66814 THE WORLD BANK Rapid Growth and Its Causes in Singapore, Finland, and Ireland Shahid Yusuf and Kaoru Nabeshima Some Small Countries Do It Better Some Small Countries Do It Better Rapid Growth and Its Causes in Singapore, Finland, and Ireland Shahid Yusuf Kaoru Nabeshima © 2012 International Bank for Reconstruction and Development / International Development Association or The World Bank 1818 H Street NW Washington DC 20433 Telephone: 202-473-1000 Internet: www.worldbank.org 1 2 3 4 15 14 13 12 This volume is a product of the staff of The World Bank with external contributions. The findings, interpretations, and conclusions expressed in this volume do not necessarily reflect the views of The World Bank, its Board of Executive Directors, or the governments they represent. The World Bank does not guarantee the accuracy of the data included in this work. 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All other queries on rights and licenses, including subsidiary rights, should be addressed to the Office of the Publisher, The World Bank, 1818 H Street NW, Washington, DC 20433, USA; fax: 202-522-2422; e-mail: pubrights@worldbank.org. ISBN (paper): 978-0-8213-8846-4 ISBN (electronic): 978-0-8213-8925-6 DOI: 10.1596/978-0-8213-8846-4 Library of Congress Cataloging-in-Publication Data has been requested. Cover design: Richard Fletcher, Fletcher Design. Cover photos: Singapore–Design Pics/thinkstock.com; Finland–Harryfn/Dreamstime.com; Ireland–Selensergen/istockphoto.com. Contents Preface and Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ix About the Authors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . xi Abbreviations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . xiii Chapter 1. Looking for Growth . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Growth: The Stylized Facts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 Hunting for Quarks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Looking at the “Sifire” Family of Models . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 Chapter 2. How Sifire Compressed Development . . . . . . . . . . . . . . . . . . . . . . 31 Globalization: The Vital Backdrop . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 Old Light . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 Crises and Consequences . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 Investing in Growth . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41 Learning and Innovation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 Creative Cities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 What Sifire Got Right . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49 Chapter 3. Elements of a Learning Economy . . . . . . . . . . . . . . . . . . . . . . . . . 55 Changes in Economic Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55 The Rise of High-Tech Exports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59 Education Sector: An Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64 Innovation Capabilities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78 Innovation Facilitator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87 Concluding Observations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 Chapter 4. Governance and Growth. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101 Coordinators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104 Institutions for Growth . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109 Power of Urban Networks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115 v vi Contents Chapter 5. Delivering Quality Education . . . . . . . . . . . . . . . . . . . . . . . . . . . 117 The Power of Quality Education . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119 Vocational Training. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123 Sustaining Consistent Performance. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125 Starting Almost from Scratch: What It Takes . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 128 Chapter 6. The Message from Sifire . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 131 Pragmatic Governance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133 Leveraging Global Markets and General-Purpose Technologies . . . . . . . . . . . . 133 Updating the Sifire Experience . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 135 Quality of Human Capital . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 138 Implications for African Countries . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 140 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145 Appendix A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 149 Appendix B . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155 Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 159 Figures 1.1 Sources of Economic Growth by Region, 1989–95 and 1995–2003 . . . . . . 