Wilcox (2005) explains that continuity alone confers only qualitative robustness to the statistic under consideration. A continuous function is relatively unaffected by small shifts in its argument. Similarly, differentiability is related to infinitesimal robustness in the sense that if a function is differentiable and its derivative is bounded, then small variations in the argument will not result in large changes in the function. Thus a search for robust statistics can focus on functionals with bounded derivatives. 8. This is analogous to the approximation of a differentiable function at a point by a Taylor’s polynomial. 9. In particular, b1 and b0 may differ just because their estimation is based on different distributions of the covariates x, even if the outcome structure remains unchanged (Firpo, Fortin, and Lemieux 2009). 10. For details, see Fortin, Lemieux, and Firpo (2011). 11. Essama-Nssah, Saumik, and Bassolé (2013) use both linear and nonlinear RIF regres- sion models in their study of growth incidence in Cameroon. They find that linear models lead to results that are qualitatively similar to nonlinear specifications. This is a significant methodological finding that should comfort analysts who might worry about the quality of the linear approximation underlying the simple RIF regression approach. 12. To see what is involved, write the conditional mean outcome as E( yt|xt;bt), t = 0,1. The counterfactual mean outcome when endowments in period 1 are valued under the (reward) regime of period 0 is equal to the following: E y1 c ( |x1; β 0 . The observed ) Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 101 difference in mean outcomes can therefore be decomposed as follows: ∆Oµ =  E y1  c ( ) |x1; β 0 − E ( y0 |x 0 ; β 0 )  +  E ( y1|x1; β1 ) − E y1   c ( ) |x1; β 0  . This expression is  analogous to equation (4.3). The first term on the right-hand side is the composition effect, and the second term is the structural effect. This is an aggregate decomposition. 13. To see where this expression comes from, let qt be the τth quantile of F. Also, let qt (b) stand for the τth quantile of the mixed distribution G so that G = bH(qt (b)) + (1 − b) F (qt (b)) = t and qt (0) = qt . The first-order derivative of G with respect to b, evalu- ′ ( 0 ) = 0. Hence ated at b = 0, yields the following expression: H ( qτ ) − F ( qτ ) + f ( qτ ) qτ the directional derivative of this quantile in the direction of H is equal to F ( qτ ) − H ( qτ ) τ − H ( qτ ) qτ′ (0) = = . Setting H(qt ) = Dy(qt ) = I( y ≤ qt ) implies that f ( qτ ) f ( qτ ) τ − I ( y ≤ qτ ) the influence function of the τth quantile of F is equal to IF ( y; qτ , F ) = . f ( qτ ) For more details, see Essama-Nssah and Lambert (2012). 14. See Essama-Nssah, Saumik, and Bassolé (2013) for an application. 15. This is the effect of a counterfactual change in the marginal distribution of a single covariate on the unconditional distribution of an outcome variable, ceteris paribus. Rothe (2010) interprets the ceteris paribus condition in terms of rank invariance. In other words, the counterfactual change in the marginal distribution of the relevant covariate is constructed in such a way that the joint distribution of ranks is unaffected. 16. The components of a detailed decomposition are easily computed by replacing (a) the expected values with the corresponding sample means, and (b) the coefficients associ- ated with the covariates with their OLS estimates. An estimate of the endowment m ∑(x q effect is ∆ X = ( x1 − x 0 ) β 0 = 1k − x 0 k ) β 0 k. Similarly, for the structural effect, we k =1 m q ( have the following expression: ∆ S = x1 β 1 − β 0 = β 11 − β 01 + ) ( ) ∑x (β 1k 1k ) − β 0k . k=2 17. This account draws on Essama-Nssah and Bassolé (2010). 18. To clarify our notation, we consider the simplest case where x represents a single characteristic. No loss of generality is involved. The marginal distribution of y is equal mx to ft ( y ) = ∫ J ( y, x ) dx, where mx stands for the maximum value of x. Equivalently, 0 t mx ft ( y ) = f gt ht ( y) = ∫ g ( y|x ) h ( x ) dx. The counterfactual used in equation (4.22) is 0 t t mx 1 therefore defined as follows: f gh0 = ∫g 0 0 ( y|x ) h1 ( x ) dx. This expression can be derived mx from the marginal outcome distribution in the initial period, f0 ( y ) = ∫g 0 0 ( y|x ) h0 ( x ) dx , by replacing h0(x) with h1(x). For this operation to lead to a meaningful counterfac- tual, two invariance conditions must be met. The conditional distributions gt( y|x) must be invariant with respect to changes in the marginal distribution of observables, ht(x). This would be the case if there are no general equilibrium effects. The distribu- tion of unobservables must be at least conditionally independent of that of observ- ables. Ignorability guarantees this. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 102 Counterfactual Decomposition of Changes in Poverty Outcomes 19. A histogram is “a representation of a frequency distribution by means of rectangles whose widths represent class intervals and whose areas are proportional to the cor- responding frequencies” (online version of the Merriam-Webster Unabridged, http:// unabridged.merriam-webster.com/). 20. Deaton (1997) further explains that the size of the bandwidth is inversely related to the sample size. The larger the sample size, the smaller the bandwidth. To obtain a consistent estimate of the density at each point, the bandwidth must become smaller at a slower rate than the rate at which the sample size is increasing. However, with only a few points, we need large bands to be able to get any points in each. By widen- ing the bands, we run the risk of biasing the estimate by bringing into the count data that belong to other parts of the distribution. Hence, the increase in the sample size does two things: It allows the analyst to reduce the bandwidth and hence the bias in estimation (due to increased mass at the point of interest). It also ensures that the variance will shrink as the number of points within each band increases. 21. Deaton (1997) argues that the choice of the bandwidth or the smoothing parameter is more important than that of the kernel function. Essentially, estimating densities by kernel methods is an exercise in smoothing the sample observations into an estimated density. The bandwidth controls the amount of smoothing achieved. Oversmoothed estimates are biased, while undersmoothed ones are too variable. 22.  f y0 |t =1 − f y0 |t = 0  The equivalent expression for the decomposition is ∆f =   f y1 |t =1 − f y0 |t =1  +   f y0 |t =1 − f y0 |t = 0  ∆f =   f y1 |t =1 − f y0 |t =1  + . 23. In the context of treatment effect analysis, the assumption of rank preservation, also known as rank invariance, is used to identify quantile treatment effects (QTE). The assumption implies that given two mutually exclusive states of the world, the out- come at the τth quantile of the outcome distribution in one state has its counterpart at the same quantile of the outcome distribution in the alternative state. Bitler, Gelbach, and Hoynes (2006) explain that when this assumption fails, the QTE approach identifies and estimates the difference between the quantiles and not the quantiles of the difference in outcome distributions. Rank preservation is akin to ­ anonymity or symmetry used to base growth incidence analysis on cross-section data instead of on panel data. Anonymity implies that when comparing two outcome dis- tributions, the identity of the individual experiencing a particular outcome is irrele- vant (Carneiro, Hansen, and Heckman 2002). Thus, a permutation of outcomes between any two individuals in any of the two distributions being compared has no effect on the comparison. One might as well then compare such distributions across quantiles. 24. Recall that ignorability means that the conditional distribution of e is the same across groups (or periods). Thus individuals with the same set of observable characteristics find themselves at the same rank in both (conditional) distributions. It is well known that a monotonic transformation preserves order. In fact, Rapoport (1999) defines a monotone transformation as “a formula that changes the numbers of one set to the numbers of another set while preserving their relative positions on the axis of real numbers.” Since ut is obtained from e through a monotonic transformation zt(·), rank preservation must therefore follow. y b ( ) 25. Note that the structural effect can also be expressed as ∆ S = yi1 − yi 0 . In the notation associated with equation (4.2), linearity and rank preservation imply that yib0 corre- sponds to the counterfactual outcome obtained by replacing the outcome structure ϕ1(∙) with ϕ0(∙). In other words, yib0 is the same as y0|t = 1. This suggests that the Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Counterfactual Decomposition of Changes in Poverty Outcomes 103 Juhn-Murphy-Pierce (1993) decomposition can be performed in two steps as follows: y Start with the overall difference ∆O = ( yi1 − yi 0 ) and then add to and subtract from this difference the counterfactual outcome yib0. This yields a twofold decomposition of the overall difference into the composition and structural effects. Finally add to and c subtract from the structural effect the counterfactual outcome yi 0. This step leads to the final threefold decomposition. Ignorability guarantees that the composition effect is due solely to changes in the distribution of observables. 26. Indeed, Fortin, Lemieux, and Firpo (2011) provide a systematic interpretation of decomposition methods within the logic of program impact evaluation. 27. According to Fortin, Lemieux, and Firpo (2011), these assumptions include the following: (a) The groups are mutually exclusive. (b) The outcome structure is an ­ additively separable function of characteristics. (c) The conditional mean for unob- servables given observed characteristics is equal to zero. (d) There is common support for the distributions of characteristics across groups (to rule out cases where argu- ments of the outcome function may differ across groups. (e) There is simple counter- factual treatment, meaning that the outcome structure of one group is assumed to be equilibrium a counterfactual for the other group. This last assumption rules out general ­ effects so that observed outcomes for one group or time period can be reasonably used to construct counterfactuals for the other group or time period. The Oaxaca-Blinder method therefore follows a partial equilibrium approach. 28. Heckman and Smith (1995) explain that the mean outcome of the control group provides an acceptable estimate of the counterfactual mean if (a) randomization does not alter the pool of participants or their behavior and (b) no close substitutes for the experimental program are readily available. These authors further note that random- ization does not eliminate selection bias, but rather balances it between the two samples (participants and nonparticipants) so that it cancels out when computing mean impact. There would be randomization bias if those who participate in an experiment differ from those who would have participated in the absence of random- ization. Furthermore, substitution bias would occur if members of the control group can easily obtain elsewhere close substitutes for the treatment. 29. Recall that the identification of the two components of the aggregate Oaxaca-Blinder decomposition relies on the zero-conditional-mean assumption for the unobservable factors stated as E(¨|x) = 0. This condition is what allows the analyst to claim that on average, variation in x is unrelated to variation in the unobservables, a manifestation of ceteris paribus variation. 30. The expression of this probability can be made more precise by considering an indica- tor function for the decision rule. The indicator is equal to one when option k is chosen and zero otherwise. The probability that the agent chooses option k is then equal to the expected value of this indicator function over all possible values of the unobserved factors. In other words, Phk = I  ∫ ( ) ( )  ε hj − ε hk < v hk − v hj ∀j ≠ k  f ( ε h ) dε h .  This is in fact a multidimensional integral over the joint density of the random vector, the elements of which represent unobserved factors associated with each alternative. This probability can be interpreted as the proportion of people within the population who face the same observable utility as h for each alternative and choose k (Train 2009). 31. The generalized extreme value model (GEV) allows correlation among unobserved factors. The standard multinomial logit assumes that the random factors are iid with a double exponential distribution. The probit model assumes that the random factors Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 104 Counterfactual Decomposition of Changes in Poverty Outcomes are jointly distributed normal variables. Train (2009) points out that the identification of discrete choice models relies heavily on the fact that only differences in utility matter and the scale of utility is irrelevant. Hence, only parameters that capture dif- ­ ferences across alternatives are identifiable and therefore estimable. This also implies that characteristics of the decision maker that do not vary across alternatives will have no effect unless they are specified in a way that induces differences in utility over alternatives. Glick and Sahn (2006) handle this problem by indexing the coefficients of sociodemographic variables in the representative utility function. 32. For agricultural households, earnings are computed on the basis of a reduced farm profit function (based on the Cobb-Douglas production function) that includes self- consumption and accounts for hired labor. 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Yun, Myeong-Su. 2009. “Wage Differentials, Discrimination and Inequality: A Cautionary Note on the Juhn, Murphy and Pierce Decomposition Method.” Scottish Journal of Political Economy 56 (1): 114–22. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Chapter 5 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction Introduction As chapter 3 found, labor market outcomes (in particular, labor income increases per working adult) were the main contributors to poverty reduction in a set of countries where poverty declined substantially during the past decade. A simple micro-decomposition methodology showed this to be true for moderate poverty lines and even extreme poverty lines in some cases. The next logical question is this: Why did total labor income increase—from improved human capital char- acteristics or from higher returns to those characteristics? To answer this ques- tion, an underlying model with additional structure is needed. A broad literature on micro-decomposition methodologies (which chapter 4 described in detail) aims to identify and estimate two effects associated with dis- tributional changes: the composition (or endowment) effect and structural (or price) effect. Either statistical or structural approaches can account for the contri- butions of these effects. Statistical approaches use semiparametric and nonpara- metric methods to identify the contributors to distributional changes without having to impose a functional form on the relationship between these changes and their determinants. However, the statistical framework cannot shed light on the mechanism underlying that relationship. In contrast, structural methods fur- ther identify the factors underpinning observed changes in poverty outcomes by specifying an economic model and using statistical analysis. In particular, these models account for behavior: how agents respond to changes in their socioeco- nomic environment, whether due to shocks or policy reform. The structural approach is followed below and in the next chapter (which will apply it in depth to three countries). In particular, this chapter presents a structure for modeling distributional changes over time. The approach rests on the typical economic assumption that agents seek to maximize their utility subject to con- straints. That assumption implies that the outcome variables of interest chosen to Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7   109   110 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction represent the consequences of behavior (such as educational or sectoral choice) can be expressed as functions of parameters of the socioeconomic environment, embedded in the constraints facing the agent. In particular, throughout this ­ chapter, we consider the Roy (1951) model of choice and consequences (which stems from the optimization principle and applies to discrete choice problems), using it to model individuals’ educational levels, sectors, and activity choices.1 We then adapt the Bourguignon, Ferreira, and Leite (2008) methodology to distinguish between distributional changes on account of (a) changes in endow- ments and the returns to those endowments; (b) changes in occupational and sectoral choice; (c) changes in geographical, age, and gender structure of the population; and (d) the nonlabor dimensions such as public transfers (the latter previously explored further in chapter 3). Therefore, the proposed model formulates an educational choice model, a sectoral choice model, an activity choice model, and individual and household earnings equations. Once all of these models are estimated for individuals and households in each time period, the estimated coefficients from one year can be replaced with the estimates from another year to simulate the impact of changes in each element at a time. For each change, we can construct a counterfactual income distribution and estimate a counterfactual poverty measure for compari- son with the observed outcome while holding everything else constant. By changing one element at a time, these decompositions allow us to account for the observed changes in poverty. Innovations in Cumulative Counterfactual Estimates In addition, we present an enhanced method to estimate these counterfactuals cumulatively, thereby accounting for the impact of concurrent changes. Although the method presented here draws heavily from Bourguignon and Ferreira (2005) and Bourguignon, Ferreira, and Leite (2008), it also offers some innovations: • It models farm household income at the household level and models the earn- ings of individuals in those farm households who have a secondary occupation, thus recognizing not only that farm households typically make labor decisions as a unit but also that these households can be highly diversified. • It assumes that welfare is measured using a consumption aggregate and accounts for the contribution of changes in the consumption-to-income ratio. • It ensures that changes in the composition of activities, sectors, and education of the work force are consistent with the counterfactual choices. As covered in chapters 2 and 3, such decompositions do not identify causal effects, but they are useful to focus attention on the elements that are quantita- tively more important in describing changes in poverty. In particular, they can capture the heterogeneity of impacts throughout the distribution and account for the contributions of demographic, sectoral, occupational, and other labor and nonlabor dimensions toward poverty reduction. After the next section presents the underlying model, the chapter describes the decomposition approach adopted here and concludes with a summary Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction 111 of the proposed model and its innovations. We implement this methodol- ogy in three countries around the world, the results for which we report in ­chapter 6. Modeling Strategy Following Bourguignon, Ferreira, and Leite (2008), our approach postulates a model in which characteristics such as age, gender, and geographic location are exogenously determined (and are taken as given), while education, employment activity, sector, and earnings are endogenous (determined within the model), as illustrated in figure 5.1. Therefore, the modeling strategy consists of six stages, each of which influences the next stage in the sequence: 1. Educational choice models 2. Sectoral and activity choice models 3. Farm and nonfarm earnings 4. Total household income, based largely on earnings 5. Household consumption, determined by total household income 6. A consumption-based calculation of the poverty rate Educational Choice First, individuals are distributed across educational levels and, further, as a func- tion of age, gender, area (urban versus rural), and region (defined as districts or provinces). This is done for all working-age individuals, following the Roy (1951) model, whereby individuals choose their educational level to maximize their utility. The allocation of individuals across levels of education is estimated with ­ a multinomial logit model (McFadden 1974a, 1974b), specified as follows: k I hi ( ) = 1 if Zhi y k + v ik > Max 0, Zhi y m + v im , j = 1,…,K, ∀m ≠ k (5.1) k I hi = 0 for all k = 1,…,K if Zhi y k + v ik ≤ 0 for all k = 1,…, K, where Zhi is a vector of characteristics