8 1.2 Percentage Point Contribution of Real Net Exports to GDP Growth in Asia, 1995–2000 and 2000–06 . . . . . . . . . . . . . . . . . . . . . . 12 3.1 Finland’s Industrial Composition, 1970–2007 . . . . . . . . . . . . . . . . . . . . . . 56 3.2 Ireland’s Industrial Composition, 1970–2007 . . . . . . . . . . . . . . . . . . . . . . . 58 3.3 Singapore’s Industrial Composition, 1970–2007. . . . . . . . . . . . . . . . . . . . . 59 3.4 Finland’s Composition of Exports by Technology Class, 1970 and 2000. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63 3.5 Ireland’s Composition of Exports by Technology Class, 1970 and 2000. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63 3.6 Singapore’s Composition of Exports by Technology Class, 1970 and 2000. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64 3.7 Average Years of Schooling for People 15-Years-Old and Above, 1960–2000 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66 3.8 Public Expenditure per Student . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67 3.9 Composition of Graduates in Finland, Tertiary Education, 1981–99 . . . . 75 3.10 Openness to Trade, 2001–08 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89 3.11 Imports of Goods and Services, 2001–08. . . . . . . . . . . . . . . . . . . . . . . . . . . 90 3.12 Net Foreign Direct Investment Flows, 1980–2008. . . . . . . . . . . . . . . . . . . . 91 3.13 Royalty Payments, 1975–2007 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93 3.14 Royalty Payments as Share of GDP, 1975–2007. . . . . . . . . . . . . . . . . . . . . . 93 4.1 Finnish Innovation System: Organizations and Coordination . . . . . . . . 106 4.2 Irish Science and Technology Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . 108 4.3 The EDB Network . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109 Contents vii Tables 1.1 Average Annual GDP Growth, 1995–2001 and 2002–08 . . . . . . . . . . . . . . . 5 1.2 Average GDP Per Capita, 1995–2001 and 2002–08 . . . . . . . . . . . . . . . . . . . . 5 1.3 Average Share of Global GDP, 1995–2001 and 2002–08. . . . . . . . . . . . . . . . 5 1.4 African Growth by Sector, 2002–07 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 1.5 Contribution of Capital, Labor, and TFP to World Growth. . . . . . . . . . . . . 7 1.6 Population of the Sifire Group, 1985 and 2008 . . . . . . . . . . . . . . . . . . . . . . 22 1.7 GDP Per Capita of the Sifire Group, 1985 and 2008 . . . . . . . . . . . . . . . . . . 23 1.8 Average Annual GDP Growth of the Sifire Group, 1985–2008 . . . . . . . . . 23 1.9 IMD World Competitiveness Rankings of the Sifire Group, 1989 and 1992. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 1.10 World Economic Forum and IMD Competitiveness Rankings of the Sifire Group, 2003 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 3.1 Finland’s Top 10 Exports in 1970, by Value . . . . . . . . . . . . . . . . . . . . . . . . . 60 3.2 Finland’s Top 10 Exports in 2000, by Value . . . . . . . . . . . . . . . . . . . . . . . . . 60 3.3 Ireland’s Top 10 Exports in 1970, by Value . . . . . . . . . . . . . . . . . . . . . . . . . 61 3.4 Ireland’s Top 10 Exports in 2000, by Value . . . . . . . . . . . . . . . . . . . . . . . . . 61 3.5 Singapore’s Top 10 Exports in 1970, by Value . . . . . . . . . . . . . . . . . . . . . . . 62 3.6 Singapore’s Top 10 Exports in 2000, by Value . . . . . . . . . . . . . . . . . . . . . . . 62 3.7 Public Expenditure on Education, 1970–2006 . . . . . . . . . . . . . . . . . . . . . . 65 3.8 Share of Public Expenditure for Education, 1970–2007 . . . . . . . . . . . . . . 66 3.9 Primary Enrollment, 1970–2007. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68 3.10 Secondary Enrollment, 1970–2007 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69 3.11 Vocational and Technical Enrollment, 2003–2007 . . . . . . . . . . . . . . . . . . . 69 3.12 Singapore’s TIMSS Ranks and Scores, 1995–2007 . . . . . . . . . . . . . . . . . . . 71 3.13 PISA Ranks and Scores, 2000–09 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72 3.14 Tertiary-Level Education Gross Enrollment Rates, 1970–2007 . . . . . . . . . 73 3.15 Labor Force with Tertiary Education, 1995–2006 . . . . . . . . . . . . . . . . . . . 73 3.16 Tertiary-Level Enrollment Composition, 2007 . . . . . . . . . . . . . . . . . . . . . . 74 3.17 Composition of Tertiary Education Graduates, 2000 . . . . . . . . . . . . . . . . . 75 3.18 Composition of Tertiary Education Graduates, 2007 . . . . . . . . . . . . . . . . . 76 3.19 Scientific and Technical Journal Articles, 1981–2005 . . . . . . . . . . . . . . . . . 77 3.20 Impact of Finnish Papers, 2004–08. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77 3.21 Impact of Irish Scientific Papers, 2004–08. . . . . . . . . . . . . . . . . . . . . . . . . . 