specific to individual i and household h; ψk is a matrix with vectors of coefficients for each educational level, m; and v ik is a vector of random variables identically and independently distributed across individuals and activities according to the law of extreme values. Within a dis- crete utility-maximizing framework, Zhi y k + v ik is interpreted as the utility associated with educational level k, with v ik being the unobserved utility deter- minants of educational level k and the utility of no education being arbitrarily set to zero. We estimate the conditional distributions of educational levels for each survey year based on age group, gender, region, and area. They are estimated separately for household heads, spouses, and other working-age members. The result of this exercise is a model that estimates the probability of individuals obtaining a certain level of education. ­ Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 112 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction Figure 5.1 Model of Contributors to Poverty Reduction, by Stage Sequence Exogenous characteristics Endogenous characteristics – Age 1. Educational choice – Gender – Area – Region 2. Activity choice 3. Nonfarm Nonfarm – Paid employee earnings household – Employer/own acct. (modeled for – Unpaid family worker each individual) 4. Total household income 2. Sectoral choice Household – Agriculture type – Industry – Services 5. Household consumption 3. Farm 2. Sectoral choice earnings Farm 6. Poverty household (of secondary (modeled as measure occupation) net household revenue) Exogenous variables used to model education, Exogenous factors activity, sector, and earnings Type of household determined Household type outside the model Endogenous variables used to model earnings, Endogenous factors income, consumption, and poverty Note: The green boxes are numbered according to the typically sequential stages by which contributors to poverty are determined: 1. Educational choice; 2. Sectoral and activity choice; 3. Farm and nonfarm earnings; 4. Total household income; 5. Household consumption; and 6. Consumption-based poverty rate. Farm households are those whose heads are self-employed in agriculture. “Area” refers to whether the household is urban or rural. “Region” refers to districts or provinces. “Activity choice” refers to an individual’s occupational status, which may include paid employment (by hourly wages or salaried); self-employment; unpaid labor (typically for family needs); or unemployment. Sectoral and Activity Choices The second stage of the model structure begins with the separation of house- holds into farm and nonfarm categories, as shown in figure 5.1. Farm households are defined as those whose household heads are self-employed in agriculture. All other households are considered to be nonfarm households. This distinction allows us to model the nonfarm sector at the individual level, where workers choose the sector of work. Meanwhile, the farm sector is modeled at the house- hold level because farm households are likely to operate as a single unit of pro- duction, thus making labor decisions at the household level. In developing countries, people commonly engage in nonfarm microenter- prises and informal small-scale activities. Although these nonfarm businesses are Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction 113 often modeled at the household level (Haggblade, Hazell, and Reardon 2007, 2010), this modeling implies a trade-off: In particular, if earnings are modeled at the household level, accounting for the contribution to poverty reduction of changes in the population’s sectoral or occupational structure is impossible because such changes can be observed only at the individual level. Once households are divided between farm and nonfarm households, the second stage in the model is the allocation of individuals across work-activity types. In particular, following Roy (1951), individuals choose the sector and type of activity they are engaged in to maximize their utility. As above, this is esti- mated with a multinomial logit model, where j = {salaried, nonfarm self- employed, unpaid family worker, not employed}. Sectoral choice is also estimated this way, where j = {agriculture, industry, services}—modeled as a function of age, gender, area, region, and educational attainment. Recognizing that farm households often include members who work on non- farm activities (Davis et al. 2010), we model those individuals’ decisions to undertake secondary activities in order to capture this diversification into non- farm activities. We assume that the residuals are independently and identically distributed according to a logistic function (a logit model being the estimator of the diversification choice to have a secondary occupation or not) for all house- hold heads who are self-employed in agriculture. The probability of undertaking a secondary activity is modeled as a function of a vector of characteristics that includes individual and household variables such as age, gender, educational level, region, and areas, among others. Random terms are drawn conditional on the initial choice. Because both the sectoral and activity choices depend on individuals’ educa- tional levels, any simulated change in education will imply a change in the activ- ity and sectoral composition of the work force. Although the choice of sector and activity are likely simultaneous decisions, here they are modeled independently for tractability of the model. Earnings Models The third portion of the model structure is a set of earnings equations that serve to construct a counterfactual income distribution. For nonfarm households, we model the heterogeneity in individual earnings in each activity j by a log-linear Mincer model: j j log( yhi ) = QXhi Ω j + ε hi , (5.2) for i = 1, …, nh, and j = {salaried, nonfarm self-employed, not employed}. Qhi is a vector of individual characteristics, including (a) those determined outside the model (such as gender, area, and region), which we call Zhi, and (b) those deter- mined within the model (including education and sector), which we call Xhi. Ω j is a matrix of coefficients, and ε hi j are random variables assumed to be distrib- uted identically and independently across individuals according to the standard ­ ormal law.2 n Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 114 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction Individual earnings equations for nonfarm workers are estimated separately for household heads, spouses, and other members who are self-employed and salaried. The set of characteristics considered in the specification include age, gender, and education (among others) as well as characteristics of other house- hold members. For instance, in the case of spouses and other members, the speci- fications include characteristics of the household head (educational level, whether employed, and so on). Similarly, for members of farm households at the individual level, earnings from secondary occupations are e­ stimated as a function of the members’ individual characteristics (such as age, gender, educational level, and economic sector where they perform their secondary job). j In both cases, changes in income ( yhi ) could be due to changes in observable endowments (Xhi) or changes in the returns to those endowments (Ω j ). However, they could also occur because of changes in unobservables that are captured in the residual term. To capture these changes, we rely on the assumption that the residual terms are drawn from a standard normal distribution. Earnings of farm households are modeled as the net revenue at the household level: F log π h = Wh ΩF + ε h F , (5.3) where Wh = (Kh, Xh) includes endowments and household characteristics, Ω F is a vector of coefficients, and ε h F are random variables distributed as a standard normal. Farm households’ net revenues are estimated using ordinary least squares. The vector of characteristics includes endowments such as land and irrigation as well as the household head’s individual and household characteristics, including educa- tional level, gender, civil status, and number of members involved in the farm activ- ity, among other characteristics. To capture changes in unobservables, we rely on the assumption that the residual terms are drawn from a standard normal distribution. Total Income Finally (and as in chapter 2), the conditional distribution of nonlabor income is estimated nonparametrically—both as a total and by its different components such as remittances, public transfers, and other private transfers. For this purpose, we create cells of household heads of the same educational level, gender, and area (urban or rural). Inside of each cell, we create quantiles of nonlabor income, to which we then ascribe the mean value of each nonlabor income component in each quantile-cell in period s to its counterpart in period t. Given the labor and nonlabor incomes described above, total household income can be written as  yh + y h + π h + yh  Yh =  w se F NL  , (5.4) w where Y is household income per capita; yh and yh SE are total incomes from F salaried labor and self-employed nonfarm labor, respectively; π h ­ is the farm NL y household net revenue function; and h is household nonlabor income. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction 115 Given the choice models described above, this becomes  n n  yh =    ∑ i =1 w w I hi ( ) ∑I yhi Qhi , Ωw + i =1 se hi se yhi( ) ( Qhi , Ω se + π h F ) Wh , ΩF + yh NL  , (5.5)   w se where I hi and I hi are indicator variables that are equal to one if individual i in w household h is a salaried or self-employed worker. yhi and yhi se are the correspond- ing earnings of individual i in household h that depend on individual and house- hold endowments (Qhi) and the returns to those endowments (Ω), which vary w SE across types of activity. Individuals with earnings yh and yh are in the “nonfarm” sector, although this category comprises all salaried workers—including those in F agriculture—plus the nonfarm self-employed. For those in the “farm” sector, π h is household net revenue in farm activities, which depends on household endow- ments (Whi) and the returns to those endowments (Ω F ). Household Consumption Since household welfare is typically measured by consumption expenditures, we can write ϑh w Ch =  yh + yh se F + πh NL + yh   , (5.6) n  where Ch is household consumption per capita, n is the number of household members, and ϑh is the consumption-to-income ratio. Note that once we have defined a way to construct household consumption per capita at the household level, we can construct a distribution of consumption across households and then measure the poverty headcount rate or any other distributional measure. Poverty Headcount Rate The poverty headcount index measures the proportion of the population whose consumption falls below the poverty line. Formally, N P0 = 1 N ∑ I(C h =1 h < z ), (5.7) where N is the total population and I(·) is an indicator function that takes on a value of 1 if the bracketed expression is true and 0 otherwise. If consumption expenditure (Ch) is less than the poverty line (z), then I(·) equals 1 and the household would be counted as poor. Whenever any of the elements in the models described above changes, a new consumption distribution can be gener- ­ ated, and therefore a new poverty rate can be calculated. Similarly, any other distributional statistic can be calculated, including measures of inequality, such as the Gini or the Theil index, as well as other poverty measures, such as the pov- erty gap and the severity of poverty. Therefore, equations (5.1)–(5.6) fully characterize the underlying reduced- form models that will allow for the micro-decompositions of poverty. Next, there are two important steps. The first is the estimation strategy, and the second is the construction of counterfactual distributions. We turn to each of these steps in turn. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 116 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction Decomposition Approach Estimation Strategy After each of these reduced-form models has been estimated for years s and t, we decompose the distributional changes by substituting each of the parameters estimated for one year with the parameters of the other year and then by formu- lating the appropriate counterfactual distribution of income and consumption. Specifically, from equation (5.5) above, we estimate the components of house- hold income for times s and t: nh nh ∑ I  Qhi Ω + ε w ∑I  Q Ω se + ε se  w log( yh ) = t w ˆ hi + se ˆ hi hi   hi  hi  i =1 i =1 (5.8) F NL ˆ ) + log( y h ), + (Wh Ω + ε F h which, for simplicity, we express as follows:  log( yh )t = f  NF  Ω NF , Zhi , ε hi ,O  Ψ , Zhi t ˆt  t  t t t , Hhi t ˆ hi , X 2thi , v ,      (5.9) F  ΩF ,Wht , H h t ˆt  ˆ NL |t  , t ,ε h , y   h   t where NF(·) =  nonfarm earning equations, and Ω NF refers to the set of esti- mated parameters; t Zhi =exogenous variables such as age, gender, region, and area that are used for the earnings and choice models estimated at the individual level; t O(·) =  activity choice equations, and Ψ refers to the set of estimated ( ) t t parameters; H Xhi t ,q hi ,φ hi =  the underlying models for the sectoral and educational struc- t ture, where Xhi is a vector of endogenous variables including t sector ( X1hi ) and education ( X 2thi ), which are estimated at the individual level and then used in the activity choice model, t t with q1hi and q 2hi being the respective set of estimated parameters; t F(·) =  net farm revenue equations, and ΩF are the set of estimated parameters; Wht =  exogenous variables such as age, gender, region, and area for the farm net revenue model estimated at the household level; t t t t error terms for earning equations for nonfarm and farm sectors ε hi , ε h , v hi ,φ hi =  and endogenous variables such as educational structure, activity choice, and economic sector; and NL t yh | = nonlabor income. From here, we can perform marginal decompositions that consist of changing one component at a time, keeping everything else constant. After describing Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction 117 how this is done for each element, we briefly discuss the cumulative approach, which changes each additional component and adds to the total effect until all components are accounted for. It is important to note that all decompositions are performed considering s as the initial year and then considering t as the initial year. The average of these decompositions is the final result reported in the analysis.3 Construction of Counterfactual Distributions Changes in Poverty as a Result of Changes in Demographics The first decomposition consists of altering the joint distribution of exogenous household characteristics such as age, gender, region, and area of each individual in the household. Because these variables do not depend on any other variables in the model, one can think of this simulation as the one assuming the greatest degree of exogeneity. The simulation is performed simply by recalibrating the population of one year by the weights corresponding to the joint distribution of these attributes in the target year. In other words, the demographic characteristics of year t are weighted such that their structure replicates the demographic characteristics of year s. For example, if the share of women in year s is higher than in year t, then the weights in year t are modified so that in the simulation they replicate the structure observed in year s. Because demographic variables are determinants of the activity, sector, and educational choice models, the reweighed structure of these variables have direct and indirect effects on household income. The indirect effects are calculated by substituting the reweighed demographic variables into the estimated multino- mial logit equations to forecast a counterfactual activity, sector, and educational composition of the work force. These new sectors, educational levels, and activi- ties are then fed into the estimated earnings equations, along with the direct effect of changes in the demographic variables. Formally, the vector of variables Zhi in equation (5.9) for year t is substituted for that of year s as follows:4 log ( yh )X . Z ,W s →t (5.10) ( ( = f NF Ω t NF s , Zhi t ˆt , Hhi ) ( t , ε hi ,O y , Zhi s ) ( ˆ hi , X 2thi , v t t , F Ω ,Whs , Hh F t ˆt ) , ε h , yh NL t | ) The resulting income distribution is then transformed to a new distribution of consumption using equation (5.6) above, where the consumption-to-income ratio is kept constant. Given this new counterfactual distribution of consump- tion, any new distributional statistic can be computed. In this case, because we are interested in the contributions to poverty reduc- tion, we apply the poverty line for period t and calculate the counterfactual headcount poverty rate, P ( yh )s →t { X . Z ,W h } . The contribution of demographic changes to the observed change in poverty will be the difference between the Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 118 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction poverty rate for year t and the counterfactual generated by equation (5.10), which can be expressed as ∆PXs →t t , Z ,W = P yh − P ( yh )s { } →t X . Z ,W h . { } h Changes in Poverty as a Result of Changes in Structure of Activity Next, to account for changes in the structure of activity, the coefficients of the activity multinomial logit models for year t are replaced with those of year s. As a result, individuals are reallocated into different activities to conform to the structure observed in year s. To allow for individuals to change activities in the simulation, we must estimate the residual terms of the multinomial logit model (v is ) in equation (5.1), which are unobserved. As annex 5A describes in detail, these residuals must be drawn from an extreme value distribution in a way that is consistent with observed choices. In contrast to previous papers (Bourguignon, Ferreira, and Lustig 2005), we use the analytical solution to this problem derived by Train and Wilson (2008). With the new simulated structure of activity in year t, labor income is ­ projected using the estimated earnings equations for year t and the residuals drawn from a standard normal distribution. Specifically, the set of parameters t s estimated at time t, y , are substituted by those estimated at time s, y , maintain- ing ­ everything else constant. This new structure of activities is then used to obtain a ­ counterfactual distribution of income as follows: log ( yh )Ψ s →t ( ( t t = f NF Ω NF , Zhi t , Hhi ˆ hi ,ε t ) ( t ,O Ψ , Zhi S ˆ hi , X 2thi , v t ), (5.11) ( t F Ω ,W , H , ε F ˆ h t t h NL h ) , y | ). NL t h The resulting counterfactual total household income distribution can then be transformed to a new distribution of consumption using equation (5.6) above, where the consumption-to-income ratio is kept constant. This counterfactual distribution of consumption can be compared with the actual distribution in (5.9). We calculate the counterfactual poverty rate and take the difference from the poverty rate found in period t to obtain the contribution to poverty reduc- tion: ∆Pys →t { }t = P yh h { s →t − P ( yh )y ) . }h Changes in Poverty as a Result of Changes in Education and Sectoral Composition Similarly, to account for changes in the educational structure or in the sectoral composition of employment, we use the coefficients from the estimated multi- nomial logit models. For instance, to account for changes in poverty due to t changes in the sectoral composition of the work force, we substitute the q1hi s parameters in the sectoral equation for time t, with q1hi . To allow for individuals to change sectors in the simulation, the residual terms in the sectoral Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction 119 multinomial logit model are taken from an extreme value distribution, as described in annex 5A. This will produce a simulated sectoral structure, which will in turn affect nonfarm incomes as well as farm incomes given that we allow for individual choice in secondary occupation. We obtain the counterfactual income distribution as follows: s →t ( ( log ( yh )Θ1 = f NF Ω NF , Zhi t S , Hhi t ( Θ1hi , ε hi , O Ψ , Zhi t S ) ) ( t , X 2thi , v hi , S t ) (5.12) ( t F Ω , Wht , Hh F S Θ1h s ,ε ( ) t h ), y | ), NL t h which can be transformed to a new distribution of consumption using equation (5.6) above, as before, thus generating a new poverty rate that can be compared with the actual. To account for changes in poverty due to changes in education, the process is slightly more complicated because education affects both occupational struc- ture and earnings. As a result, we substitute the parameters for the educational s t choice equation estimated in time s, q 2hi , with those estimated for time t, q 2hi , in the H function. As before, to allow for individuals to change educational levels in the simulation, the residual terms in the educational multinomial logit model are taken from an extreme value