78 3.22 Ranking of Universities, 2009 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79 3.23 R&D Expenditure, 1996–2007 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79 3.24 Researchers in R&D, 1984–2006 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80 3.25 U.S. Patents Granted by Country of Origin, 1970–2008. . . . . . . . . . . . . . . 81 3.26 Top 10 Technology Classes by the Number of Patents Granted to Residents of Finland in the 1980s. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81 3.27 Top 10 Technology Classes by the Number of Patents Granted to Residents of Finland between 2005 and 2009 . . . . . . . . . . . . . . . . . . . . . 82 3.28 Top 10 Technology Classes by the Number of Patents Granted to Residents of Ireland in the 1980s . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83 viii Contents 3.29 Top 10 Technology Classes by the Number of Patents Granted to Residents of Ireland between 2005 and 2009 . . . . . . . . . . . . . . . . . . . . . 83 3.30 Top 10 Technology Classes by the Number of Patents Granted to Residents of Singapore in the 1980s. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84 3.31 Top 10 Technology Classes by the Number of Patents Granted to Residents of Singapore between 2005 and 2009 . . . . . . . . . . . . . . . . . . . 84 3.32 Top 10 Assignees by the Number of Patents Granted to Residents of Finland in the 1980s. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85 3.33 Top 10 Assignees by the Number of Patents Granted to Residents of Finland between 2005 and 2009 . . . . . . . . . . . . . . . . . . . . . 86 3.34 Top 10 Assignees by the Number of Patents Granted to Residents of Ireland in the 1980s . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87 3.35 Top 10 Assignees by the Number of Patents Granted to Residents of Ireland between 2005 and 2009 . . . . . . . . . . . . . . . . . . . . . 87 3.36 Top 10 Assignees by the Number of Patents Granted to Residents of Singapore in the 1980s. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88 3.37 Top 10 Assignees by the Number of Patents Granted to Residents of Singapore between 2005 and 2009 . . . . . . . . . . . . . . . . . . . 88 3.38 Exports of ICT Goods, 1998–2006 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94 3.39 Exports of ICT Services, 1998–2007 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94 3.40 ICT Expenditure as a Share of GDP, 2003–08 . . . . . . . . . . . . . . . . . . . . . . . 95 3.41 Internet Users, 1995–2008 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 3.42 Fixed Broadband Subscribers, 2000–08 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96 3.43 International Internet Bandwidth, 1999–2007 . . . . . . . . . . . . . . . . . . . . . . 96 A.1 Ghana’s Top Five Exports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 149 A.2 Kenya’s Top Five Exports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 149 A.3 South Africa’s Top Five Exports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150 A.4 Rwanda’s Top Five Exports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150 A.5 Zambia’s Top Five Exports. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 151 A.6 Costa Rica’s Top Five Exports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 151 A.7 Jordan’s Top Five Exports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 152 A.8 Mauritius’s Top Five Exports. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 152 A.9 Morocco’s Top Five Exports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 153 A.10 Tunisia’s Top Five Exports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 153 A.11 Sri Lanka’s Top Five Exports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 154 B.1 Finland’s Top 10 Exports in 1980, by Value . . . . . . . . . . . . . . . . . . . . . . . . 155 B.2 Finland’s Top 10 Exports in 1990, by Value . . . . . . . . . . . . . . . . . . . . . . . . 156 B.3 Ireland’s Top 10 Exports in 1980, by Value . . . . . . . . . . . . . . . . . . . . . . . . 156 B.4 Ireland’s Top 10 Exports in 1990, by Value . . . . . . . . . . . . . . . . . . . . . . . . 157 B.5 Singapore’s Top 10 Exports in 1980, by Value . . . . . . . . . . . . . . . . . . . . . . 157 B.6 Singapore’s Top 10 Exports in 1990, by Value . . . . . . . . . . . . . . . . . . . . . . 158 Preface and Acknowledgments This book is an outcome of a series of study visits to Singapore for African policy makers initiated by Jee-Peng Tan in 2005 with support from Tommy Koh in Singapore and Birger Fredriksen, Yaw Ansu, and Dzingai Mutumbuka at the World Bank. The idea of writing a comparative study of three small economies germi- nated following a third visit in which the authors participated in discussions with Jee-Peng, who encouraged the authors to explore the contribution of insti- tutions and human capital to the successful performance of small economies and to draw lessons from this experience for late-starting African economies, and who championed the preparation of a study. Vital encouragement and support was also forthcoming from Obiageli Ezekwesli, Vice President of the Africa Region; Ritva Reinikka, Sector Director, Human Development, Africa Region; and Raj Nallari at the World Bank Institute. Typically the gestation period for books, even fairly slender ones, can be long, and in the eighteen months during which we intermittently worked on the manuscript, we accumulated many debts: to our reviewers—Linda English, Vikram Nehru, Ismail Ridwan, Jorma Routti, and Michel Welmond—who offered numerous penetrating comments and sugges- tions that improved both content and presentation; and to our loyal and hard- working researchers, Rory Birmingham and Lopamudra Chakraborti. Many others indirectly contributed through their backing for the study visits and the project. These include Koh Tin Fook, former Director of the Technical Coopera- tion Directorate at the Ministry of Foreign Affairs in Singapore; Lee Sing Kong, Director of the National Institute of Education; Law Song Seng, former Director and CEO of the Institute of Education; Chan Lee Mun, Principal of the Nanyang Polytechnic; and Jayakrishnan Gopalakrishnan, Director of the International Operations (Americas) Group at International Enterprise Singapore. Last but not least, we owe thanks to the governments of Norway and Singapore, which financed the project and through it, the background research, the writing, and the publication of this book. ix About the Authors Shahid Yusuf is currently Chief Economist of The Growth Dialogue at the George Washington University School of Business in Washington, DC. He holds a PhD in economics from Harvard University, and a BA in economics from Cambridge University. Prior to joining The Growth Dialogue, Dr. Yusuf was on the staff of the World Bank. During his 35-year tenure at the World Bank, Dr. Yusuf was the team leader for the World Bank–Japan project on East Asia’s Future Economy from 2000–09. He was the Director of the World Development Report 1999/2000, Entering the 21st Century. Prior to that, he was Economic Adviser to the Senior Vice President and Chief Economist (1997–98), Lead Economist for the East Africa Department (1995–97), and Lead Economist for the China and Mongolia Department (1989–93). Dr. Yusuf has written extensively on development issues, with a special focus on East Asia, and has also published widely in various academic journals. He has authored or edited 24 books, some of which have been translated into multiple languages, on industrial and urban development, innovation systems, and tertiary education. His five most recent books are Development Economics through the Decades (2009); Tiger Economies under Threat (co-authored with Kaoru Nabeshima, 2009); Two Dragonheads: Contrasting Development Paths for Beijing and Shanghai (co-authored with Kaoru Nabeshima, 2010); Changing the Industrial Geography in Asia: The Impact of China and India (co-authored with Kaoru Nabeshima, 2010); and China Urbanizes (co-edited with Tony Saich, 2008). Dr. Yusuf lives in Washing- ton, DC, and also consults with the World Bank and with other organizations. Kaoru Nabeshima is Director, Technological Innovation and Economic Growth Studies Group, Institute of Developing Economies–Japan External Trade Organi- zation (IDE-JETRO), holds a PhD in economics from University of California- Davis, and a BA in economics from Ohio Wesleyan University. Prior to joining IDE-JETRO in 2010, he was a staff member and consultant to the World Bank. During his tenure at the World Bank, which began in 2001, he was a team member for the World Bank–Japan project on East Asia’s Future Economy. His recent pub- lications include Tiger Economies under Threat (co-authored with Shahid Yusuf, 2009); Two Dragonheads: Contrasting Development Paths for Beijing and Shanghai (co-authored with Shahid Yusuf, 2010); and Changing the Industrial Geography in Asia: The Impact of China and India (co-authored with Shahid Yusuf, 2010). His research interests lie in East Asia’s economic development, especially in the inno- vation capabilities of firms. xi Abbreviations A*STAR Agency for Science, Technology, and Research (Singapore) EDB Economic Development Board (Singapore) EEC European Economic Community EU European Union FDI foreign direct investment GATT General Agreement on Tariffs and Trade GDP gross domestic product GPT general-purpose technology GSM Global System for Mobile Communications ICT information and communication technology IDA Industrial Development Agency (Ireland) I-O input-output IT information technology ITE Institute of Technical Education (Singapore) LIS learning and innovation system MNC multinational corporation OECD Organisation for Economic Co-operation and Development PAP