distribution, as described in annex 5A. Because education affects the choice of activity, the composition of activity across the distribution needs to be simulated. The resulting new distribution of activities is then introduced into the earnings functions, along with the new educational structure, and we obtain the following income counterfactual distribution: s →t ( ( log ( yh )Θ2 = f NF Ω NF , Zhi , Hhi Θ 2hi , ε t S t ˆ hi t t( ,O Ψ , Zhi hi , Θ 2hi v , X 2S S ) ) ( ˆ hi t , (5.13) S ( S ) ) ( t F ΩF ,Wht , H h t ˆh Θ 2h , ε t ( s NL t , yh | . ) ) ) This counterfactual distribution can then be transformed to a new distribution of consumption using equation (5.6), as before, and compared with the actual distribution in equation (5.9). The contribution of the change in educational structure to the change in poverty between s and t can be estimated by the dif- ference between poverty indices of the actual (equation [5.9]) and counterfac- tual (equation [5.13]) distribution: ∆PΘ s →t 2 = P yh t − P ( yh )Θ2 . s →t { }h { } h The difference between the distributions generated by the series of changes in demographics, educational structure, sector choices, and activity choices is comparable to the endowment effect in the standard Oaxaca (1973) and Blinder (1973) decomposition. This difference is that, in each case, a new Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 120 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction counterfactual distribution is generated, and as a result we can look at the contributions to any distributional summary statistic, including changes in poverty. Changes in Poverty due to Changes in Returns to Endowments Poverty rates may have changed not only because of changes in endowments but also because changing market conditions may have changed the returns to existing endowments. For instance, higher educational attainment would likely increase incomes and therefore reduce poverty. However, if the supply of edu- cated workers outpaces the demand for such workers, the premium for having higher educational levels would fall, and thus the returns to higher education likely would also fall. This idea is often associated with Tinbergen’s (1975) “race” between technological progress (which he saw as raising the demand for skills) and the expansion of formal education, which raises the supply of skills (Ferreira 2012). To ascertain the extent to which changes in the returns to endowments con- tributed to poverty reduction, we simulate the counterfactual household income distribution by substituting the estimated returns to individual and household characteristics (Ω) computed for period s into the earnings of every household at time t, holding everything else constant: ( ( log ( yh )Ω = f NF Ω NF , Zhi s →t S t t , Hhi t ) ( , ε hi ,O Ψ , Zhi t t , X 2thi , v hi , t ) (5.14) ( S F Ω ,W , H , ε , y F h t t h t h ) NL t h | . ) This simulation yields the earnings of each household in the sample if the returns to each observed characteristic had been those observed at time s rather than the actual returns observed at time t, keeping everything else constant.5 The contribution to the overall change in the distribution assigned to a change in returns (Ω s →t ) between periods s and t can be obtained by comparing equation (5.9) with equation (5.14). Therefore, the effect of a change in endowment returns on a change in poverty is ∆PΩ s →t t = P yh { } h s →t − P ( yh )Ω h { . } The difference between this simulated distribution of household incomes, { i }Ω y s →t , and the actual distribution is equivalent to the price effect in the standard Oaxaca (1973) and Blinder (1973) decomposition. Changes in Poverty due to Unobservable Factors Note that, up to this point, we have accounted for changes in the distribution due to observable factors. However, it is likely that factors that are unobserv- able at the household and individual levels nevertheless affect the distribu- tion of consumption and therefore affect changes in poverty. Although we cannot ­ completely capture these effects, we can simulate the effect of changes in the residuals in the earnings equations.6 To do so, we rescale the Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction 121 estimated residuals of the earning and net revenue equations for nonfarm and farm workers of time t by the ratio of their standard deviations. This counter- factual is defined as follows: log ( yh )ε s →t   t t = f  NF  Ω NF , Zhi  t ˆt  σ ε  , H hi  ˆS  , ε hi  t   ,O Ψ , Z hi σˆ   t t ( ˆ hi , X 2thi , v t , )  ε (5.15)  t ˆ S  NL  t ˆt  σ ε  F  ΩF ,Wht , H h , ε h  t   , yh |t  .  σˆε   The contribution to a change in poverty from a change in unobservable factors (ε s →t ) can be obtained by calculating the poverty rate for the counterfactual distribution generated by equation (5.15) with the original poverty rate at time t as follows: ∆Pεs →t = P yh t { } s →t − P ( yh )ε h . { } h Changes in Poverty as a Result of Changes in Nonlabor Income To account for changes in nonlabor income, the nonparametric technique first described in chapter 2 can be used. To do so, cells of household heads with the same educational level, gender, and area (urban or rural) must be created. Then, quantiles of nonlabor income must be created for each cell. The counterfactual distribution of nonlabor income in year t is estimated by assigning the mean value of nonlabor income of quantile q in cell c in year s, to the same quantile and cell in year t. In other words, we rank the two distributions by per capita household nonlabor income, and if q is the rank of a household with NL income yh at time t, we replace it with the nonlabor income of the household with the same rank at time s. This counterfactual distribution can be expressed formally as follows: s →t ( ( log ( yh ) y NL = f NF Ω NF , Zhi S t t , Hhi t , ε hi O Ψ , Z hi S ) ( , X 2S t ˆ hi hi , v t , ) h (5.16) ( t F Ω ,WhS , Hh t F ,ε t h ), y NL S h q ) | . As before, we can compare with the actual distribution described in equation (5.9), calculate poverty indices, and obtain the contribution of nonlabor income →t to poverty change between years s and t as follows: ∆PysNL t = P yh h { } h { − P ( yh )sy→ NL h t }. h Changes in Poverty as a Result of Changes in Consumption-Income Ratio Finally, it is important to note that each of the counterfactual distributions simu- lated so far assumes that the consumption-to-income ratio in period t remains constant. However, in practice, this ratio could change either because of changes in households’ savings rates or changes in measurement error. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 122 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction To account for changes in the consumption-income ratio, the nonparametric technique described above can be used. In particular, cells of household heads with the same level of education, gender, and area (urban or rural) must be created. Then, quantiles of consumption must be created for each cell. The counterfactual distribution of the consumption-to-income ratio in year t is estimated by assigning the mean value of this ratio for quantile q in cell c in year s to the same quantile and cell in year t. In other words, we rank the two distributions by consumption, and if q is the rank of a household with con- sumption-to-income ratio ϑ ht at time t, we replace it with the consumption-to- income ratio of the household with the same rank at time s. Equation (5.6) then becomes ϑh s s →t Ch =  yh t  , (5.17) n   which creates a counterfactual distribution from which a new poverty rate can be calculated and compared with the poverty rate obtained in period t. The Cumulative Decomposition Technique All of the decompositions described above can be done on their own, holding everything else constant. We refer to the results from that analysis as the marginal effects. However, as mentioned before, all of these changes are likely to occur over the course of a decade. Moreover, the effects of interaction between these elements could be important in accounting for the changes in poverty. For instance, changes in the educational composition could reinforce changes in the sectoral composition of employment. Therefore, it is important to take these potential interactions into account. The cumulative decomposition technique allows us to account for these inter- actions by calculating each effect successively and cumulating them into a set of counterfactuals that contain the cumulative effects of multiple changes. We attribute all of the additional contribution to poverty change to each specific factor successively being added. As described in chapters 2 and 3, it is important to note that the magnitude of the contribution will depend on the path chosen for the ­ decomposition. However, the large number of factors involved in calculating Shapley values (from s to t and vice versa) is beyond the scope of this chap- ter. Instead, we use theory to better inform the path to be adopted. In ­particular, we follow Bourguignon, Ferreira, and Leite (2008) by first calculating the effects of changes in the characteristics of the population— beginning with the most exogenous variables (such as age, gender, region, and area) and following with changes in the population’s sectoral, educa- tional, and activity structure. With these results, we then calculate the changes in farm and nonfarm earnings resulting from changes in the returns to these characteristics, the changes in nonlabor incomes, and the changes in the consumption-to-​ income ratio.7 Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction 123 Final Remarks This chapter has presented a methodology to account for the finding in c ­ hapter 3 that total labor income increased across countries where poverty declined sub- stantially over the past decade. As chapter 4 then described in detail, there are both statistical and structural approaches to account for the contribution of endowment and price effects in explaining distributional changes. In contrast to statistical methods, structural methods aim to account for the factors underpin- ning observed changes in poverty outcomes by specifying an economic model while also incorporating statistical analysis. In particular, these structural models take into account the behavior of agents in response to changes in their socioeco- nomic environments. The approach proposed in this chapter rests on the typical economic assump- tion that agents seek to maximize their utility subject to constraints. In particular, throughout this chapter, we consider the Roy (1951) model of choice and con- sequences, which stems from the optimization principle and applies to discrete choice problems. We use it to model individuals’ educational levels, sectoral (industry) choices, and activity choices or occupational statuses. These models are set up sequentially, so that changes in education affect ­ sectoral and activity choice. All of these, in turn, affect earnings, which are modeled separately for nonfarm individuals (in the form of standard Mincer equations) and as net revenue functions for farm households. This setup allows us to distinguish between distri- butional changes resulting from changes in endowments and those resulting from returns to those endowments (following Bourguignon, Ferreira, and Leite [2008]). Once all of these models are estimated for individuals and households in each time period, the estimated coefficients from one year can be replaced with the estimates from another year to simulate the impact of changes in each element at a time. The resulting series of counterfactual income distributions can then be used to estimate a counterfactual poverty measure for comparison with the observed outcome while holding everything else constant. By changing one ele- ment at a time, these decompositions allow us to account for the observed changes in poverty. In addition, we present a method to estimate these counter- factuals cumulatively, thereby accounting for the impact of concurrent changes. The method presented here makes some important innovations relative to previous work. First, it models farm income at the household level and models the earnings of individuals in those farm households who have secondary occu- pations, thus recognizing both that farm households typically make labor deci- sions as a unit and that these households can be highly diversified. Second, it measures welfare using a consumption aggregate, thus accounting for the contri- bution of changes in the consumption-to-income ratio. Finally, it ensures that changes in the composition of the work force’s activity, sectoral, and educational choices are consistent with the counterfactual choices. The next chapter concludes the volume by applying the methodology pre- sented in this chapter to three countries that reduced poverty drastically between 2000 and 2010: Bangladesh, Peru, and Thailand. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 124 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction Annex 5A: Estimating the Residual Term in Multinomial Logit The allocation of individuals across activities is represented through a multino- mial logit model. To calculate the utility of activity s and therefore allow for people to change activities in the simulation exercise when either Zhi or y s changes, we must estimate the residual terms of the choice model (v is ), which are unobserved. The residual terms must be drawn from extreme value distributions in a way that is consistent with the observed choices. Train and Wilson (2008) define the distribution functions of the extreme value errors conditional on the chosen alternative. In particular, assume that the alternative zero is chosen (j = 0), and J ∑ exp  −V , j 0j 0j j 0 denote Zhi Ψ = V for j = 0,…, J. Define V = V − V and D = 0 j hi hi hi hi hi hi  j=0 0 0 where Phi = 1 Dhi is the logit choice probability. Then the cumulative distribu- 0 tion function (cdf ) for the alternative chosen v hi is ( 0 F v hi ) 0 |alternative 0 is chosen = exp( − Dhi 0 exp Vhi . (5A.1)( ) Calculating the inverse of this distribution, we have ( ) ( ) − ln − ln ( µ ) , (5A.2) 0 0 v hi = ln Dhi where μ is drawn from a uniform distribution between zero and one. Error terms j for other alternatives v hi with j ≠ 0 must be calculated conditioned on the error terms of the alternative chosen (v 0 hi j ). The distribution for these errors is ( j F v | alternative 0 is chosen, j ≥ 1 = ) ( j exp −exp v hi ( )) hi  0  (5A.3)  exp  −exp  −  V hi + v hi    0j     j  0j 0  for v hi <  V hi + v hi  . The inverse of this distribution is j  v hi = − ln  − ln  m v hi µ   , (5A.4)    0 ( )  ( ) 0  where m v hi = exp  − exp  −  V hi + v hi    , and m is drawn from a uniform dis-     0j 0   tribution between zero and one. We repeat this same method when an alterna- tive other than zero is chosen. A similar approach is taken for the sectoral and educational choice models. Annex 5B: The Cumulative Decomposition Technique The cumulative decomposition technique allows us to account for these interac- tions by calculating each effect successively and cumulating them into a set of counterfactuals that contain multiple changes. We attribute all of the additional contribution to poverty change to each specific factor being added. However, the Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction 125 magnitude of that contribution will depend on the path chosen for the decom- position. We follow the path suggested by Bourguignon, Ferreira, and Leite (2008)—creating a cumulative counterfactual distribution from which poverty headcount rates can be calculated at every point in the adopted path and com- pared with the actual poverty rates to estimate the contribution of each addi- tional change on the observed change in poverty. We begin by calculating the effects of changes in the characteristics of the population, beginning with what we consider to be the most exogenous variables, s including age, gender, region, and area ( Zhi , Whs ). Specifically, first we reweigh the demographic characteristics of year t in such a way that their structure rep- licates the demographic characteristics of year s as follows: {( ( ∆P s →t = P f NF Ω NF , Z hi t t ˆt , Hhi , ε hi ,O Ψ , Z hi t t t , H hi ˆ hi ,v t , ) ( t ) ( t ˆt F ΩF ,Wht , Hh t , ε h , yh NL t |q ) )} h (5B.1) {( ( s − P f NF Ω , Z hi t ˆt , Hhi , ε hi ,O Ψ , Z hi s t , H hi NF t ˆ hi ,v t , ) ( t ) ( t ˆt F ΩF ,Whs , Hh t , ε h , yh NL t |q h . ) } Second, keeping the demographic effects, we add the education structure s change (Θ2hi ): {( ( s = P f NF Ω NF , Zhi , Hhi t t ˆt , ε hi ,O Ψ , Zhi s t , Hhi ˆ hi ,v t , ) ( t ) ( t t ˆt F ΩF ,Whs , Hh , ε h , yh NL t |q ) )} h   (5B.2) {( ( − P f NF Ω t NF ,Z ,Hs hi s hi (Θ1 ,Θ2 ) ,εˆ ) ,O ( Ψ , Z t hi s hi t hi t s hi s , H , Θ2 v hi ˆ s t hi hi ), ( t F ΩF ,Whs , Hh s ˆ hi Θ1hi , Θ2hi , ε t ( NL t , yh |q t s ) ) )} . h Third, preserving the previous changes, we include the change in occupation ( ) structure Ψ s : {( ( s = P f NF Ω NF , Zhi s , Hhi t ˆ hi Θ1hi , Θ2hi , ε t ( s ,O Ψ , Zhi s , Hhi t ˆ hi Θ2hi , v t , s ) ) ( t ( s ) ) ( t F ΩF ,Whs , Hh s ˆh Θ1hi , Θ2hi , ε ( t NL t , yh |q t s ) ) )} h {( ( (5B.3) − P f NF Ω t NF s ,Z ,H hi s hi (Θ1 ,Θ2 ) ,ε ) ,O ( Ψ , Z t hi s hi t hi s s hi s , H , Θ2 hi ( s hi ) , vˆ ) , t hi ( t F ΩF ,Whs , Hh s ˆh Θ1hi , Θ2hi , ε ( t NL t , yh |q t s ) ) )} . h Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 126 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction s Fourth, we add the change in the structure of economic sectors (Θ1hi ): {( ( s = P f NF Ω NF , Zhi s t , Hhi ˆ hi Θ1hi , Θ2hi , ε t s ,O Ψ , Zhi s , Hhi ( ˆ hi Θ2hi , v t t , s ) ) ( s ( s ) ) ( s F ΩF ,Whs , Hh t ˆh Θ1hi , Θ2hi ε t NL t , yh |q ( t s ) ) )} h   (5B.4) {( ( − P f NF Ω t NF ,Z ,H s hi s hi (Θ1 ,Θ2 ) ,εˆ ) ,O ( Ψ , Z s hi s hi t hi s s hi ,H s hi (Θ2 ) , vˆ )) , s hi t hi ( t F ΩF ,Whs , Hh s ˆh Θ1hi , Θ2hi ε t NL t , yh |q ( s s ) ) )} . h s Fifth, we include the returns to the nonfarm sector (Ω NF ): {( ( s = P f NF Ω NF , Zhi s , Hhi ˆ hi Θhi , ε t t s ,O Ψ , Zhi s , Hhi ˆ hi Θ2hi , v t ( ) ) ( s s ( s ) ) ( t s F ΩF ,Whs , Hh ˆh Θhi , ε t NL t , yh |q ( ) ) s )} h (5B.5) {( ( − P f NF Ω s NF ,Z ,Hs hi s hi (Θ ) ,εˆ ) ,O ( Ψ , Z s hi t hi s s hi ,H s hi (Θ2 ) , vˆ ) ,s hi t hi ( s F ΩF ,Whs , Hh t ˆh Θhi , ε t NL t , yh |q ( ) ) s )} . h s Sixth, we change the returns to the farm sector (ΩF ): {( ( s = P f NF Ω NF , Zhi s , Hhi ˆ hi Θhi , ε t s s ,O Ψ , Zhi s , Hhi ˆ hi Θ2hi , v t , ( ) ) ( s s ( s ) ) ( s F ΩF ,Whs , Hh t ˆh Θhi , ε t NL t , yh |q ( ) ) s )} h (5B.6) {( ( s − P f NF Ω NF , Zhi s , Hhi ˆ hi Θhi , ε t s s ,O Ψ , Zhi s , Hhi ˆ hi Θ2hi , v t , ( ) ) ( s s ( s ) ) ( s F ΩF ,Whs , Hh s ˆh Θhi , ε t NL t , yh |q ( ) ) s )} . h Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction 127 Seventh, we change residuals of both earnings and net revenues equations: {( ( s s = P f NF Ω NF , Zhi s , Hhi ( ) ) ( ˆ hi Θhi , ε t s s ,O Ψ , Zhi s s , Hhi ˆ hi Θ2hi , v t , ( s ) ) ( s s F ΩF ,Whs , Hh ( ) ) ˆh Θhi , ε s t NL t , yh |q )}h     s  s − P  f  NF  Ω NF , Zhi s , Hhi ( ) s ˆs  t  σε  ˆ hi Θhi , ε  σ t  ˆε  s ( s ,O Ψ , Zhi s , Hhi s (ˆ hi Θ2hi , v t ) ) , (5B.7)      s s F  ΩF ,Whs , Hh s ( ) ˆh Θhi , ε t  σε   ˆ s  NL ˆεt  , yh  |tq   .  σ  h Eighth, we add the change in nonlabor income components and the consump- tion ratio. The latter is not formally displayed in this example:     s ˆs   s s s  t  σε  t  Θhi  , ε s  Θ2hi  ,ν s s s = P  f  NF  Ω NF , Zhi , Hhi ˆ hi t  ,O y , Zhi , Hhi ˆ hi  ,    ˆ  σε           s s  ˆ s  NL t   t  σε   Θhi  , ε s F  ΩF ,Whs , Hhi ˆh t  , yh |q      σˆ  ε   h (5B.8)     s ˆs   s s t  σε  s  t  s  Θhi  , ε Θ2hi  ,ν s s s − P  f  NF  Ω NF , Zhi , Hhi ˆ hi  t  ,O y , Zhi , Hhi ˆ hi  ,    ˆ  σε          s s  ˆ s  NL s   t  σε   Θhi  , ε s F  ΩF ,Whs , Hhi ˆh  t  , yh |q   .    ˆ  σε  h Finally, we take into account changes in the consumption-to-income ratio as described in the main text. The cumulative counterfactual change in poverty and the observed change in poverty are compared. Any change that is not accounted for is described as a residual change. As before, the cumulative decomposition technique is performed both consid- ering s as the initial year and then considering t as the initial year. The average of these decomposition effects is the final result reported in the analysis. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 128 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction Notes 1. By “activity choice,” we refer to the individual’s occupational status, which may include paid employment, self-employment, unpaid labor, or unemployment. 2. Note that earnings may be underestimated to the extent that individuals opt out of the labor force because their reservation wage is lower than their market wage (Heckman 1979). Although this is a well-known bias, we do not attempt to correct for it given the complexity of the decompositions that follow. 3. Bear in mind that this approach does not solve all path-dependence problems. Shapley values must be estimated to tackle this difficulty. 