People’s Action Party PISA Programme for International Student Assessment R&D research and development Sifire Singapore, Finland, and Ireland Sitra Finnish Innovation Fund SMEs small and medium-size enterprises STEM science, technology, engineering, and mathematics Tekes Funding Agency for Technology and Innovation (Finland) TEU 20-foot equivalent unit TFP total factor productivity TIMSS Trends in International Mathematics and Science Study USPTO U.S. Patent and Trademark Office xiii 1 Looking for Growth Economic growth is an endlessly fascinating and seemingly inexhaustible topic. Experience and research are steadily enlarging our knowledge, and one needs only to glance at papers written a couple of decades ago to appreciate the great strides in analytic sophistication and empirical verification. Starting in the 1960s—earlier if Japan is included—a number of East Asian economies began achieving growth rates well above the average and were able to maintain that pace until nearly the end of the 1990s. The first set of “flying geese”1—the Republic of Korea; Hong Kong SAR, China; Singapore; and Taiwan, China— followed in the wake of Japan, the pacesetter and exemplar. They were joined by Malaysia and Thailand in the 1970s and by Indonesia in the 1980s. The col- lective growth experience of these economies, which has been exhaustively examined and variously interpreted, serves as the compass for countries aspir- ing to a higher level of economic performance. But this deepening knowledge, impressive though it is, has yet to produce the robust and broadly applicable policy formulas that practitioners of development are seeking. Almost every country in the world is struggling to raise potential growth rates and to squeeze a few additional percentage points—or even a single additional percentage point—of growth from investment in productive assets; however, even a broadly coordinated application of tested policies cannot guarantee success, and few countries can manage a coordinated application and systematic imple- mentation of policies. They must be content with second-best approaches and policy satisficing. 1 The term flying geese was introduced by Akamatsu in the 1930s and was later presented in a paper published in English (Akamatsu 1962). 1 2 Some Small Countries Do It Better In the majority of cases, growth outcomes of late starters have fallen short of expectations.2 Developed economies averaged growth rates of 2.4 percent between 1990 and 2008, and Germany and Japan averaged rates of 1.9 and 1.5 percent, respectively. Developing economies have collectively increased their gross domestic product (GDP) by an average of 4.7 percent per year over the same period.3 A small number of emerging economies notched up growth rates of 7 percent per year for a period of 25 years or more,4 but the majority of these economies have experienced a trend deceleration since 1997 to 1998, leaving only three economies with growth rates exceeding 7 percent per year between 2000 and 2008: China (10.0 percent), India (7.1 percent), and Vietnam (7.5 percent). Countries, large and small, have struggled to imitate the industrial prowess of the East Asian pacesetters and to exploit the opportunities presented by global- ization to expand exports. But approximating the East Asian benchmarks has proven difficult, and growth accelerations have tended to be remarkably tran- sient.5 Building a portfolio of tradable goods and services and steadily raising the level of investment in these activities have generally defied the best policy efforts. (In particular, bringing investment ratios on par with East Asian averages has presented the greatest challenge.) Thus, for most countries, the East Asian model has remained a stretch. Growing at high single-digit rates, as the East Asian economies did and some still do, demands GDP investment ratios of 30 percent or more. Hence, the search is on for growth recipes not so tightly bound to investment, to manufacturing activities, and to the export of manufactured products.6 2 Growth accelerations have for the most part been short lived, with a strong tendency for countries to revert to a global mean rate of growth (see Durlauf, Johnson, and Temple 2004; Yusuf 2009). Easterly (2009, 7), relying on the findings of panel regressions of annual growth rates, observes that “only 8 percent of the variance is permanent cross-country dif- ferences, the other 92 percent is transitory deviations . . . from a world mean of 1.8 percent per capita annual increase.” 3 Per capita growth rates in the poorer countries are much lower because populations have been expanding. Once resource depletion and environmental externalities are factored in, the growth achievements to date are further diminished. 