4. The notation s → t refers to using the parameters estimated in period s in the equation for time t. ˆ t are assumed 5. The returns to the unobserved characteristics behind the residual term ε to be unchanged. 6. The estimated error terms for the multinomial logit models are not rescaled. 7. For a full description of the cumulative approach, please refer to annex 5B. Bibliography Blinder, Alan S. 1973. “Wage Discrimination: Reduced Form and Structural Estimates.” Journal of Human Resources 8 (4): 436–55. Bourguignon, François, and Francisco H. G. Ferreira. 2005. “Decomposing Changes in the Distribution of Household Incomes: Methodological Aspects.” In The Microeconomics of Income Distribution Dynamics in East Asia and Latin America, edited by François Bourguignon, Francisco H. G. Ferreira, and Nora Lustig, 17–46. Washington, DC: World Bank. Bourguignon, François, Francisco H. G. Ferreira, and Nora Lustig, eds. 2005. The Microeconomics of Income Distribution Dynamics in East Asia and Latin America. Washington, DC: World Bank. Bourguignon, François, Francisco H. G. Ferreira, and Phillippe G. Leite. 2008. “Beyond Oaxaca-Blinder: Accounting for Differences in Household Income Distributions.” Journal of Economic Inequality 6 (2): 117–48. Davis, Benjamin, Paul. Winters, Calogero Carletto, Katia Covarrubias, Esteban J. Quiñones, Alberto Zezza, Carlo Azzarri, Kostas Stamoulis, and Stefania DiGiuseppe. 2010. “A Cross-Country Comparison of Rural Income Generating Activities.” World Development 38 (1): 48–63. Ferreira, Francisco H. G. 2012. “Distributions in Motion: Economic Growth, Inequality, and Poverty Dynamics.” In The Oxford Handbook of the Economics of Poverty, edited by Philip N. Jefferson, 427–62. New York: Oxford University Press. Haggblade, Steven, Peter B. R. Hazell, and Thomas Reardon. 2007. Transforming the Rural Non-Farm Economy: Opportunities and Threats in the Developing World. Baltimore, MD: Johns Hopkins University Press. ———. 2010. “The Rural Non-Farm Economy: Prospects for Growth and Poverty Reduction.” World Development 38 (10): 1429–41. Heckman, James J. 1979. “Sample Selection Bias as a Specification Error.” Econometrica 47 (1): 153–61. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Why Has Labor Income Increased? An In-Depth Approach to Understanding Poverty Reduction 129 McFadden, Daniel. 1974a. “Conditional Logit Analysis of Qualitative Choice Behavior.” In Frontiers in Econometrics, edited by Paul Zarembka, 105–42. New York: Academic Press. ———. 1974b. “The Measurement of Urban Travel Demand.” Journal of Public Economics 3 (4): 63–82. Oaxaca, Ronald L. 1973. “Male-Female Wage Differentials in Urban Labor Markets.” International Economic Review 14 (3): 693–709. Roy, Arthur D. 1951. “Some Thoughts on the Distribution of Earnings.” Oxford Economic Papers 3 (2): 135–46. Tinbergen, Jan. 1975. Income Differences: Recent Research. Amsterdam, the Netherlands: North-Holland. Train, Kenneth E., and Wesley W. Wilson. 2008. “Estimation on Stated-Preference Experiments Constructed from Revealed-Preference Choices.” Transportation Research Part B: Methodological 42 (3): 191–203. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Chapter 6 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand Introduction The decomposition method proposed in chapter 2 and implemented in c ­ hapter 3 distinguished labor income growth as the main contributor to poverty reduction. However, the method’s main limitation is that it cannot explain why labor incomes increased: Did they grow because the populations increased their own human capital endowments (such as higher educational levels or other produc- tive assets) or because of changes in returns to those endowments? For this answer, we have turned to an alternative decomposition technique that imposes an underlying labor model and greater structure. This chapter implements chapter 5’s proposed approach: to distinguish between distributional changes on account of (a) changes in endowments and the returns to those endowments; (b) changes in occupational and sectoral choice; (c) changes in the population’s geographical, age, and gender structure; and (d) the contribution of the nonlabor income dimensions (such as public transfers, remit- tances, and other private transfers) previously explored in chapter 3. This micro- decomposition approach is adapted from Bourguignon, Ferreira, and Leite (2008). In focusing on Bangladesh, Peru, and Thailand, the chapter highlights their impressive reductions in poverty while taking advantage of the availability, com- parability, and transparency of their microdata. The moderate national poverty headcount rate in each of these countries fell by more than 12 percentage points during the past decade, partly because of high gross domestic product (GDP) growth, which was well above 4 percent per year during the 2002–08 period.1 In the cases of Peru and Thailand, GDP sharply decelerated in the wake of the financial crisis in 2009, only to rebound quickly the following year. In contrast, GDP growth in Bangladesh got through the crisis unscathed. In all three countries, employment and public social transfers increased, as did remittances. However, the changing patterns of income distribution varied across countries, as did the roles of different factors in reducing poverty. Moreover, the countries progressed from very different starting points: Bangladesh, despite Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7   131   132 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand strong growth, remains a low-income country with a GDP per capita of $1,710. Peru and Thailand are firmly in the middle-income ranks, with GDP per capita of $10,439 and $9,630, respectively (all figures in purchasing power parity terms). In addition, Peru is highly urbanized, as opposed to Bangladesh and Thailand, whose shares of urban population remain below 30 percent. To understand how these diverse economies each reduced poverty so substan- tially over a similar period of time, we applied the structural decomposition approach progressively developed in the previous chapters of this volume. Chapter 5 had proposed a method to estimate an educational choice model, a sectoral choice model, a work-activity choice model, and individual and house- hold earnings equations. Once all of these models are estimated for individuals and households in each time period, the estimated coefficients from one year can be replaced with the estimates from another year to simulate the impact of changes in each element at a time. This process enables us to build a series of counterfactual income distributions to estimate a counterfactual poverty measure for comparison with the observed outcome while holding everything else constant. By changing one element at a time, these decompositions allow us to account for the observed changes in poverty. In addition, we can estimate these counterfactuals cumulatively, thereby accounting for the impact of concurrent changes. The chapter next describes the evolution of poverty and economic growth in Bangladesh, Peru, and Thailand—highlighting the countries’ similarities and differ- ences in their initial- and end-period outcomes. “The Decomposition Approach” then presents the results of the decomposition exercise for each country. The chapter ends the volume by summarizing our findings and laying out the possi- bilities for further application. Country Context For all their differences, Bangladesh, Peru, and Thailand have at least one thing in common: they drastically reduced poverty rates over the past decade (figure 6.1). The share of households living at or below the international poverty line corresponding to $2.50 per day (as shown in table 6.1) fell by an ­ average of 1.8 percentage points per year in Bangladesh (2000–10), 2.7 per- centage points per year in Peru (2004–10), and 1.6 percentage points per year in Thailand (2000–09). To calculate the share of population living below the moderate poverty line, the three countries use the “cost of basic needs” approach, although the “basket” for basic needs and specific lines are different.2 Moreover, this reduction in poverty coincided with strong GDP growth over the decade, which averaged 5.8 ­ percent in Bangladesh, 6 percent in Peru, and 4.4 percent in Thailand ( ­ figure 6.2). There is considerable evidence that economic growth is strongly and nega- tively correlated with changes in poverty (Ravallion and Chen 2007). Indeed, in these three countries, using the standard Datt and Ravallion (1992) decom­ position, growth does indeed explain most of the observed poverty reduction Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 133 Figure 6.1 Change in Moderate Poverty Rates in Bangladesh, Peru, and Thailand, 2000s 60 50 40 Population (%) 30 20 10 0 Bangladesh Peru Thailand 2000–10 2004–10 2000–09 Initial Final Sources: Household survey results from Bangladesh (HIES 2000–10), Peru (ENAHO 2004–10), and Thailand (SES 2000–09). Note: “Moderate poverty” headcounts are based on each country’s national moderate poverty line. HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics); ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information); SES = Household Socio-Economic Survey (Thailand National Statistical Office). Table 6.1 Change in Poverty Rates, by Level, in Bangladesh, Peru, and Thailand, 2000s Poverty lines National National $1.25 $2.50 $4.00 extreme moderate Poverty rate in Bangladesh, 2000–10 Initial period (%) 57.7 89.2 — 34.5 49.1 Final period (%) 40.3 84.0 — 17.6 31.5 Change (ppts) −17.4 −5.2 — −16.9 −17.6 Average annual change (ppts) −1.7 −0.5 — −1.7 −1.8 Annualized percentage change (%) −3.5 −0.6 — −6.5 −4.3 Poverty rate in Peru, 2004–10 Initial period (%) 3.5 22.9 45.8 17.4 49.1 Final period (%) 0.8 11.7 30.0 10.5 33.0 Change (ppts) −2.6 −11.2 −15.8 −6.9 −16.2 Average annual change (ppts) −0.4 −1.9 −2.6 −1.2 −2.7 Annualized percentage change (%) −21.1 −10.6 −6.8 −8.1 −6.4 table continues next page Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 134 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand Table 6.1  Change in Poverty Rates, by Level, in Bangladesh, Peru, and Thailand, 2000s (continued) Poverty lines National National $1.25 $2.50 $4.00 extreme moderate Poverty rate in Thailand, 2000–09 Initial period (%) 0.2 7.9 31.4 — 23.9 Final period (%) 0.0 2.5 16.6 — 9.8 Change (ppts) −0.2 −5.3 −14.8 — −14.1 Average annual change (ppts) … −0.6 −1.6 — −1.6 Annualized percentage change (%) −16.8 −11.8 −6.8 — −9.4 Sources: Household survey results from Bangladesh (HIES 2000–10), Peru (ENAHO 2004–10), and Thailand (SES 2000–09). Note: … = negligible; — = not available; ppts = percentage points; HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics); ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information). SES = Household Socio-Economic Survey (Thailand National Statistical Office). The $1.25, $2.50, and $4.00 poverty lines are daily household income amounts that correspond to international measurements of varying poverty levels in low- and moderate-income countries. The “National extreme” and “National moderate” poverty levels refer to country- based poverty lines calculated based on the “cost of basic needs,” such as specified calorie levels per person per day, and other essentials, such as clothing and shelter. Figure 6.2  GDP in Bangladesh, Peru, and Thailand, 2000–10 12 10 8 Real GDP growth (%) 6 4 2 0 –2 –4 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 Bangladesh Thailand Peru Source: World Bank 2011. Note: GDP = gross domestic product. (table 6.2). In each case, more than 80 percent of the reduction in poverty is explained by growth in mean income, whereas better income distribution explains less than 20 percent of the reduction. Although these estimates of the reduced-form relationships between eco- nomic growth, inequality, and poverty have been useful in identifying empirical regularities, they cannot explicitly link how growth and poverty reduction are Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 135 Table 6.2  Growth and Redistribution Decomposition of Moderate Poverty Rate Changes in Bangladesh, Peru, and Thailand, 2000s Percent Bangladesh Peru Thailand 2000 vs. 2010 2004 vs. 2010 2000 vs. 2009 Poverty headcount rate: FGT(0)a t0 48.9 (1.2) 49.1 (0.2) 23.9 (0.2) t1 31.5 (0.9) 33.0 (0.2) 9.8 (0.1) Actual percentage change −17.3 (1.5) −16.1 (0.3) −14.1 (0.2) Change resulting from growth −15.8 (1.6) −13.8 (0.4) −14.2 (0.3) Change resulting from redistribution −1.6 (1.5) −2.4 (0.3) 0.1 (0.3) Contributions to the decline in FGT(0) Growth 91 85 101 Redistribution 9 15 −1 Poverty gap FGT(1)b t0 12.8 (0.5) 16.4 (0.1) 5.5 (0.1) t1 6.5 (0.2) 9.3 (0.1) 1.8 (0.0) Actual percentage change −6.2 (0.5) −7.1 (0.1) −3.6 (0.1) Change resulting from growth −5.6 (0.6) −5.9 (0.2) −3.7 (0.1) Change resulting from redistribution −0.6 (0.6) −1.1 (0.2) 0.0 (0.1) Contributions to the decline in FGT(1) Growth 90 84 103 Redistribution 10 16 −3 Sources: Household survey results from Bangladesh (HIES 2000–10), Peru (ENAHO 2004–10), and Thailand (SES 2000–09). Note: Poverty rates are based on per capita consumption. The Datt and Ravallion (1992) decomposition reported here uses the Shapley (1953) approach described in chapter 2. Standard errors shown in parentheses. t0 = the initial year and t1 = the last year. HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics); ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information); SES = Household Socio-Economic Survey (Thailand National Statistical Office). a. FGT(0) = the poverty headcount rate. FGT refers to the Foster, Greer, and Thorbecke (1984) metric, a generalized measure of poverty in an economy. b. FGT(1) = the poverty gap, which estimates the depth of poverty, defined as the average percentage distance between the incomes of the incomes of the poor and the poverty line (Foster, Greer, and Thorbecke 1984). related (Ferreira 2010). In particular, we would like to capture the heterogeneity of impacts throughout the distribution and to be able to account for the contri- butions of demographics, sectoral, occupational, and other labor and nonlabor dimensions toward reducing poverty. Elements That Could Affect Poverty Reduction Changes in poverty can be decomposed into those resulting from changes in demographics, changes in labor incomes, changes in nonlabor incomes, and changes in ­consumption-to-income ratios. Changes in the population’s demo- graphics include changes in age, gender, and regional structure. Changes in labor incomes could result from improvements in human capital (such as education) and other endowments (such as greater access to productive assets), all of which would have increased labor productivity. Alternatively, labor incomes could have Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 136 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand risen simply because demand for certain characteristics outstripped supply—­ representing increased returns to a population’s endowments. In addition, increases in nonlabor incomes could have reduced poverty through higher remit- tances or public transfers. Finally, households are likely to change the share of income they dedicate to consumption, which affects the very measurements of consumption from which poverty rates are calculated. We look at each of these types of changes in turn. Demographic Changes Population growth slowed considerably in each of the countries considered over the past decade (figure 6.3). The change has been significant enough that in Bangladesh and Peru, the youth bulge observed in earlier periods has now reached working age (15–64 years old).3 As a result, the share of adults per household increased in each case (table 6.3). In other demographic changes, the share of employed women in all three countries increased slightly. Finally, there have been population shifts across regions, with a clear tendency toward greater urbanization in Bangladesh and Thailand. Changes in Labor Income Labor income growth is a primary factor to examine regarding the observed poverty reduction. The growth incidence curves in figure 6.4 show that labor income in the 2000s grew across the income distribution in each country. Figure 6.3 Population Growth in Bangladesh, Peru, and Thailand, 2000–10 a. Total population growth b. Population growth of working-age adults 2.0 75 1.8 Population in 15–64 age group (%) 1.6 70 Population growth (%) 1.4 1.2 65 1.0 0.8 60 0.6 0.4 55 0.2 0 50 01 01 03 00 02 03 09 10 0 02 08 09 10 04 08 04 05 06 05 06 07 07 0 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 Bangladesh Peru Thailand Source: World Bank 2011. Note: “Working-age adults” are defined as those aged 15–64 years. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 137 Table 6.3 Population and Labor Force Characteristics in Bangladesh, Peru, and Thailand, 2000s Bangladesh Peru Thailand 2000 2010 2004 2010 2000 2009 Population and demographics Total (millions) 71.0 89.8 27.6 31.4 59.8 64.7 Men (%) 50.4 48.4 49.7 49.2 47.8 47.9 Women (%) 49.6 51.6 50.3 50.8 52.2 52.1 Urban (%) 21.8 28.0 64.5 63.5 30.9 31.0 Rural (%) 78.2 72.0 35.5 36.5 69.1 69.0 Average household size (no. of members) 5.2 4.5 4.4 4.2 3.6 3.3 Average adults per household (no.) 3.1 2.9 2.7 2.6 2.5 2.4 Average adults per household (%) 63.4 68.4 68.0 70.7 75.2 78.9 Average occupied adults per household 48.4 50.1 73.2 75.7 77.7 77.4 (% of no. of adults) Labor force participation (% of working-age population) All 49.4 49.2 73.5 76.2 80.4 80.5 Men 83.3 84.9 83.1 84.4 87.0 86.7 Women 14.9 15.6 64.1 68.4 74.5 74.9 Employment rate (% of working-age population) All 46.6 47.8 71.2 74.9 78.3 79.8 Men 81.6 82.9 80.9 83.4 84.3 85.8 Women 11.1 14.8 61.6 66.8 73.0 74.4 Unemployment rate (% of labor force) All 5.6 1.4 5.1 3.8 2.5 0.9 Men 2.0 2.0 4.5 3.3 3.1 1.0 Women 25.9 0.8 5.8 4.4 2.0 0.7 Educational level (% of working-age population) Illiterate and incomplete primary 57.2 47.1 19.5 16.4 44.3 34.4 Primary and lower secondary 33.8 43.4 31.6 29.4 32.2 39.0 Higher secondary and tertiary 8.9 9.4 47.4 52.2 23.6 26.7 Labor relationship (% of employed population) Daily workersa 33.5 32.4 — — — — Self-employed 46.3 42.3 61.3 57.0 58.8 57.4 Wage workers 20.2 25.4 38.7 43.0 41.2 42.6 Economic sector (% of employed population) Agriculture 49.2 41.8 35.9 30.0 49.3 40.6 Manufacturinga 18.5 19 — — — — Industry 4.4 5.5 9.8 10.4 17.3 20.1 Services 27.9 33.7 46.0 50.8 24.6 30.2 Area (% of employed population) Rural 78.6 71.6 36.5 34.6 68.9 68.7 Urban 21.4 28.4 63.5 65.4 31.1 31.3 Sources: Household survey results from Bangladesh (HIES 2000–10), Peru (ENAHO 2004–10), and Thailand (SES 2000–09). Note: “Working-age population” is defined as adults aged 15–64 years. — = not available; HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics); ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information); SES = Household Socio-Economic Survey (Thailand National Statistical Office). a. The statistics in Peru and Thailand make no distinctions between “daily” and “wage” workers or between the “manufacturing” and “industrial” sectors. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 138 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand Figure 6.4  Growth Incidence Curves of Labor Income in Bangladesh, Peru, and Thailand, 2000s a. Bangladesh, 2000–10 b. Peru, 2004–10 6 0.14 5 0.12 Change in income (%) Change in income (%) 4 0.10 3 0.08 2 0.06 1 0.04 0 0.02 –1 0 1 11 21 31 41 51 61 71 81 91 100 1 11 21 31 41 51 61 71 81 91 100 Percentile Percentile c. Thailand, 2000–09 0.8 0.7 Change in income (%) 0.6 0.5 0.4 0.3 0.2 0.1 0 1 11 21 31 41 51 61 71 81 91 100 Percentile Labor income per capita Total income per capita Sources: Household survey results from Bangladesh (HIES 2000–10), Peru (ENAHO 2004–10), and Thailand (SES 2000–09). Note: The smoothing algorithm is a polynomial regression. The degrees of the polynomial vary by country and were chosen to maximize the fit of the data. “Total income” includes both labor and nonlabor sources of income. HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics); ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information); SES = Household Socio- Economic Survey (Thailand National Statistical Office). In Bangladesh, labor incomes grew faster for those at the top of the distribu- tion than for those at the bottom, while in Peru the opposite was true. In Thailand, incomes of the poor grew faster than those of the higher deciles (except for those in the poorest decile). Given the magnitude of the changes, labor income increases likely had an influence in moving people out of poverty. What accounts for these increases? What accounts for the different rates of growth across the distribution? Labor incomes could have grown for several reasons pertaining to changing labor force characteristics in all three countries: • Increased, and better-paying, employment. In the economically active popula- tion, increases in employment, particularly in better-paying jobs, would lead to Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 139 declines in poverty. Although labor force participation remained relatively stable in Bangladesh and Thailand over the 2000s, employment increased slightly. In Peru, both labor force participation and employment increased, ­ particularly among women. • Increases in wage employment. In addition to higher employment, all three countries saw a clear movement away from self-employed work and toward wage employment. In Bangladesh, there was also a movement away from daily-wage work toward wage work. All of these movements are likely to have led to better-quality employment. • Sectoral shifts. Similarly, employment shifted away from agriculture and toward the manufacturing and services sectors, which tend to be better paying. In Bangladesh, there was also a slight movement toward industry, which is also better paying than agriculture. • Educational advancement. The improved educational composition of the work force over the past 10 years also could have increased labor incomes. In all three countries, a smaller share of the population was illiterate by the end of the decade. In Bangladesh and Thailand, higher shares of the work force had completed primary and lower secondary school; and in Peru and Thailand, higher shares of the population had completed secondary and tertiary school (table 6.3). Changes in Nonlabor Income Although labor income has clearly increased, growth in nonlabor income could also be driving the observed reductions in poverty. Indeed, figure 6.5a shows that both public and private transfers steadily increased in Bangladesh, Peru, and Thailand during the 2000s. Although the countries differed widely in terms of the magnitude of public social spending relative to the size of their economies, public spending in each case increased by at least 25 percent during the 2000s. Whether public transfers are an important means of reducing poverty—and, if so, how important—depends on how effective this spending has been, particu- larly in terms of targeting the poor. As for private transfers, international remit- tances have tripled in Bangladesh over the past decade, have grown modestly in Peru, but have declined in Thailand (figure 6.5b). The question is how important have these changes been to poverty reduction? Changes in Consumption-to-Income Ratio Finally, in the context of growing overall incomes, households are likely to change the share of income they dedicate to consumption, given different marginal pro- pensities to consume. Figure 6.6 shows that in Bangladesh and Thailand, the consumption-to-income ratio fell over the course of the decade—a large part of which occurred in households below the poverty line, as table 6.4 shows. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 140 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand Figure 6.5 Nonlabor Income Growth, by Source, in Bangladesh, Peru, and Thailand, 2000s a. Subsidies and other social transfers b. International remittances 9 14 8 12 7 10 6 8 GDP (%) GDP (%) 5 4 6 3 4 2 2 1 0 0 00 01 02 03 04 05 06 07 08 09 10 00 01 02 03 04 05 06 07 08 09 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 Peru Thailand Bangladesh Source: World Bank 2011. Note: GDP = gross domestic product. Data on subsidies and other social transfers were unavailable for Bangladesh preceding 2001 and for Thailand preceding 2003. Figure 6.6 Change in Household Consumption-to-Income Ratio in Bangladesh, Peru, and Thailand, 2000s 10 Change in household consumption-to- 8 6 4 income ratio (%) 2 0 –2 –4 –6 –8 –10 –12 Bangladesh Peru Thailand 2000–10 2004–10 2000–09 Sources: Household survey results from Bangladesh (HIES 2000–10), Peru (ENAHO 2004–10), and Thailand (SES 2000–09). Note: HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics); ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information); SES = Household Socio-Economic Survey (Thailand National Statistical Office). In contrast, the consumption-to-income ratio increased over the course of the decade in Peru, particularly at the bottom of the distribution. As a result, the observed changes in consumption may be less dramatic than what we would have otherwise expected in Bangladesh and Thailand, but more dramatic in Peru, had the consumption-to-income ratio remained constant. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 141 Table 6.4 Household Consumption-to-Income Ratio, by Income Decile, in Bangladesh, Peru, and Thailand, 2000s Units of consumption per units of income Bangladesh Peru Thailand 2000 2010 2004 2010 2000 2009 Average 1.26 1.22 1.13 1.22 0.98 0.89 Income deciles (per capita) 1 3.69 3.46 1.96 2.52 2.74 3.01 2 1.39 1.53 1.33 1.50 2.24 1.64 3 1.14 1.29 1.22 1.31 1.77 1.5 4 1.07 1.13 1.18 1.18 1.76 1.46 5 1.05 1.03 1.12 1.13 1.74 1.29 6 1.01 0.92 1.05 1.05 1.56 1.31 7 0.97 0.83 1.00 1.01 1.49 1.21 8 0.95 0.76 0.93 0.92 1.49 1.22 9 0.88 0.67 0.84 0.85 1.59 1.15 10 0.76 0.5 0.71 0.71 1.5 1.1 Spearman ranka 0.79 0.56 0.86 0.83 0.81 0.83 Correlation 0.62 0.18 0.76 0.73 0.62 0.51 Coefficient of variation Consumption 0.87 0.78 0.97 0.85 0.96 0.99 Income 1.06 2.99 1.35 1.26 1.33 1.49 Sources: Household survey results from Bangladesh (HIES 2000–10), Peru (ENAHO 2004–10), and Thailand (SES 2000–09). Note: HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics); ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information); SES = Household Socio-Economic Survey. a. “Spearman rank” refers to Spearman’s rank correlation coefficient (named after Charles Spearman), a nonparametric measure of statistical dependence between two variables. The closer the correlation is to one, the more perfect the correlation is. Since poverty is measured by consumption, actual poverty rates are higher in the final period than they would have been had the consumption-to-income ratio remained constant in Bangladesh and Thailand. In contrast, actual poverty will be lower in the final period in Peru simply because poor households are consuming a higher share of their income. The Decomposition Approach As described in chapter 4, we implement the decomposition in four stages: 1. We estimate the determinants of occupational choice, sectoral choice, and educational level for two periods during the past decade. 2. We estimate the earnings regressions for each period for household heads and other household members (distinguishing between wage workers, self- employed, and daily workers) and for net farm revenue for farm households. 3. We use the coefficients from these regressions to simulate counterfactual distributions by replacing one element at a time. ­ 4. We compare these counterfactuals to the observed changes in distribution. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 142 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand Estimate Educational, Occupational, and Sectoral Choice Structures As summarized in the first step above, we first estimate the educational, occupa- tional, and sectoral choice models in each period for which data are available. In annex 6A, tables 6A.1, 6A.2, and 6A.3 present simulations for the educational structure, occupation, and economic sectors using these regressions compared with the actual structures during the early and late part of the decade. Also in the annex, tables 6A.4, 6A.5, and 6A.6 present the multinomial logit regression results for occupational choice in Bangladesh, Peru, and Thailand, respectively. Given the considerable diversification of income sources that is common in rural households (Davis et al. 2010), we estimate the sectoral choice model for the secondary occupation of individuals in farm households, as well as for all nonfarm work. The simulated structures are close to the true structures, with the errors being relatively small in all three countries. In the case of Bangladesh, the simulated 2010 nonfarm occupational structure has slightly fewer wage workers and more daily workers than the true values, but the regression results show a relatively high coefficient of determination (R2). This gives us confidence that we can use the coefficients from these regressions to simulate shifts in the labor force struc- ture one at a time. Estimate Earnings Equations Next, we separate labor income into farm and nonfarm income to estimate the earnings equations. Nonfarm Household Income Tables 6A.7, 6A.8, and 6A.9 present the results for individuals engaged in non- farm activities in Bangladesh, Peru, and Thailand, respectively. The results show that the models fit the data relatively well, with coefficients being statistically significant and of the right sign. In all cases, higher individual earnings are associ- ated with being male, having higher education and experience, living in urban areas, and belonging to the manufacturing sector. Farm Household Income Tables 6A.10, 6A.11, and A6A.12 present results of net revenue for farm house- holds in Bangladesh, Peru, and Thailand, respectively.4 Net revenue for farmers increases with experience, land holdings, access to irrigation, and the number of household members participating in farm work.5 Simulate Counterfactual Distributions In the next step, we use the estimated coefficients from the educational, sectoral, labor, and earnings models to simulate counterfactual distributions. For instance, because we estimated the returns to education in two periods, we can take the estimated parameters in the first period (say, 2000) and evaluate the earnings equations with the 2010 levels of education. This generates counterfactual earnings at the individual level, which we aggregate to get the corresponding ­ household income, then the corresponding level of consumption, and finally a Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 143 counterfactual poverty rate. In this way—changing one parameter at a time or one characteristic at a time—we can generate multiple counterfactual distribu- tions and recalculate a new poverty rate. Compare Counterfactuals with Distributional Changes Finally, we compare these counterfactual poverty rates with the observed pov- erty rates to quantify the impact of each element being considered. Because replacing the first-period parameters into last-period data will yield results that are different from doing it the other way around, we calculate the counterfactual by doing it both ways and then take the average (in line with Bourguignon, Ferreira, and Lustig 2005; Bourguignon, Ferreira, and Leite 2008). We first calculate the effects on poverty by changing one element at a time and leaving everything else constant. However, given that changes in multiple factors could have interaction effects, we also calculate the cumulative effect of these decompositions. For this purpose, we adhere to the literature (Bourguignon, Ferreira, and Leite 2008) as follows: • Begin by calculating the effects on poverty as a result of changes in the popula- tion’s characteristics, beginning with the most exogenous: age, gender, and region. • Then calculate the effects on poverty as a result of changes in the population’s educational, occupational, and sectoral structure, all of which depend on age, ­ gender, and region. • Use the preceding results to calculate the effects on poverty as a result of –– Changes in farm and nonfarm earnings due to changes in the returns to these characteristics; –– Changes in nonlabor incomes (first private transfers, then public ones); and –– Changes in the consumption-to-income ratio. Decomposition Results Chapter 3 found that, in a set of 21 countries with large declines in poverty, most of these declines could be attributed to increases in labor income. The results of this chapter are in line with that result, while adding a modeling structure that enables us to further conclude that the main contributor to increased labor incomes—and thus to poverty reduction—was the improvement in the returns to individual and household characteristics and endowments. Endowments and the Returns on Endowments That these increased returns contributed the most to poverty reduction, rather than changes in the populations’ endowments or characteristics, points to an increase in the relative price of labor and higher productivity as the main ­ contributors to poverty reduction in each case. In particular, returns to farm and nonfarm endowments amount to 44 percent of poverty reduction in Peru, more than 48 percent in Thailand, and 60 percent in Bangladesh (table 6.5). In both Thailand and Bangladesh, this effect is concentrated in the farm sector, whereas Peru’s increased returns were slightly larger in the nonfarm sector. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 144 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand The overall conclusion—that increased returns to endowments was the largest factor in poverty reduction—holds true whether we (a) calculate one counter- factual at a time, holding all else constant (as shown by the marginal contribu- tions in tables 6.5 and 6.6) or (b) adopt the cumulative decomposition path described (as shown in table 6.7). Although the cumulative results are slightly different in magnitude, the overall messages are the same. Table 6.5 shows the net effect of changes in returns. However, these net effects reflect the sum of price changes that the labor market assigns to each Table 6.5 Marginal Contributions to Poverty Reduction in Bangladesh, Peru, and Thailand, 2000s Bangladesh, Peru, Thailand, 2000–10 2004–10 2000–09 Change Change Change Change Change Change (ppts) (% of total) (ppts) (% of total) (ppts) (% of total) Nonfarm labor income −4.56 26 −9.35 58 −3.46 27   Returns to characteristics −3.52 20 −4.93 31 −1.25 10   Occupational choice −1.61 9 −3.44 21 0.08 −1   Economic sector −0.48 3 −0.08 1 −1.01 8  Education −0.55 3 −0.25 2 −1.34 10   Unobservable factors 1.59 −9 −0.65 4 0.06 0 Farm income −6.02 35 −2.74 17 −4.91 38   Returns to characteristics −6.98 40 −2.04 13 −4.83 38   Occupational choice 0.56 −3 −0.25 2 1.31 −10   Economic sector — — −0.14 1 −1.11 9  Education 0.13 −1 −0.08 1 −0.56 4   Unobservable factors 0.26 −2 −0.23 1 0.28 −2 Nonlabor income 1.05 −6 −2.28 14 −5.80 45   Total private transfers 1.05 −6 −0.85 5 −3.30 26    International private transfers −1.94 11 0.19 −1 −2.19 17    Domestic private transfers 1.10 −6 0.24 −1 — —   Private donations — — −0.70 4 — —    Other private transfers 0.58 −3 0.01 0 −1.12 9    Capital 1.31 −8 −0.58 4 0.02 0   Total public transfers 0.00 0 −1.38 9 −2.51 20   Public donations — — −0.45 3 — —    Public transfers — — −0.90 6 — —   Pensions — — 0.01 0 −2.51 20 Other nonlabor income — — −0.04 0 — — Other −7.50 43 −0.78 5 2.50 −20   Age-gender-regional structure −3.48 20 −1.17 7 −1.18 9   Consumption-to-income ratio 0.93 −5 −1.73 11 3.43 −27   Unexplained −4.95 29 2.12 −13 0.26 −2 Total −17.34 100 −16.13 100 −12.84 100 Sources: Calculations derived from household survey data from Bangladesh (HIES 2000–10), Peru (ENAHO 2004–10), and Thailand (SES 2000–09). Note: ppts = percentage points; — = not available; HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics); ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information); SES = Household Socio-Economic Survey (Thailand National Statistical Office). Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Table 6.6 Contributions to Poverty Reduction by Returns to Endowments in Bangladesh, Peru, and Thailand, 2000s Bangladesh Peru Thailand 2000–10 2004–10 2000–09 Nonfarm households Farm households Nonfarm households Farm households Nonfarm households Farm households Change Change Change Change Change Change Change Change Change Change Change Change (ppts) (%) (ppts) (%) (ppts) (%) (ppts) (%) (ppts) (%) (ppts) (%) Total parameter effects −3.52 20 −6.98 40 −4.93 31 −2.04 13 −1.25 10 −4.83 38 Education 1.77 −10 0.78 −4 0.54 −3 … … −0.28 2 −1.11 9 Age 3.9 −23 4.19 −24 1.0 −6 0.96 −6 −0.90 7 −0.54 4 Female −0.44 3 −0.20 1 0.77 −5 −0.08 1 −0.01 … −0.33 3 Urban 0.11 −1 0.45 −3 0.20 −1 0.12 −1 −0.40 3 −0.09 1 Region −0.87 5 −1.82 10 −4.79 30 −0.18 1 −0.27 2 −1.62 13 Sector 5.85 −34 0.21 −1 −1.05 7 −0.19 1 3.50 −27 0.32 −3 Land n.a. n.a. −7.25 42 n.a. n.a. −3.18 20 n.a. n.a. — — Irrigation n.a. n.a. 0.30 −2 n.a. n.a. −0.11 1 n.a. n.a. — — Other members n.a. n.a. 1.48 −9 n.a. n.a. 1.07 −7 n.a. n.a. — — Constant −14.87 86 −7.74 45 −3.38 21 … … −2.71 21 −1.11 9 Sources: Calculations derived from household survey data from Bangladesh (HIES 2000–10), Peru (ENAHO 2004–10), and Thailand (SES 2000–09). Note: ppts = percentage points; … = negligible; — = not available; n.a. = not applicable. “Region” refers to residence in provinces, states, or other regional subgroups. “Sector” refers to changes in the sectoral choice of workers, including agriculture, manufacturing, industry, and services. “Other members” refers to the number of household members engaged in farm activities. HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics). ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information). SES = Household Socio-Economic Survey (Thailand National Statistical Office). 145 146 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand Table 6.7 Cumulative Contributions to Poverty Reduction in Bangladesh, Peru, and Thailand, 2000s Bangladesh, 2000–10 Peru, 2004–10 Thailand, 2000–09 Change Change Change Change Change Change (ppts) (%) (ppts) (%) (ppts) (%) Demographics −4.41 25 −0.88 5 −0.41 3 Education −0.88 5 −0.31 2 −1.74 14 Occupation −1.38 8 −3.90 24 0.52 −4 Sector −0.51 3 0.02 0 −1.75 14 Returns nonfarm −2.93 17 −5.06 31 −1.40 11 Returns farm −8.18 47 −1.95 12 −3.59 28 Residuals 1.33 −8 0.05 0 0.06 0 Nonlabor income −1.93 11 −0.13 1 −3.59 28 Others 1.55 −9 −3.96 25 −0.93 7 Total −17.34 100 −16.13 100 −12.84 100 Sources: Calculations derived from household survey data from Bangladesh (HIES 2000–10), Peru (ENAHO 2004–10), and Thailand (SES 2000–09). Note: ppts = percentage points. “Demographics” refers to the exogenous structure of the population’s age, gender, and regional makeup. For a detailed description of the methodology, refer to chapter 5. HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics); ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information); SES = Household Socio-Economic Survey (Thailand National Statistical Office). characteristic or endowment. For example, the price the labor market assigns for each additional level of education or for living in a particular region in the country may be components of this net effect. ­ Table 6.6 breaks down these changes in returns. The results show that for self- employed farmers, most of the increase in returns has to do with a large increase in the constant, which measures average real farm wages holding everything else constant. This increase could be the result of either higher productivity or higher relative prices in agriculture—potentially resulting from food price increases. As we have seen, poverty rates changed because of both changes in endow- ments and changes in the returns to those endowments. However, these two forces could act in opposite directions. For instance, if higher education raises incomes, it also would tend to lower poverty. However, if the supply of educated workers outpaces the demand for such workers, then the returns to, or premium for, higher education will likely fall. This idea is often associated with Tinbergen’s (1975) “race” between technological progress—which he saw as raising the demand for skills—and the expansion of formal education—which raises the supply of skills (Ferreira 2012). Below, we summarize the results regarding the net impacts of changes in these opposing forces. Impact of Demographic Changes Changes in the structure of the populations’ age, gender, area (urban or rural), and regional (district) accounted for about 25 percent of the observed poverty reduction in Bangladesh, 5 percent of the reduction in Peru, and 3 percent of the reduction in Thailand when holding all else constant (table 6.7). Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 147 These are important contributions that are consistent with the results described in chapter 3, which follow an alternative methodology. Given the increase in the economically active population, the size of the effect is not surprising—­ particularly in Bangladesh, where fertility rates have declined while a large genera- tion of young people has joined the work force. However, the entrance of young people has coincided with a decline in the premium for experience (as proxied by age), particularly for daily and self-employed workers in Bangladesh. The decline in the returns to experience (shown as a –23 percent decline in the age parameter for Bangladesh in table 6.6) has counteracted the progress in poverty reduction (shown as a combined positive effect of 25 percent for Bangladesh in table 6.7). In contrast, in Thailand, both the increase in the working-age population and the greater returns to age (interpreted as experience) contributed to pov- erty reduction. In particular, demographics contributed 3 percent to poverty reduction (table 6.7), while greater returns to experience in the farm and non- farm households contributed 4 percent and 7 percent, respectively (table 6.6). A consistent result in all three countries is that the earnings penalty for living outside of the capital city fell over the past decade. This finding points to either an increase in the relative price of labor, higher productivity outside the capitals that helped to reduce poverty, or both. This result is most evident in Peru, where the reduced penalty for living outside of Lima (which table 6.6 reflects through the impact of residency in the “regions”) accounted for 30 percent of the reduction in poverty for nonfarm households.6 In Bangladesh, the penalty for living outside of the capital also declined, accounting for 10 percent and 5 percent of poverty reduction for farm and nonfarm households, respectively. Thailand saw a 13 percent and 2 percent in poverty reduction among farm and nonfarm households, respectively, even though the share of people living out- side the capital remained more or less constant. Impact of Changes in Labor Income Education As expected, a more-educated population helped to reduce poverty in all three countries, particularly in the nonfarm sector (table 6.5). However, this effect was modest—being more than offset by a decline in the returns to education in Bangladesh and Peru (table 6.6). In Thailand, in contrast, wage premiums for education increased in farm and nonfarm households, further reducing poverty. The results of greater education and of returns to education were as follows in the three countries: • In Bangladesh, the large increase in the share of the population who had com- pleted primary school (from 33.8 percent in 2000 to 43.4 percent in 2010, as previously shown in table 6.3) led to only a slight (3 percent) reduction in poverty in the nonfarm sector (table 6.5) because it drove down the premium for completing primary school for all but wage workers. • In Peru, similarly, a more-educated population accounted for 2 percent of the decline in poverty in the nonfarm sector (table 6.5). However, this effect was Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 148 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand more than offset by a decline in the returns to education (table 6.6), because the greater supply of more-educated household heads was not met with greater demand for these workers; therefore, the wage premium for education fell. As a result, the increase in education reduced poverty less than expected. • In Thailand, a more-educated population accounted for 10 percent of the reduction in poverty in nonfarm households, and a 4 percent reduction in farm households (table 6.5). In contrast to Peru and Bangladesh, increased returns to education reinforced these gains in poverty reduction, as wage premiums for education and experience increased in both farm and nonfarm households (table 6.6). These results point to greater demand for specialized workers in Thailand than in Bangladesh and Peru. Collectively, these results point to a relative increase in the price of labor for uneducated workers, an increase that strongly drove poverty reduction in Bangladesh and Peru. Capturing this effect is the large contribution to poverty reduction from the left-out category—the constant—which includes the returns to labor for individuals with no schooling (table 6.6). In Bangladesh, this was true in both the farm and nonfarm sectors for daily and self-employed workers, whose additional years of education did not help to reduce poverty (see the table 6A.7). However, the opposite is true for wage workers, whose returns to education increased. This seeming contrast implies that the population’s educational levels grew faster than the rate at which job creation could absorb them. The different job-related returns to education also reflect a sizable increase in the relative price of unskilled labor, which could be driven, at least partly, by higher productivity. Occupation Changes in occupational choice were critical to poverty reduction in all three countries among nonfarm workers, who aimed to benefit from better work opportunities. This effect was most important in Peru, where occupational shifts—from being unpaid family workers to being wage workers—accounts for 21 percent of poverty reduction (table 6.5). In the nonfarm sector in Bangladesh, the shift from daily and self-employed work toward wage employment accounted for almost 10 percent of the observed poverty reduction.7 In contrast, for workers who remained in agriculture, we find greater special- ization on the part of farmers. By the end of the decade, they were less likely to diversify into a secondary occupation, either because they saw increased returns from farm activities or because they lacked the skills to take up a second occu- pation. For example, the share of Thai farmers with a secondary occupation declined from 32 percent in 2000 to 23 percent in 2009. Meanwhile, in Bangladesh, the drop was even more dramatic: the share of farmers with a ­ secondary occupation fell from 30 percent in 2000 to 10 percent in 2010. This lower diversification increased poverty by 10 percent and 3 percent in Thailand and Bangladesh, respectively (see the “Occupational choice” row under “Farm income” in table 6.5).8 Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 149 Sector of Work Changes in work sector also affected poverty reduction, particularly shifts away from agriculture and into services. However, in both Bangladesh and Thailand, any related poverty reduction was more than offset by reduced returns to work- ing in the service sector, whereas Peru showed the opposite dynamic: • In Bangladesh, the nonfarm sector’s shift into the services sector accounted for 3 percent of the observed poverty reduction (table 6.5). However, this was more than offset by a reduction in the service sector wage premium in non- farm households, leading to a 34 percent higher poverty rate than would have otherwise been expected (table 6.6). • In Thailand, similarly, many workers’ movement into manufacturing and ser- vices accounted for a 9 percent poverty decrease among farm households and an 8 percent decrease among nonfarm households (table 6.5). However, these effects were countered by a decline in the returns to working in those sectors in farm and nonfarm households (table 6A.9), which led to a 3 percent and 27 percent higher poverty rate, respectively, than would have otherwise been expected (table 6.6). • In Peru, in contrast, despite the increasing share of workers in the service sector, there were increases in the returns to working in the service sector ­ (see table 6A.8) that accounted for 7 percent of the reduction in poverty (table 6.6). This is astonishing, given that Peru has a much larger share of ­ service sector workers than either of the other countries (see table 6.3). Rural Assets Among farm households in Bangladesh and Peru, we find some evidence of increased returns to agriculture. In particular, for farm households in Bangladesh, the most important change was the increase in the returns to land, accounting for 42 percent of the reduction in national poverty when holding all other factors constant (table 6.6). These returns increased because average land per capita declined from 0.8 acres to 0.6 acres between 2000 and 2010 given the popula- tion increase. In contrast, in the case of Peru, the average land size for farm households increased while the returns to land increased as well (table 6.6), a boon that accounted for 20 percent of the reduction in poverty. This was complemented by better access to irrigation in Peru, accounting for another 1 percent of the poverty reduction. However, the returns to additional agricultural workers declined. In Bangladesh, although both access to irrigation and the number of agricultural workers increased over the course of the decade, the returns to irrigation and having additional household members employed in farming fell, so ­ neither effect helped to reduce poverty.9 In considering the increase to rural assets, it is important to note that we cannot disentangle the effects as a result of increased real productivity (real out- ­ put per worker) from the increase in the real value of output per worker. Given that this period was characterized by an increase in the prices of commodities, Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 150 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand this factor might have been an important driver of agricultural returns, through its effect on the real value of agricultural production. Impact of Changes in Nonlabor Income Although poverty was reduced primarily because of labor income growth, increases in nonlabor income also played a role that varied by country: • In Bangladesh, the increase in international remittances contributed 11 p­ ercent to the decline in poverty. Offsetting this effect, however, was a decline in domestic transfers that led to a slightly higher poverty rate than if both remit- tance sources had remained constant (table 6.5). • In Peru, public transfers and donations accounted for 9 percent of the reduc- tion in poverty (table 6.5), while capital and private donations accounted for nearly 5 percent of the reduction in poverty (table 6.5). • In Thailand, nonlabor income was important, particularly through private transfers in the form of international remittances and other private transfers (17 percent and 9 percent, respectively) and pensions (20 percent), poten- tially reflecting the introduction of a new pension scheme in the late 1990s (table 6.5). These results are consistent with those using the simple approach, but they have been further disaggregated to show the relative importance of the different types of sources. Final Remarks The past decade affords us a fantastic opportunity to study the most significant factors that worked in favor of the poor. This chapter accounts for the contribu- tion of changes in demographics, labor income, and nonlabor income in the significant poverty reductions observed in Bangladesh, Peru, and Thailand dur- ing the 2000s. In contrast to methods that focus on aggregate summary statis- tics, the methods adopted here generate entire counterfactual distributions, allowing us to identify more precisely the contributions to the observed distri- butional changes. Link of Labor Income to Marginal Value of Work The results show that labor income growth has been the most important con- tributor to poverty reduction over the past decade. Further—through the micro- decomposition methods employed here—we ascertained that the growth in labor income was mainly the result of higher returns to endowments, signaling an increase in the marginal value of work, resulting from increases in either pro- ductivity or relative prices of labor. In Bangladesh and Peru, this increase in the marginal value of work was not driven by higher returns to education, but rather by higher returns to unskilled labor. Thailand, in contrast, demonstrated that greater specialization and higher returns to human capital can boost the marginal value of work, potentially through productivity increases. All three countries showed these results consistently: Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 151 • A falling earnings penalty for living outside of the capital city served to reduce poverty over the past decade—accounting for as much of 31 percent of the reduction in Peru, 15 percent in Bangladesh, and 15 percent in Thailand. • A shift in the sectoral composition of the work force—away from agriculture and toward services—reduced poverty only slightly in Bangladesh and Peru and a bit more in Thailand. However, this increase in service sector workers led to a declining premium for working in the service sector in Bangladesh and Thailand. In Peru, however, the higher share of service workers was accom- panied by increased premiums even though Peru’s service sector makes up a far larger share of total employment than it does in the other countries. • Occupational choices among nonfarm workers shifted away from daily-wage and self-employed work and toward wage jobs, all of which contributed to poverty reduction, particularly in Peru. Roles of Demographic Change and Nonlabor Income Growth Beyond the effects of labor income growth, the decomposition method adopted in this chapter (as well as the method adopted in chapter 3) showed that a greater share of working-age adults helped to reduce poverty, particularly in Bangladesh. Finally, although most of the reduction in poverty was the result of labor income growth, it is important to recognize that nonlabor income in the form of transfers did play a role: International remittances accounted for 11 percent and 17 ­percent of poverty reduction in Bangladesh and Thailand, respectively. Public transfers accounted for about 9 percent of Peru’s poverty reduction, particularly for those at the very bottom of the income distribution. And Thailand’s generous new pension scheme, combined with various private and other transfers, accounts for more than one-third of its poverty reduction. An Agenda for Further Research This volume has proposed two distinct micro-decomposition approaches to understanding changes in poverty over the last decade. The proposed approaches are complementary—the first being quite simple and easy to apply across coun- tries with relatively limited data requirements, and the second providing a more in-depth analysis based on a structural approach. The approach implemented in this chapter allows for movement across ­ sectors and occupations for nonfarm households. In addition, it allows individuals in farm households to choose a secondary occupation and sector. However, the proposed structure does not model the choice of a household to be either a farm or a nonfarm household. Further research could explore the extent to which this could be incorporated into the decomposition analysis. In addition, to the extent that demographic changes are important, further work could include a fertility choice model, particularly in settings where there are substantial shifts over time. Finally, as described in chapter 4, other decom- position techniques could be explored and perhaps combined with the two approaches highlighted in this volume. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 152 Annex 6A: Regression and Simulation Results Table 6A.1 Simulating the Changing Characteristics of Households in Bangladesh, 2000–10 Household head Other members 2000 2010 2000 2010 Actual Simulated Actual Simulated Actual Simulated Actual Simulated (1) (2) (2) – (1) (1) (2) (2) – (1) (1) (2) (2) – (1) (1) (2) (2) – (1) (%) (%) (ppts) (%) (%) (ppts) (%) (%) (ppts) (%) (%) (ppts) Education structure Illiterate and incomplete primary 63.2 61.9 −1.3 57.0 57.8 0.8 54.4 54.5 0.1 42.1 42.3 0.2 Primary and low secondary 29.0 29.6 0.6 33.1 33.2 0.1 36.2 36.0 −0.3 48.6 48.2 −0.4 Complete tertiary 7.7 8.5 0.8 9.9 9.0 −0.9 9.5 9.6 0.1 9.3 9.4 0.2 Occupation Nonemployed 9.6 10.1 0.5 8.0 7.7 −0.4 79.8 83.0 3.2 78.0 80.1 2.2 Daily workers 45.5 40.7 −4.9 43.4 49.9 6.5 8.6 4.7 −3.9 8.2 5.6 −2.7 Self-employed—nonagriculture 24.7 25.1 0.3 24.1 23.9 −0.2 4.4 4.8 0.3 4.1 4.4 0.3 Wage workers 20.2 24.2 4.0 24.5 18.6 −5.9 7.2 7.5 0.3 9.7 9.9 0.2 Economic sectors Daily workers  Agriculture 58.8 56.4 −2.4 51.8 51.8 0.0 54.8 53.4 −1.4 42.7 44.1 1.4   Manufacturing 12.3 12.8 0.5 12.6 13.1 0.6 19.0 18.3 −0.8 21.5 20.4 −1.1  Industry 7.9 8.5 0.6 11.9 12.3 0.4 8.4 8.9 0.6 15.8 16.4 0.5  Services 21.0 22.4 1.4 23.7 22.8 −0.9 17.8 19.4 1.6 20.0 19.2 −0.8 Self-employed                           Manufacturing 34.9 35.3 0.4 17.6 17.0 −0.6 41.1 45.7 4.7 26.8 22.1 −4.8  Industry 6.2 7.8 1.6 1.7 1.9 0.1 7.1 6.9 −0.2 3.1 2.6 −0.5  Services 58.9 57.0 −2.0 80.7 81.1 0.4 51.8 47.4 −4.5 70.1 75.4 5.3 Wage workers  Agriculture 8.6 7.3 −1.3 5.4 6.9 1.4 4.4 3.4 −1.0 3.0 3.7 0.8   Manufacturing 27.7 26.8 −0.9 33.4 34.3 0.9 42.6 42.4 −0.2 47.3 47.5 0.3  Industry 3.7 3.8 0.1 3.9 4.0 0.1 2.5 2.0 −0.5 2.6 2.7 0.1  Services 60.0 62.2 2.1 57.3 54.9 −2.4 50.5 52.2 1.7 47.2 46.0 −1.2 Source: Household survey results from Bangladesh (HIES 2000–10). Note: ppts = percentage points. HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics). Table 6A.2 Simulating the Changing Characteristics of Households in Peru, 2005–09 Household head Other members 2004 2010 2004 2010 Actual Simulated Actual Simulated Actual Simulated Actual Simulated (1) (2) (2) – (1) (1) (2) (2) – (1) (1) (2) (2) – (1) (1) (2) (2) – (1) (%) (%) (ppts) (%) (%) (ppts) (%) (%) (ppts) (%) (%) (ppts) Education type Less than primary 55.3 55.4 0.1 49.7 49.9 0.3 50.3 50.8 0.6 45.4 44.6 −0.8 Primary 28.2 28.1 −0.1 32.4 32.3 −0.1 36.5 35.6 −0.8 39.7 40.7 1.0 Secondary and above 16.5 16.5 0.0 18.0 17.8 −0.2 13.3 13.6 0.3 15.0 14.7 −0.2 Occupation Nonemployed 16.8 17.3 0.5 13.1 12.8 −0.3 57.9 58.7 0.9 49.5 50.4 0.9 Wage workers 48.2 48.1 0.0 50.2 50.0 −0.2 26.2 25.7 −0.5 32.2 31.6 −0.6 Self-employed (nonagriculture) 35.0 34.5 −0.5 36.7 37.2 0.5 15.9 15.6 −0.4 18.3 18.0 −0.3 Economic sectors Wage workers  Agriculture 31.8 29.9 0.0 25.9 27.6 0.1 17.0 17.7 −0.5 14.8 13.9 0.7  Industry 12.1 12.1 1.6 12.0 12.1 −1.0 13.2 12.8 −1.4 13.2 13.9 1.6  Services 35.2 36.8 0.2 40.7 39.7 −1.0 52.8 51.4 1.2 56.7 58.3 −1.4   Public sector 20.9 21.2 0.0 21.5 20.5 0.0 16.9 18.1 0.0 15.3 14.0 0.0 Source: Household survey results from Peru (ENAHO 2004–10). Note: ppts = percentage points. ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information). 153 154 Table 6A.3 Simulating the Changing Characteristics of Households in Thailand, 2000–09 Household head Other members 2000 2009 2000 2009 Actual Simulated Actual Simulated Actual Simulated Actual Simulated (1) (2) (2) – (1) (1) (2) (2) – (1) (1) (2) (2) – (1) (1) (2) (2) – (1) (%) (%) (ppts) (%) (%) (ppts) (%) (%) (ppts) (%) (%) (ppts) Education (years) <6 59.7 64.8 5.1 46.9 40.8 −6.0 36.6 42.3 5.7 27.3 22.1 −5.2 6–11 23.2 19.3 −3.8 29.3 34.2 4.9 37.1 32.9 −4.2 44.4 49.0 4.6 >11 17.1 15.9 −1.3 23.8 25.0 1.2 26.3 24.8 −1.5 28.3 28.9 0.7 Occupation Nonemployed 20.4 21.5 1.1 20.7 19.4 −1.2 49.4 47.0 −2.5 47.3 50.6 3.3 Salaried 57.3 56.4 −0.9 53.9 55.7 1.8 41.0 42.8 1.8 41.9 39.5 −2.4 Self-employed (nonagriculture) 22.3 22.1 −0.2 25.4 24.8 −0.6 9.5 10.3 0.7 10.8 9.9 −0.9 Economic sectors Self-employed  Industry 15.6 14.4 −1.2 17.1 16.7 −0.4 20.0 18.4 −1.6 18.7 16.1 −2.6  Services 84.4 85.6 1.2 82.9 83.3 0.4 80.0 81.7 1.6 81.3 83.9 2.6 Wage workers  Agriculture 20.6 16.5 −4.0 11.6 15.1 3.5 20.7 18.9 −1.8 9.1 11.0 1.9  Industry 30.7 27.1 −3.6 35.3 37.3 1.9 36.0 32.2 −3.8 38.8 41.2 2.4  Services 23.6 22.8 −0.7 29.3 30.5 1.2 27.2 25.6 −1.5 34.7 35.9 1.2   Public sector 25.1 33.5 8.4 23.8 17.2 −6.6 16.1 23.3 7.2 17.4 11.9 −5.4 Source: Household survey results from Thailand (SES 2000–09). Note: ppts = percentage points. SES = Household Socio-Economic Survey (Thailand National Statistical Office). Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 155 Table 6A.4 Multinomial Logit on Occupational Choice of Working-Age Population, by Household Status, in Bangladesh, 2000 and 2010 2000 2010 Daily workers Self-employeda Wage worker Daily workers Self-employeda Wage worker a. Household heads Primary & lower secondary −1.204*** −0.0182 0.614*** −1.082*** 0.122 0.682*** education (0.160) (0.161) (0.166) (0.145) (0.147) (0.147) Higher secondary −2.408*** 0.301 2.002*** −3.461*** −0.599*** 1.227*** & tertiary education (0.368) (0.294) (0.287) (0.267) (0.203) (0.194) Age 0.0408 0.126** 0.114** 0.109** 0.281*** 0.238*** (0.0510) (0.0544) (0.0556) (0.0423) (0.0449) (0.0440) Age squared −0.00141** −0.00228*** −0.00208*** −0.00211*** −0.00382*** −0.00360*** (0.000572) (0.000611) (0.000627) (0.000473) (0.000504) (0.000496) Urban −0.354** 0.421*** 0.795*** −1.150*** −0.411*** −0.00785 (0.160) (0.161) (0.162) (0.134) (0.135) (0.133) Barisal 0.0892 −0.0402 −0.313 0.101 −0.330 −0.310 (0.263) (0.275) (0.288) (0.255) (0.262) (0.258) Chittagong −0.490*** −0.310* −0.216 0.228 −0.525*** −0.264 (0.179) (0.184) (0.186) (0.161) (0.168) (0.161) Khulna 0.432* 0.273 0.0118 1.127*** 0.352 0.128 (0.231) (0.240) (0.248) (0.217) (0.224) (0.223) Rajsahi 1.735*** 1.400*** 0.834*** 1.641*** 1.141*** 0.390** (0.227) (0.234) (0.242) (0.190) (0.194) (0.197) Sylhet 0.541* −0.0682 0.126 0.564** 0.467* −0.0835 (0.281) (0.319) (0.323) (0.262) (0.270) (0.276) Attends school −3.549*** −3.393*** −2.742*** −0.263 −14.93 −1.508 (0.753) (0.866) (0.724) (1.439) (565.3) (1.281) Remittances −0.646*** −1.014*** −0.715*** −0.129 −0.00592 −0.178 (0.172) (0.178) (0.181) (0.214) (0.215) (0.218) Female −2.213*** −2.993*** −1.178*** −1.903*** −2.802*** −1.019*** (0.409) (0.489) (0.444) (0.376) (0.444) (0.379) Remittances × Female −0.328 −0.985* −1.450*** −1.534*** −1.583*** −2.358*** (0.321) (0.595) (0.431) (0.338) (0.506) (0.380) Married 0.558 0.683* 0.593 1.295*** 1.471*** 1.235*** (0.367) (0.384) (0.389) (0.355) (0.375) (0.355) Married × Female −2.269*** −1.432** −1.876*** −2.703*** −1.877*** −1.897*** (0.496) (0.651) (0.569) (0.467) (0.590) (0.464) Other member −0.521*** −0.385*** −0.513*** −0.395*** −0.492*** −0.363*** employed (0.0700) (0.0717) (0.0762) (0.0730) (0.0760) (0.0736) Number of children 0.246*** 0.267*** 0.213*** 0.114 0.0960 −0.115 (0.0484) (0.0503) (0.0521) (0.0697) (0.0713) (0.0722) Constant 3.198*** 0.0640 −0.443 1.710* −3.336*** −2.206** (1.030) (1.094) (1.113) (0.915) (0.976) (0.943) Observations 4,974 4,974 4,974 7,862 7,862 7,862 Pseudo R2 0.233 0.233 0.233 0.259 0.259 0.259 table continues next page Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 156 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand Table 6A.4  Multinomial Logit on Occupational Choice of Working-Age Population, by Household Status, in Bangladesh, 2000 and 2010 (continued) 2000 2010 Daily workers Self-employeda Wage worker Daily workers Self-employeda Wage worker b. Other household members Primary & lower secondary −0.964*** −0.0334 0.259*** −0.802*** 0.321*** 0.240*** education (0.0977) (0.117) (0.0965) (0.0739) (0.0986) (0.0704) Higher secondary −2.894*** 0.0292 1.227*** −2.253*** 0.114 1.460*** & tertiary education (0.358) (0.197) (0.155) (0.264) (0.171) (0.111) Age 0.180*** 0.231*** 0.190*** 0.154*** 0.336*** 0.183*** (0.0239) (0.0311) (0.0255) (0.0207) (0.0281) (0.0194) Age squared −0.00286*** −0.00345*** −0.00308*** −0.00243*** −0.00459*** −0.00303*** (0.000345) (0.000454) (0.000381) (0.000296) (0.000407) (0.000285) Urban −0.172 0.623*** 0.781*** −0.134 0.358*** 0.966*** (0.108) (0.112) (0.0884) (0.0826) (0.0907) (0.0617) Barisal 0.219 −0.117 −0.284 0.0287 −0.406** −0.677*** (0.179) (0.206) (0.174) (0.157) (0.183) (0.136) Chittagong 0.107 −0.0791 0.0725 0.189* −0.704*** −0.429*** (0.119) (0.136) (0.103) (0.100) (0.124) (0.0766) Khulna 0.504*** 0.155 −0.540*** 0.902*** 0.219* −0.506*** (0.141) (0.166) (0.155) (0.109) (0.128) (0.0996) Rajsahi 1.508*** 0.433*** −0.141 0.976*** 0.0781 −0.748*** (0.109) (0.142) (0.121) (0.0901) (0.108) (0.0847) Sylhet 0.414** 0.0886 0.193 0.791*** 0.0883 −0.629*** (0.171) (0.222) (0.168) (0.130) (0.163) (0.132) Attends school −3.253*** −3.346*** −3.866*** −3.964*** −3.359*** −3.996*** (0.281) (0.287) (0.228) (0.251) (0.239) (0.151) Remittances −0.319** −0.440*** −0.367*** −0.516*** −0.295** −0.394*** (0.127) (0.139) (0.125) (0.110) (0.123) (0.106) Female −3.038*** −3.288*** −1.753*** −3.197*** −3.580*** −1.563*** (0.161) (0.269) (0.136) (0.146) (0.256) (0.0973) Remittances × Female 0.143 −0.0907 0.0784 0.0908 0.140 −0.352** (0.201) (0.329) (0.189) (0.202) (0.251) (0.166) Married 0.822*** 1.240*** 0.932*** 0.817*** 0.794*** 0.639*** (0.148) (0.159) (0.149) (0.116) (0.128) (0.114) Married × Female −2.151*** −2.283*** −2.376*** −1.856*** −1.477*** −2.115*** (0.202) (0.309) (0.189) (0.176) (0.276) (0.138) Employed Hd head −0.413*** −0.412*** −0.331*** 0.170 −0.0691 0.0817 (0.121) (0.135) (0.112) (0.123) (0.135) (0.0982) Household head with primary & lower secondary −0.952*** −0.244** −0.379*** 1.414*** 0.171 0.213** education (0.104) (0.115) (0.0948) (0.240) (0.160) (0.106) Household head with higher secondary & −1.844*** −0.492** −0.465*** 0.630*** 0.0284 −0.0465 tertiary education (0.314) (0.204) (0.156) (0.244) (0.156) (0.100) Constant −1.512*** −3.638*** −2.838*** −3.080*** −5.940*** −2.808*** (0.364) (0.475) (0.387) (0.414) (0.482) (0.329) Observations 14,058 14,058 14,058 21,715 21,715 21,715 Pseudo R2 0.362 0.362 0.362 0.359 0.359 0.359 Source: Household survey results from Bangladesh (HIES 2000–10). Note: “Working-age” = 15–64 years; Hd = household. Dhaka is the base region. “Nonemployed” is the base category. Remittances × Female = interaction effect between remittances and female. Married × Female = interaction effect between married and female. Standard errors in parentheses. HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics). a. Nonagricultural self-employment. *p < 0.1, **p < 0.05, ***p < 0.01 Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Table 6A.5 Multinomial Logit on Occupational Choice of Working-Age Population, by Household Status, in Peru, 2004 and 2010 2004 2010 Head Spouse Other Head Spouse Other Salaried Self- Salaried Self- Salaried Self- Salaried Self- Salaried Self- Salaried Self- job employed job employed job employed job employed job employed job employed At least high school 0.609*** 0.416*** 0.809*** 0.527*** education (0.0476) (0.0690) (0.0510) (0.0748) Head or spouse with 0.395*** −0.0337 0.547*** 0.0410 −0.323*** −0.572*** 0.185* −0.128 0.675*** 0.119 −0.324*** −0.384*** at least high school (0.0882) (0.0881) (0.0940) (0.0685) (0.0517) (0.0730) (0.102) (0.103) (0.0917) (0.0763) (0.0562) (0.0787) education Age (years) 26–35 0.737*** 1.052*** 0.709*** 0.693*** 0.777*** 1.305*** 0.401* 0.844*** 0.439*** 0.856*** 0.863*** 1.181*** (0.187) (0.205) (0.165) (0.125) (0.0567) (0.0774) (0.233) (0.257) (0.161) (0.154) (0.0648) (0.0866) 36–45 0.673*** 1.208*** 0.859*** 0.746*** 0.564*** 1.312*** 0.286 0.894*** 0.570*** 0.946*** 0.796*** 1.425*** (0.176) (0.194) (0.172) (0.128) (0.0941) (0.113) (0.224) (0.246) (0.165) (0.154) (0.0997) (0.122) 46–55 0.127 0.778*** 0.192 0.179 0.372*** 1.211*** −0.189 0.603** 0.296* 0.757*** 0.316** 1.458*** (0.179) (0.196) (0.190) (0.139) (0.144) (0.167) (0.229) (0.250) (0.177) (0.162) (0.154) (0.163) 56–65 −1.287*** −0.128 −0.479* −0.200 −0.790*** 0.455** −1.307*** −0.204 −0.727*** 0.260 −1.248*** 0.911*** (0.182) (0.198) (0.272) (0.153) (0.215) (0.227) (0.232) (0.250) (0.210) (0.173) (0.274) (0.222) At least one family 0.0356 1.314*** −1.118*** 0.689*** −0.261*** 0.218** −0.0482 1.003*** −0.844*** 0.811*** −0.202*** 0.221** worker (0.239) (0.208) (0.234) (0.0909) (0.0633) (0.0938) (0.330) (0.314) (0.188) (0.0940) (0.0668) (0.0984) Farm household −0.315** −0.900*** −0.829*** −0.480*** −0.317*** −0.568*** −0.162 −0.573*** −0.927*** −0.591*** −0.244*** −0.402*** (0.150) (0.170) (0.134) (0.103) (0.0711) (0.104) (0.171) (0.185) (0.143) (0.107) (0.0771) (0.116) Female −1.640*** −0.949*** −2.191*** −0.974*** −0.712*** −0.643*** −1.412*** −1.193*** −1.975*** −0.736*** −0.685*** −0.623*** (0.129) (0.127) (0.231) (0.245) (0.0448) (0.0630) (0.152) (0.155) (0.224) (0.234) (0.0477) (0.0661) Attends school −0.773*** −1.019*** 0.995*** −0.00837 −1.110*** −0.803*** 0.0414 −0.673** 0.714** −0.461 −1.163*** −0.917*** (0.206) (0.252) (0.298) (0.340) (0.0600) (0.0840) (0.275) (0.301) (0.279) (0.350) (0.0578) (0.0842) Married −0.141 −0.0760 0.00307 0.267*** −0.185 −0.236 −0.109 0.138 (0.128) (0.128) (0.0608) (0.0833) (0.155) (0.158) (0.0689) (0.0866) table continues next page 157 158 Table 6A.5  Multinomial Logit on Occupational Choice of Working-Age Population, by Household Status, in Peru, 2004 and 2010 (continued) 2004 2010 Head Spouse Other Head Spouse Other Salaried Self- Salaried Self- Salaried Self- Salaried Self- Salaried Self- Salaried Self- job employed job employed job employed job employed job employed job employed Head employed −0.00833 −0.431*** −0.0719 0.0156 0.203 −0.212* −0.0477 0.117 (0.155) (0.106) (0.0586) (0.0775) (0.163) (0.125) (0.0706) (0.0889) Spouse employed  0.0886* 0.0435 0.0948* 0.0138 (0.0496) (0.0688) (0.0513) (0.0733) Costa −0.00486 0.0614 −0.153 0.307*** −0.0886 0.201** −0.0765 0.121 0.0767 0.367*** −0.366*** −0.0823 (0.103) (0.103) (0.107) (0.0891) (0.0586) (0.0808) (0.118) (0.119) (0.108) (0.0990) (0.0671) (0.0904) Sierra −0.0484 0.0569 −0.150 0.340*** −0.418*** −0.0714 −0.0881 0.256** −0.0680 0.289*** −0.477*** −0.275*** (0.109) (0.110) (0.113) (0.0921) (0.0625) (0.0861) (0.125) (0.127) (0.112) (0.100) (0.0715) (0.0944) Selva −0.190 0.105 −0.0935 0.200** −0.388*** −0.0687 −0.0160 0.304** 0.0924 0.383*** −0.457*** −0.0230 (0.128) (0.125) (0.120) (0.101) (0.0715) (0.0987) (0.141) (0.143) (0.117) (0.105) (0.0763) (0.0987) Rural 0.314*** −0.414*** −0.457*** −0.674*** −0.0716 −0.570*** −0.00734 −0.609*** −0.308** −0.737*** −0.0120 −0.543*** (0.113) (0.121) (0.129) (0.0973) (0.0716) (0.103) (0.148) (0.152) (0.139) (0.106) (0.0774) (0.118) Child ≤5 0.0589 0.176* −0.300*** −0.349*** −0.0138 −0.0140 −0.313*** −0.179*** (0.0971) (0.102) (0.0670) (0.0496) (0.0861) (0.0898) (0.0621) (0.0418) Constant 1.349*** 0.477** 0.594* 0.289 −0.0442 −1.454*** 2.166*** 1.253*** 0.687** −0.165 0.315*** −1.089*** (0.204) (0.220) (0.329) (0.291) (0.0809) (0.114) (0.273) (0.288) (0.306) (0.299) (0.100) (0.131) Observations 10,087 10,087 12,004 12,004 21,720 21,720 8,312 8,312 9,327 9,327 16,824 16,824 Pseudo R2 0.0879 0.0879 0.0914 0.0914 0.118 0.118 0.0599 0.0599 0.0950 0.0950 0.136 0.136 Source: Household survey results from Peru (ENAHO 2004–10). Note: “Working age” = 15–64 years. Standard errors in parentheses. “Other” = household members who are neither household heads nor spouses. ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information). *p < 0.1, **p < 0.05, ***p < 0.01 Table 6A.6 Multinomial Logit on Occupational Choice of Working-Age Population, by Household Status, in Thailand, 2000 and 2009 2000 2009 Head Spouse Other Head Spouse Other Wage Self- Wage Self- Wage Self- Wage Self- Wage Self- Wage Self- worker employed worker employed worker employed worker employed worker employed worker employed 6–11 yrs educ. 0.452*** 0.541*** 0.655*** 0.581*** (0.0846) (0.133) (0.0775) (0.107) >11 yrs educ. 0.610*** 0.443*** 1.336*** 0.887*** (0.0881) (0.142) (0.0796) (0.114) Head of household education (years) 6–11 0.128 0.0573 −0.157* 0.321*** −0.121 −0.141 0.194** 0.0547 0.0444 0.313*** −0.0690 −0.145 (0.123) (0.133) (0.0898) (0.123) (0.0876) (0.152) (0.0819) (0.0855) (0.0716) (0.0867) (0.0624) (0.120) >11 0.797*** −0.256* −0.422*** 0.309** 0.173* −0.224 0.616*** −0.221** 0.0599 0.434*** −0.0296 −0.190 (0.121) (0.140) (0.116) (0.153) (0.103) (0.210) (0.0842) (0.0886) (0.0839) (0.103) (0.0681) (0.125) Spouse education <6 0.316** 0.581*** −0.252*** −0.285*** 0.540*** 0.581*** −0.258*** −0.169* (0.157) (0.172) (0.0659) (0.109) (0.120) (0.123) (0.0563) (0.0914) 6–11 0.829*** 1.204*** 0.240** −0.124 −0.363*** −0.636*** 0.478*** 0.807*** 0.237*** 0.0360 −0.390*** −0.307** (0.188) (0.206) (0.0977) (0.126) (0.119) (0.234) (0.126) (0.132) (0.0757) (0.0867) (0.0787) (0.138) >11 0.660*** 1.021*** 1.164*** −0.552*** −0.188 −0.274 0.598*** 0.881*** 0.842*** −0.200* −0.422*** −0.358** (0.200) (0.217) (0.127) (0.175) (0.163) (0.278) (0.125) (0.134) (0.0879) (0.113) (0.0905) (0.165) Age (years) 26–35 0.936*** 1.936*** 0.00906 1.252*** 0.597*** 1.524*** 1.159*** 2.171*** 0.157 0.743*** 0.758*** 1.352*** (0.178) (0.244) (0.146) (0.256) (0.0681) (0.131) (0.156) (0.227) (0.114) (0.245) (0.0556) (0.117) 36–45 0.591*** 1.977*** −0.328** 1.421*** 0.482*** 1.888*** 0.619*** 2.028*** −0.0610 1.234*** 0.549*** 1.760*** (0.171) (0.238) (0.149) (0.258) (0.0988) (0.166) (0.150) (0.219) (0.111) (0.237) (0.0663) (0.123) 46–55 −0.270 1.263*** −0.881*** 1.221*** −0.0748 1.667*** −0.222 1.427*** −0.611*** 1.070*** 0.225** 1.778*** (0.182) (0.243) (0.160) (0.269) (0.140) (0.206) (0.140) (0.212) (0.118) (0.240) (0.0972) (0.147) 56–65 −1.997*** −0.121 −2.002*** 0.282 −2.409*** 0.237 −1.934*** 0.102 −1.705*** 0.240 −1.330*** 0.740*** (0.178) (0.240) (0.188) (0.285) (0.218) (0.300) (0.147) (0.214) (0.138) (0.249) (0.143) (0.184) Female −1.169*** −0.649*** −0.972*** −0.108 −0.459*** −0.199** −1.020*** −0.563*** −1.214*** −0.394*** −0.531*** −0.326*** (0.111) (0.120) (0.141) (0.177) (0.0532) (0.0923) (0.0719) (0.0734) (0.0762) (0.0953) (0.0426) (0.0709) table continues next page 159 160 Table 6A.6  Multinomial Logit on Occupational Choice of Working-Age Population, by Household Status, in Thailand, 2000 and 2009 (continued) 2000 2009 Head Spouse Other Head Spouse Other Wage Self- Wage Self- Wage Self- Wage Self- Wage Self- Wage Self- worker employed worker employed worker employed worker employed worker employed worker employed Central −0.0226 0.0373 0.0240 0.0409 −0.404*** −0.153 0.278*** 0.302*** 0.109 0.248** 0.0418 0.0641 (0.125) (0.133) (0.107) (0.141) (0.0940) (0.167) (0.0865) (0.0923) (0.0788) (0.107) (0.0639) (0.112) North 0.0286 0.0767 0.382*** 0.579*** −0.343*** 0.269 −0.188** 0.295*** −0.403*** 0.417*** −0.407*** 0.110 (0.129) (0.139) (0.114) (0.146) (0.102) (0.170) (0.0944) (0.0983) (0.0886) (0.109) (0.0735) (0.121) Northeast −0.502*** −0.502*** −0.0292 0.249* −0.755*** −0.347** −0.690*** −0.0869 −0.469*** 0.255** −0.649*** −0.0379 (0.125) (0.133) (0.110) (0.144) (0.0956) (0.173) (0.0908) (0.0954) (0.0864) (0.109) (0.0693) (0.119) South 0.0191 0.255* −0.358*** 0.372** −0.874*** −0.161 0.172 0.420*** −0.230** 0.518*** −0.105 0.339** (0.140) (0.149) (0.116) (0.145) (0.102) (0.178) (0.108) (0.114) (0.0931) (0.116) (0.0801) (0.136) Urban 0.107 0.842*** −0.345*** −0.0744 −0.162*** 0.109 0.0459 0.728*** −0.277*** 0.0603 −0.151*** 0.144** (0.0766) (0.0855) (0.0686) (0.0821) (0.0534) (0.0936) (0.0569) (0.0597) (0.0498) (0.0587) (0.0420) (0.0686) Head employed 0.575*** −0.277** 0.00257 −0.130 0.599*** −0.217*** −0.220*** −0.406*** (0.111) (0.119) (0.0620) (0.100) (0.0814) (0.0837) (0.0498) (0.0784) Spouse employed 0.185*** 0.240* 0.276*** 0.146 (0.0710) (0.130) (0.0566) (0.105) Married −0.660*** −0.630*** 0.111* 0.449*** −0.640*** −0.569*** 0.190*** 0.711*** (0.138) (0.155) (0.0574) (0.0986) (0.112) (0.116) (0.0470) (0.0734) Attends school −2.980*** −2.716*** −0.649 0.399 −3.489*** −3.428*** −2.325*** −2.473*** −0.127 −2.850*** −3.016*** −3.195*** (0.235) (0.399) (0.546) (0.502) (0.110) (0.353) (0.283) (0.286) (0.271) (0.656) (0.0823) (0.254) Number of children −0.371*** −0.167** −0.525*** −0.398*** −0.350*** −0.286*** −0.575*** −0.386*** < 5 years old (0.0668) (0.0689) (0.0582) (0.0689) (0.0550) (0.0562) (0.0488) (0.0574) Constant 2.002*** −0.884*** 0.969*** −1.936*** 0.810*** −2.567*** 1.825*** −1.034*** 1.009*** −1.653*** 0.145 −2.818*** (0.226) (0.281) (0.249) (0.357) (0.141) (0.245) (0.178) (0.238) (0.176) (0.289) (0.113) (0.189) Observations 15,221 15,221 11,386 11,386 19,603 19,603 25,341 25,341 19,176 19,176 31,564 31,564 Pseudo R2 0.163 0.163 0.0883 0.0883 0.266 0.266 0.145 0.145 0.106 0.106 0.262 0.262 Source: Household survey results from Thailand (SES 2000–09). Note: “Working age” = 15–64 years; “Other” = household members who are neither heads of households nor spouses. Sample includes individuals who are nonfarmers in main occupation. The omitted occupational category includes family workers, unemployed, and inactive individuals (that is, individuals with zero earnings). Standard errors in parentheses. SES = Household Socio-Economic Survey (Thailand National Statistical Office). *p < 0.1, **p < 0.05, ***p < 0.01 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 161 Table 6A.7 Earnings Regressions for Nonfarm Working-Age Population in Bangladesh, 2000 and 2010 2000 2010 Self- Self- Daily workers employeda Wage worker Daily workers employeda Wage worker a. Household heads Primary & lower 0.132*** 0.370*** 0.330*** 0.0530*** 0.312*** 0.357*** secondary education (0.0392) (0.0484) (0.0499) (0.0150) (0.0387) (0.0387) Higher secondary & 0.420** 0.994*** 0.796*** 0.248*** 0.632*** 0.826*** tertiary education (0.164) (0.0810) (0.0551) (0.0654) (0.0625) (0.0420) Age 0.0510*** 0.0591*** 0.0529*** 0.0224*** 0.0411*** 0.0916*** (0.00989) (0.0186) (0.0161) (0.00426) (0.0149) (0.0117) Age squared −0.000666*** −0.000664*** −0.000570*** −0.000267*** −0.000541*** −0.00107*** (0.000119) (0.000219) (0.000191) (5.09e-05) (0.000172) (0.000138) Female −0.894*** −1.477*** −0.956*** −0.688*** −1.080*** −0.709*** (0.0621) (0.166) (0.0849) (0.0266) (0.138) (0.0609) Urban 0.0863* 0.234*** 0.108** −0.0217 0.264*** 0.117*** (0.0447) (0.0495) (0.0421) (0.0164) (0.0396) (0.0315) Barisal 0.0601 −0.193** −0.0421 0.0120 −0.0592 −0.0989 (0.0641) (0.0966) (0.0880) (0.0293) (0.0857) (0.0671) Chittagong −0.0891* −0.0956 −0.0181 0.0488** −0.152** −0.0456 (0.0461) (0.0622) (0.0521) (0.0194) (0.0597) (0.0405) Khulna 0.103** −0.108 −0.0193 −0.216*** −0.212*** −0.184*** (0.0478) (0.0747) (0.0677) (0.0194) (0.0621) (0.0506) Rajsahi −0.182*** −0.242*** −0.195*** −0.179*** −0.314*** −0.112** (0.0364) (0.0589) (0.0610) (0.0160) (0.0466) (0.0454) Sylhet −0.0841 −0.183 −0.370*** −0.0994*** 0.302*** −0.0124 (0.0604) (0.131) (0.111) (0.0298) (0.0846) (0.0812) Manufacturing 0.432*** 0.446*** 0.0674*** 0.107 (0.0456) (0.0780) (0.0196) (0.0699) Industry 0.178*** 0.00876 0.433*** 0.272*** −0.0833 0.250** (0.0547) (0.0962) (0.121) (0.0201) (0.146) (0.0969) Services 0.429*** −0.0220 0.403*** 0.111*** −0.0844* 0.0882 (0.0379) (0.0472) (0.0740) (0.0156) (0.0475) (0.0670) Public job 0.178*** 0.320*** (0.0452) (0.0393) Constant 6.395*** 6.636*** 6.256*** 7.190*** 7.164*** 5.698*** (0.198) (0.386) (0.334) (0.0872) (0.317) (0.248) Observations 2,092 1,269 1,134 3,390 2,007 1,820 R2 0.216 0.240 0.401 0.289 0.183 0.373 Adjusted R2 0.211 0.232 0.393 0.286 0.177 0.368 b. Other members Primary & lower 0.133** 0.449*** 0.459*** 0.0492** 0.0246 0.292*** secondary education (0.0554) (0.0831) (0.0674) (0.0211) (0.0676) (0.0372) Higher secondary & 0.114 0.975*** 0.837*** 0.466*** 0.331*** 0.954*** tertiary education (0.270) (0.124) (0.0854) (0.0992) (0.107) (0.0478) Age 0.0514*** 0.0693*** 0.0478*** 0.0384*** 0.124*** 0.0693*** (0.0131) (0.0222) (0.0178) (0.00593) (0.0167) (0.00975) Age squared −0.000633*** −0.000774** −0.000444 −0.000470*** −0.00170*** −0.000846*** (0.000203) (0.000350) (0.000282) (9.17e-05) (0.000246) (0.000153) table continues next page Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 162 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand Table 6A.7  Earnings Regressions for Nonfarm Working-Age Population in Bangladesh, 2000 and 2010 (continued) 2000 2010 Self- Self- Daily workers employeda Wage worker Daily workers employeda Wage worker Female −1.078*** −1.244*** −0.682*** −0.691*** −1.132*** −0.462*** (0.0698) (0.121) (0.0656) (0.0301) (0.0841) (0.0331) Urban −0.0135 0.0209 −0.147** −0.104*** 0.287*** −0.0407 (0.0737) (0.0803) (0.0619) (0.0276) (0.0615) (0.0316) Barisal 0.216* −0.0186 −0.228* 0.0885* 0.156 −0.0396 (0.111) (0.151) (0.124) (0.0502) (0.127) (0.0752) Chittagong −0.200*** −0.123 −0.178** 0.101*** −0.149* −0.0281 (0.0756) (0.101) (0.0704) (0.0321) (0.0883) (0.0388) Khulna −0.107 −0.0433 −0.215* −0.204*** −0.297*** −0.237*** (0.0855) (0.121) (0.117) (0.0338) (0.0907) (0.0562) Rajsahi −0.227*** −0.396*** −0.295*** −0.103*** −0.00253 −0.0741 (0.0665) (0.103) (0.0910) (0.0281) (0.0756) (0.0481) Sylhet −0.231** −0.481*** −0.636*** 0.0448 0.125 −0.0857 (0.103) (0.166) (0.125) (0.0389) (0.112) (0.0741) Manufacturing 0.300*** 0.463*** −0.169*** 0.149* (0.0674) (0.145) (0.0274) (0.0904) Industry 0.448*** −0.0366 0.440** 0.174*** 0.700*** 0.0853 (0.0897) (0.148) (0.221) (0.0296) (0.171) (0.126) Services 0.469*** 0.0881 0.297** 0.0930*** 0.195*** −0.0847 (0.0692) (0.0777) (0.144) (0.0276) (0.0707) (0.0905) Public job 0.555*** 0.437*** (0.0921) (0.0522) Constant 6.270*** 6.379*** 6.198*** 6.974*** 5.456*** 6.227*** (0.192) (0.334) (0.285) (0.0892) (0.273) (0.163) Observations 1,153 673 1,104 1,857 973 1,984 R2 0.307 0.317 0.285 0.383 0.343 0.348 Adjusted R2 0.299 0.304 0.275 0.379 0.334 0.343 Source: Household survey results from Bangladesh (HIES 2000–10). Note: “Working-age” = 15–64 years. Dhaka is the base region. “Illiterate and incomplete primary” education is the base for educational levels. “Agriculture” is the base sector for “Daily” and “wage” workers, while “Manufacturing” is the base sector for “self-employed.” Standard errors in parentheses. HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics). a. Nonagricultural self-employment. *p < 0.1, **p < 0.05, ***p < 0.01 Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Table 6A.8 Earnings Regressions for Nonfarm Working-Age Population in Peru, 2004 and 2010 2004 2010 Head Spouse Other Head Spouse Other Salaried Self- Salaried Self- Salaried Self- Salaried Self- Salaried Self- Salaried Self- job employed job employed job employed job employed job employed job employed Education type Primary 0.132*** 0.296*** 0.0984** 0.148*** 0.220*** 0.142*** (0.0383) (0.0637) (0.0417) (0.0367) (0.0623) (0.0457) Secondary 0.350*** 0.558*** 0.238*** 0.271*** 0.519*** 0.278*** (0.0382) (0.0663) (0.0415) (0.0359) (0.0633) (0.0451) College 0.837*** 0.937*** 0.570*** 0.627*** 0.825*** 0.578*** (0.0404) (0.0727) (0.0452) (0.0381) (0.0662) (0.0477) Age (years) 26–35 0.243*** 0.314*** 0.280*** 0.291*** 0.321*** 0.389*** 0.169*** 0.305*** 0.249*** 0.457*** 0.283*** 0.556*** (0.0441) (0.0842) (0.0875) (0.0955) (0.0206) (0.0486) (0.0422) (0.0946) (0.0754) (0.110) (0.0198) (0.0539) 36–45 0.358*** 0.428*** 0.318*** 0.372*** 0.313*** 0.482*** 0.192*** 0.390*** 0.254*** 0.591*** 0.285*** 0.705*** (0.0436) (0.0818) (0.0876) (0.0946) (0.0307) (0.0634) (0.0413) (0.0922) (0.0731) (0.108) (0.0289) (0.0691) 46–55 0.405*** 0.277*** 0.357*** 0.329*** 0.396*** 0.339*** 0.167*** 0.253*** 0.241*** 0.554*** 0.251*** 0.545*** (0.0446) (0.0824) (0.0922) (0.0983) (0.0484) (0.0935) (0.0419) (0.0919) (0.0759) (0.110) (0.0462) (0.0899) 56–65 0.305*** 0.0801 0.541*** 0.128 0.548*** 0.220 0.0896** −0.00376 0.405*** 0.418*** 0.223** 0.711*** (0.0504) (0.0845) (0.107) (0.106) (0.0968) (0.156) (0.0456) (0.0940) (0.0907) (0.116) (0.0994) (0.133) Female −0.427*** −0.582*** −0.166*** −0.601*** −0.435*** −0.781*** −0.236*** −0.859*** (0.0287) (0.0338) (0.0182) (0.0416) (0.0235) (0.0337) (0.0172) (0.0461) Informal −0.373*** −0.554*** −0.539*** −0.568*** −0.336*** −0.538*** −0.383*** −0.596*** −0.731*** −0.829*** −0.373*** −0.580*** (0.0248) (0.0323) (0.0504) (0.0592) (0.0194) (0.0505) (0.0229) (0.0317) (0.0425) (0.0554) (0.0187) (0.0545) Manufacturing 0.0471 0.327*** 0.299*** −0.00185 0.497*** 0.153*** (0.0383) (0.0924) (0.0347) (0.0371) (0.0856) (0.0339) Services −0.0832*** −0.00266 0.402*** 0.855*** 0.266*** 0.478*** 0.0911*** 0.113*** 0.599*** 0.723*** 0.209*** 0.534*** (0.0322) (0.0396) (0.0770) (0.0569) (0.0297) (0.0648) (0.0312) (0.0414) (0.0708) (0.0575) (0.0287) (0.0713) Public sector −0.188*** 0.352*** 0.337*** −0.0215 0.460*** 0.287*** (0.0357) (0.0804) (0.0387) (0.0351) (0.0736) (0.0368) table continues next page 163 164 Table 6A.8  Earnings Regressions for Nonfarm Working-Age Population in Peru, 2004 and 2010 (continued) 2004 2010 Head Spouse Other Head Spouse Other Salaried Self- Salaried Self- Salaried Self- Salaried Self- Salaried Self- Salaried Self- job employed job employed job employed job employed job employed job employed Costa −0.360*** −0.491*** −0.392*** −0.575*** −0.459*** −0.682*** −0.233*** −0.234*** −0.347*** −0.176*** −0.255*** −0.298*** (0.0257) (0.0345) (0.0502) (0.0526) (0.0222) (0.0501) (0.0231) (0.0353) (0.0457) (0.0543) (0.0219) (0.0563) Sierra −0.342*** −0.632*** −0.570*** −0.563*** −0.599*** −0.730*** −0.233*** −0.212*** −0.486*** −0.305*** −0.370*** −0.386*** (0.0283) (0.0393) (0.0537) (0.0553) (0.0257) (0.0612) (0.0254) (0.0391) (0.0494) (0.0581) (0.0241) (0.0676) Selva −0.452*** −0.521*** −0.409*** −0.490*** −0.442*** −0.645*** −0.209*** −0.201*** −0.444*** −0.0545 −0.230*** −0.232*** (0.0381) (0.0501) (0.0667) (0.0686) (0.0339) (0.0784) (0.0347) (0.0512) (0.0638) (0.0703) (0.0315) (0.0787) Rural −0.186*** −0.200*** −0.104 −0.496*** −0.0519* −0.524*** −0.208*** −0.196*** −0.196*** −0.513*** −0.112*** −0.348*** (0.0339) (0.0595) (0.0675) (0.0540) (0.0289) (0.0722) (0.0318) (0.0575) (0.0629) (0.0573) (0.0259) (0.0739) Has two jobs 0.243*** 0.229*** 0.324*** 0.539*** 0.316*** 0.448*** 0.0652*** 0.190*** 0.163*** 0.403*** 0.111*** 0.361*** (0.0284) (0.0435) (0.0575) (0.0601) (0.0317) (0.0700) (0.0228) (0.0387) (0.0454) (0.0543) (0.0262) (0.0637) Head/spouse with at 0.201*** 0.156*** −0.241*** 0.0844*** 0.103** −0.266*** least secondary (0.0312) (0.0432) (0.0457) (0.0327) (0.0466) (0.0477) At least one family 0.307*** 0.160*** −0.00777 0.246*** 0.283*** −0.00123 worker (0.0525) (0.0535) (0.0601) (0.0554) (0.0552) (0.0652) At least secondary 0.178*** 0.410*** (0.0482) (0.0540) Constant 6.248*** 6.709*** 5.268*** 5.133*** 5.813*** 5.949*** 6.495*** 6.764*** 5.462*** 5.114*** 5.992*** 5.530*** (0.0605) (0.0954) (0.115) (0.127) (0.0484) (0.0978) (0.0592) (0.107) (0.105) (0.137) (0.0506) (0.109) Observations 4,758 3,651 1,665 3,022 6,374 2,375 5,483 4,250 2,326 3,586 7,963 2,817 R2 0.370 0.300 0.444 0.264 0.414 0.380 0.271 0.265 0.437 0.198 0.300 0.327 Sigma 0.650 0.846 0.761 1.049 0.722 1.025 0.649 0.921 0.801 1.206 0.764 1.162 Source: Household survey results from Peru (ENAHO 2005–09). Note: “Working age” = 15–64 years. Standard errors in parentheses. “Other” = those who are neither household heads nor spouses. ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information). *p < 0.1, **p < 0.05, ***p < 0.01. Table 6A.9 Earnings Regressions for Nonfarm Working-Age Population in Thailand, 2000 and 2009 2000 2009 Head Spouse Others Head Spouse Others Wage Self- Wage Self- Wage Self- Wage Self- Wage Self- Wage Self- worker employed worker employed worker employed worker employed worker employed worker employed Education (years) 6–11 yrs 0.375*** 0.289*** 0.330*** 0.240*** 0.428*** 0.378*** 0.369*** 0.129* (0.0240) (0.0365) (0.0321) (0.0788) (0.0176) (0.0243) (0.0264) (0.0716) >11 yrs 0.944*** 1.104*** 0.783*** 0.454*** 1.089*** 1.058*** 0.888*** 0.376*** (0.0256) (0.0413) (0.0348) (0.0863) (0.0180) (0.0261) (0.0269) (0.0733) Head of household education (years) 6–11 0.185*** 0.171*** 0.0273 0.211*** 0.194*** 0.0753 (0.0387) (0.0558) (0.0969) (0.0306) (0.0459) (0.0654) >11 0.534*** 0.316*** 0.291** 0.508*** 0.321*** 0.0711 (0.0493) (0.0733) (0.117) (0.0355) (0.0530) (0.0767) Spouse education (years) <6 0.108** 0.105* 0.177*** −0.00364 (0.0480) (0.0592) (0.0357) (0.0459) 6–11 0.285*** 0.0293 0.287* 0.270*** 0.154*** −0.114 (0.0523) (0.0637) (0.150) (0.0351) (0.0488) (0.0899) >11 0.460*** 0.434*** 0.0742 0.344*** 0.267*** −0.0660 (0.0631) (0.0942) (0.168) (0.0384) (0.0612) (0.107) Age (years) 26–35 0.304*** 0.140 0.211*** −0.0875 0.341*** 0.485*** 0.259*** 0.205** 0.209*** 1.186*** 0.391*** 0.367*** (0.0326) (0.108) (0.0451) (0.168) (0.0210) (0.0771) (0.0258) (0.102) (0.0361) (0.146) (0.0144) (0.0671) 36–45 0.534*** 0.277*** 0.341*** 0.203 0.497*** 0.745*** 0.457*** 0.309*** 0.361*** 1.331*** 0.573*** 0.592*** (0.0337) (0.107) (0.0500) (0.169) (0.0322) (0.0901) (0.0252) (0.0991) (0.0358) (0.140) (0.0181) (0.0691) 46–55 0.597*** 0.414*** 0.440*** 0.199 0.612*** 0.696*** 0.656*** 0.244** 0.577*** 1.364*** 0.699*** 0.508*** (0.0367) (0.109) (0.0576) (0.174) (0.0578) (0.126) (0.0266) (0.0999) (0.0391) (0.144) (0.0292) (0.0885) 56–65 0.395*** 0.0838 0.141* 0.0322 0.348*** −0.0913 0.541*** −0.00722 0.487*** 1.169*** 0.643*** 0.185 (0.0436) (0.113) (0.0746) (0.182) (0.130) (0.183) (0.0311) (0.102) (0.0489) (0.150) (0.0597) (0.126) table continues next page 165 166 Table 6A.9  Earnings Regressions for Nonfarm Working-Age Population in Thailand, 2000 and 2009 (continued) 2000 2009 Head Spouse Others Head Spouse Others Wage Self- Wage Self- Wage Self- Wage Self- Wage Self- Wage Self- worker employed worker employed worker employed worker employed worker employed worker employed Female −0.283*** −0.271*** −0.246*** −0.291*** −0.0594*** −0.0789 −0.242*** −0.254*** −0.243*** −0.278*** −0.0650*** −0.166*** (0.0193) (0.0448) (0.0443) (0.109) (0.0191) (0.0568) (0.0130) (0.0286) (0.0207) (0.0541) (0.0124) (0.0417) Services 1.159*** 0.0232 1.136*** 0.665*** 1.026*** 0.357*** 0.635*** −0.0124 0.649*** 0.613*** 0.518*** 0.314*** (0.0284) (0.0407) (0.0402) (0.0573) (0.0315) (0.0703) (0.0223) (0.0299) (0.0307) (0.0456) (0.0257) (0.0533) Central −0.0730*** −0.102** −0.0775* −0.254*** −0.115*** −0.268*** −0.196*** −0.206*** −0.149*** −0.131** −0.278*** −0.393*** (0.0253) (0.0438) (0.0412) (0.0842) (0.0313) (0.0978) (0.0183) (0.0353) (0.0280) (0.0660) (0.0210) (0.0765) North −0.578*** −0.558*** −0.646*** −0.674*** −0.696*** −0.420*** −0.499*** −0.403*** −0.598*** −0.507*** −0.629*** −0.750*** (0.0306) (0.0525) (0.0481) (0.0845) (0.0360) (0.105) (0.0232) (0.0405) (0.0338) (0.0692) (0.0247) (0.0814) Northeast −0.694*** −0.630*** −0.692*** −0.690*** −0.786*** −0.726*** −0.611*** −0.411*** −0.627*** −0.436*** −0.694*** −0.662*** (0.0292) (0.0490) (0.0468) (0.0838) (0.0346) (0.102) (0.0217) (0.0373) (0.0319) (0.0673) (0.0227) (0.0773) South −0.247*** −0.248*** −0.305*** −0.326*** −0.379*** −0.172 −0.279*** −0.237*** −0.237*** −0.236*** −0.500*** −0.342*** (0.0322) (0.0536) (0.0515) (0.0893) (0.0401) (0.116) (0.0228) (0.0414) (0.0340) (0.0710) (0.0251) (0.0853) Urban 0.148*** 0.346*** 0.141*** 0.117** 0.0608** 0.157** 0.268*** 0.410*** 0.247*** 0.360*** 0.254*** 0.325*** (0.0202) (0.0337) (0.0311) (0.0516) (0.0237) (0.0635) (0.0140) (0.0254) (0.0205) (0.0399) (0.0151) (0.0488) Manufacturing 1.067*** 1.041*** 1.071*** 0.636*** 0.612*** 0.482*** (0.0261) (0.0365) (0.0289) (0.0214) (0.0295) (0.0249) Public sector 1.489*** 1.458*** 1.269*** 0.976*** 1.116*** 0.775*** (0.0302) (0.0478) (0.0380) (0.0242) (0.0356) (0.0292) Constant 7.168*** 8.545*** 7.183*** 8.228*** 7.107*** 7.745*** 7.486*** 8.633*** 7.498*** 6.876*** 7.480*** 8.219*** (0.0454) (0.127) (0.0810) (0.218) (0.0491) (0.156) (0.0368) (0.111) (0.0561) (0.169) (0.0393) (0.129) Observations 8,251 4,216 4,138 1,929 7,755 1,350 13,016 7,564 7,216 3,421 13,185 2,587 R2 0.624 0.236 0.627 0.203 0.473 0.176 0.537 0.213 0.522 0.210 0.438 0.175 Sigma 0.725 0.959 0.762 0.975 0.816 1.005 0.667 0.933 0.700 0.978 0.687 1.001 Source: Household survey results from Thailand (SES 2000–09). Note: “Working age” = 15–64 years; “Others” = those who are neither heads of households nor spouses. Standard errors in parentheses. SES = Household Socio-Economic Survey (Thailand National Statistical Office). *p < 0.1, **p < 0.05, ***p < 0.01. Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 167 Table 6A.10 Net Revenue Regressions for Farm Households in Bangladesh, 2000 and 2010 2000 2010 Primary & lower secondary education 0.132** (0.0633) 0.0331 (0.0489) Higher secondary & tertiary education 0.295** (0.147) −0.00290 (0.119) Age 0.142*** (0.0214) 0.0795*** (0.0172) Age squared −0.00175*** (0.000245) −0.000843*** (0.000190) Female −2.243*** (0.123) −0.926*** (0.0605) Urban 0.197 (0.123) −0.161** (0.0816) Barisal −0.285** (0.123) 0.270*** (0.0920) Chittagong −0.240** (0.0977) 0.164** (0.0680) Khulna 0.405*** (0.0955) 0.204*** (0.0751) Rajshahi 0.0125 (0.0763) 0.303*** (0.0629) Sylhet 0.0104 (0.126) 0.253** (0.108) Land (low) −0.107 (0.0986) 0.743*** (0.0666) Land (high) 0.457*** (0.111) 1.333*** (0.0786) Irrigation 0.458*** (0.0941) 0.408*** (0.0707) Household members (no.) 0.525*** (0.0507) 0.429*** (0.0525) Constant 4.007*** (0.462) 4.780*** (0.381) Observations 1,678 2,956 R2 0.340 0.323 Adjusted R2 0.334 0.320 Source: Household survey results from Bangladesh (HIES 2000–10). Note: Results represent net revenue for farm households in Bangladesh. Net revenue was calculated using the available information on total revenue stemming from agricultural production and the cost of inputs. The sample comprises those farm household members of working age (15–64 years) who are self-employed in agriculture. Dhaka is the base region. “Illiterate and incomplete primary” is the base for education. “No-land” is the base category for land tenure. Standard errors appear in parentheses. HIES = Household Income and Expenditure Survey (Bangladesh Bureau of Statistics). *p < 0.1, **p < 0.05, ***p < 0.01. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 168 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand Table 6A.11 Net Revenue Regressions for Farm Households in Peru, 2004 and 2010   2004 2010 Head/spouse with at least secondary 0.133*** (0.0296) 0.128*** (0.0273) Age (years)   26–35 0.267*** (0.0610) 0.231*** (0.0736)   36–45 0.412*** (0.0598) 0.333*** (0.0722)   46–55 0.473*** (0.0600) 0.272*** (0.0724)   56–65 0.373*** (0.0607) 0.214*** (0.0736) Female −0.420*** (0.0349) −0.385*** (0.0318) Head farmer 0.421*** (0.0409) 0.304*** (0.0351) More than 1 farmer in household 0.688*** (0.0571) 0.513*** (0.0453) Land size (ha)   0.5–2 −0.0127 (0.0377) 0.437*** (0.0281)   2–5 0.288*** (0.0443) 0.799*** (0.0348)   >5 0.604*** (0.0468) 1.055*** (0.0371) Share of adults >50 percent 0.0476* (0.0254) 0.0206 (0.0251) Improved irrigation system 0.130*** (0.0340) 0.177*** (0.0249) Owns land −0.218*** (0.0336) 0.0647** (0.0252) Sierra −0.151*** (0.0336) 0.00957 (0.0326) Selva 0.0414 (0.0404) −0.0303 (0.0422) Rural 0.0757** (0.0302) 0.0935*** (0.0303) Constant 4.249*** (0.0784) 4.182*** (0.0845) Observations 6,870 7,117 R2 0.123 0.238 Sigma 0.922 0.894 Source: Household survey results from Peru (ENAHO 2005–09). Note: ha = hectares (1 hectare = about 100 acres or 10,000 square meters). Results represent net revenue for farm households in Bangladesh. Net revenue was calculated using the available information on total revenue stemming from agricultural production and the cost of inputs. Standard errors in parentheses. “Other” = those who are neither household heads nor spouses. ENAHO = Encuesta Nacional de Hogares (Peru National Institute of Statistics and Information). *p < 0.1, **p < 0.05, ***p < 0.01. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 169 Table 6A.12 Net Revenue Regressions for Farm Households in Thailand, 2000 and 2009 2000 2009 Head of household education (years)   6–11 0.0575 (0.0556) 0.0474 (0.0387)   >11 0.273*** (0.105) 0.0814 (0.0565) Spouse education (years)   <6 0.189** (0.0742) 0.343*** (0.0429)   6–11 0.271*** (0.0890) 0.421*** (0.0497)   >11 0.743*** (0.154) 0.629*** (0.0724) Age (years)   26–35 0.177 (0.167) 0.369** (0.170)   36–45 0.426** (0.166) 0.573*** (0.165)   46–55 0.455*** (0.169) 0.612*** (0.167)   56–65 0.545*** (0.170) 0.512*** (0.168) Female −0.334*** (0.0761) −0.158*** (0.0388) North −0.816*** (0.0607) −0.512*** (0.0443) Northeast −1.078*** (0.0556) −1.104*** (0.0413) South −0.0996 (0.0675) 0.220*** (0.0508) Urban −0.171*** (0.0651) −0.0914* (0.0485) Household owns land 0.132 (0.101) 0.167*** (0.0585) Household members older than 18 years of age (%) −0.161* (0.0947) −0.0815 (0.0686) Constant 7.392*** (0.205) 7.394*** (0.177) Observations 5,801 10,118 R2 0.119 0.151 Sigma 1.393 1.348 Source: Household survey results from Thailand (SES 2000–09). Note: HH = household. Standard errors in parentheses. Figure results represent net revenue for farm households in Thailand. Net revenue was calculated using the available information on total revenue stemming from agricultural production and the cost of inputs. Unfortunately, unlike the surveys for Bangladesh and Peru, the household survey for Thailand does not contain information on landholding and access to irrigation. SES = Household Socio-Economic Survey (Thailand National Statistical Office). *p < 0.1, **p < 0.05, ***p < 0.01. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 170 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand Notes 1. As first noted in chapter 1, “moderate poverty” is a country-specific poverty line refer- ring to the international poverty line that is closest to the country’s moderate poverty rate (in some cases $1.25 a day, in others $2.50; and in still others $4–$5 per day). 2. The widely used “cost of basic needs” approach to drawing consumption-based pov- erty lines “first estimates the cost of acquiring enough food for adequate nutrition— usually 2,100 calories per person per day—and then adds the cost of other essentials such as clothing and shelter” (Haughton and Khandker, 2009, 39). 3. Despite this deceleration of population growth, Bangladesh has added 19 billion people to its total, a 15 percent increase between 2000 and 2010. Over the same period, Peru has added 3.2 million (a 12 percent increase) and Thailand 6 million (a 9 percent increase). 4. Net revenue was calculated using the available information on total revenue stem- ming from agricultural production and the cost of inputs. 5. Unfortunately, the household survey for Thailand does not contain information on landholding and access to irrigation. 6. As mentioned earlier, this decomposition method cannot identify the reason behind this change. However, one possible theory is that improved road networks reduced transportation costs and thus allowed for greater returns in investing outside the capital. An alternative explanation is that internal migration toward the capital led to ­ a greater scarcity of workers in other regions, and therefore relatively better earnings. Given the size of this effect, further research on this would be useful to identify the source of change. 7. The cumulative effects are larger because they include all occupational changes, including the choice between daily, wage, and self-employed work for nonfarm workers, and the choice to have a secondary occupation for farm workers. ­ 8. Note that this is consistent with the findings using the simple approach (see table 6.5). 9. Similar analysis about the returns to agriculture in Thailand was not possible because of lack of similar variables in the database used. Bibliography Bourguignon, François, Francisco H. G. Ferreira, and Nora Lustig, eds. 2005. The Microeconomics of Income Distribution Dynamics in East Asia and Latin America. Washington, DC: World Bank. Bourguignon, François, Francisco H. G. Ferreira, and Phillippe G. Leite. 2008. “Beyond Oaxaca-Blinder: Accounting for Differences in Household Income Distributions.” Journal of Economic Inequality 6 (2): 117–48. Datt, Gaurav, and Martin Ravallion. 1992. “Growth and Redistribution Components of Changes in Poverty Measures: A Decomposition with Applications to Brazil and India in the 1980s.” Journal of Development Economics 38 (2): 275–96. Davis, Benjamin, Paul Winters, Calogero Carletto, Katia Covarrubias, Esteban J. Quiñones, Alberto Zezza, Carlo Azzarri, Kostas Stamoulis, and Stefania DiGiuseppe. 2010. “A Cross-Country Comparison of Rural Income Generating Activities.” World Development 38 (1): 48–63. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Understanding Poverty Reduction in Bangladesh, Peru, and Thailand 171 Ferreira, Francisco H. G. 2010. “Distributions in Motion: Economic Growth, Inequality and Poverty Dynamics.” Policy Research Working Paper 5424, World Bank. ———. 2012. “Distributions in Motion: Economic Growth, Inequality, and Poverty Dynamics.” In The Oxford Handbook of the Economics of Poverty, edited by Philip N. Jefferson, 427–62. New York: Oxford University Press. Foster, James, Joel Greer, and Erik Thorbecke. 1984. “A Class of Decomposable Poverty Measures.” Econometrica 52 (3): 761–66. Government of Thailand. 2003. “Thailand’s Official Poverty Lines.” National Economic and Social Development Board, Government of Thailand, Bangkok. Haughton, Jonathan, and Shahidur R. Khandker. 2009. Handbook on Poverty + Inequality. World Bank Training Series. Washington, DC: World Bank. Kakwani, Nanak, and Medhi Krongkaew. 1998. “Poverty in Thailand: Defining, Measuring and Analyzing.” Working Paper N4, Office of the National Economic and Social Development Board, Development Evaluation Division, Bangkok. Ravallion, Martin, and Shaohua Chen. 2007. “China’s (Uneven) Progress against Poverty.” Journal of Development Economics 82 (1): 1–42. Shapley, Lloyd. S. 1953. “A Value for n-Person Games.” In Contributions to the Theory of Games, Vol. 2, edited by H. W. Kuhn and A. W. Tucker, 307–17. Princeton, NJ: Princeton University Press. Shorrocks, Anthony F. 1999. “Decomposition Procedures for Distributional Analysis: A Unified Framework Based on Shapley Value.” University of Essex and Institute for Fiscal Studies, London. Tinbergen, Jan. 1975. Income Differences: Recent Research. Amsterdam, the Netherlands: North-Holland. World Bank. 2011. World Development Indicators 2011. Washington, DC: World Bank. Online database. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 Environmental Benefits Statement The World Bank Group is committed to reducing its environmental footprint. In support of this commitment, the Publishing and Knowledge Division lever- ages electronic publishing options and print-on-demand technology, which is located in regional hubs worldwide. Together, these initiatives enable print runs to be lowered and shipping distances decreased, resulting in reduced paper consumption, chemical use, greenhouse gas emissions, and waste. ­ The Publishing and Knowledge Division follows the recommended standards for paper use set by the Green Press Initiative. Whenever possible, books are printed on 50 percent to 100 percent postconsumer recycled paper, and at least 50 percent of the fiber in our book paper is either unbleached or bleached using Totally Chlorine Free (TCF), Processed Chlorine Free (PCF), or Enhanced Elemental Chlorine Free (EECF) processes. More information about the Bank’s environmental philosophy can be found at http://crinfo.worldbank.org/wbcrinfo/node/4. Understanding Changes in Poverty  •  http://dx.doi.org/10.1596/978-1-4648-0299-7 The 2015 Millennium Development Goal to reduce by 50 percent the share of the world’s population living in extreme poverty was met early. The number of individuals in developing countries who live in extreme poverty had decreased from 43 percent in 1990 to 21 percent by 2010. Yet, with 1.2 billion people still struggling today, we have a long way to go. What can we learn from the recent success of reducing extreme poverty? Understanding Changes in Poverty brings together different methods to decompose the contributions to poverty reduction. A simple approach quantifies the contribution of changes in demographics, employment, earnings, public transfers, and remittances to poverty reduction. A more complex approach quantifies the contributions to poverty reduction from changes in individual and household characteristics, including changes in the sectoral, occupational, and educational structure of the workforce, as well as changes in the returns to individual and household characteristics. Understanding Changes in Poverty implements these approaches and finds that labor income growth—that is, growth in income per worker rather than an increase in the number of employed workers—was the largest contributor to moderate poverty reduction in 21 countries experiencing substantial reductions in poverty over the past decade. Changes in demographics, public transfers, and remittances helped, but made relatively smaller contributions to poverty reduction. Further decompositions in three countries find that labor income grew mainly because of higher returns to human capital endowments, signaling increases in productivity, higher relative price of labor, or both. Understanding Changes in Poverty will be of particular relevance to development practitioners interested in better understanding distributional changes over time. The methods and tools presented in this book can also be applied to better understand changes in inequality or any other distributional change. ISBN 978-1-4648-0299-7 SKU 210299