4 The elite 13—Botswana; Brazil; China; Hong Kong SAR, China; Indonesia; Japan; Korea; Malaysia; Malta; Oman; Singapore; Taiwan, China; and Thailand—were justly celebrated in the report issued by the Commission for Growth and Development (2008). 5 For more about growth accelerations, see the article by Hausmann, Pritchett, and Rodrik (2005) and the subsequent reappraisal and critique of their findings by Xu (2011) using an augmented data set. 6 Several of the fast-growing economies also benefited from an abundance of natural resources and the export of resource-intensive products. The economic successes of countries such as Botswana, Indonesia, and Malaysia, for example, are closely linked to the exploitation of energy, land, and mineral resources. Looking for Growth 3 In casting around for recipes of this type that are validated by demonstrated results, one is drawn to the experience of economies that relied less on the sheer volume of capital spending (or an abundance of natural resources) and more on other drivers of growth: human capital and knowledge. Finland and Ireland are among the tiny band of nations that grew rapidly for well over a decade by adopt- ing an approach that derived the maximum mileage from an adequate investment in physical assets and by harnessing the potential of human capital and technolo- gies. Singapore adopted a hybrid approach that embraces the high investment, export-led East Asian model, but by quickly moving to build its human and knowledge assets, the country was able to diversify much faster into higher- technology manufactures and tradable services than some of the other East Asian economies. Such diversification allowed Singapore to maintain higher growth rates over a longer period. 7 The path followed by these three countries offers a different perspective on growth. Their approach may be of greater relevance than the well-worn East Asian model in the highly competitive global environment of the early 21st century because it does not necessarily assume heroic levels of investment. Moreover, it may be better tailored to the opportunities available to a heterogeneous group of middle- and lower-middle-income economies aiming for growth rates in the 6 percent range, as well as to late-starting, low-income countries that, because of their youthful, rapidly increasing populations, need to grow at high single-digit rates to create enough jobs and to double per capita income in 10 years. Efforts to accelerate growth and sustain higher trend rates—by late starters as well as middle-income economies—must be tempered by three considerations.8 First, resource scarcities, rising energy prices, environmental pressures, and the 7 The three countries followed a course defined by the Arrow–Lucas–Romer model of endogenous growth. 8 The question posed by David Landes (1990)—“Why are we so rich and they so poor?”— remains unanswered. Neither the neoclassical growth models nor the more recent models of endogenous growth have convincingly explained the divergence between incomes and levels of development across the world or why for many poor countries backwardness has not served as a springboard to faster growth. As Robert Solow (2007, 5–6) observed, “Some of the literature gives the impression that it is after all pretty easy to increase the long-run growth rate. Just reduce a tax on capital here or eliminate an inefficient regulation there, and the reward is fabulous, a higher growth rate forever. . . . But in real life it is very hard to move the permanent growth rate; and when it happens, as perhaps in the USA in the later 1990s, the source can be a bit mysterious even after the fact.” The literature on the investment climate also creates the impression that higher growth rates can be achieved if countries can muster the political will to engage in institutional regulatory reforms so as to reduce a number of transaction costs, lower factor market impediments, and ease infrastructure bottlenecks that weigh on businesses. See for example the comparison of business climates in China and India by Li, Mengistae, and Xu (2011). 4 Some Small Countries Do It Better maturing of globalization9 are undermining policy-induced growth impulses. Second, the economies of the European Union (EU) and the United States, which served as sources of demand in the recent past, face strong headwinds that are largely of their own creation10 but are undoubtedly problematic for late-starting countries that must export to accelerate growth. Third, development economics is faced with a policy deficit.11 The advances in theory and the deepening of empiri- cal analysis have yielded only a meager crop of ideas on how countries can realize development goals, and the effective implementation of better policies is needed for countries to realize their growth ambitions.12 The East Asian model has served as the policy workhorse for decades. Supplementing it with other models is a mat- ter of urgency. This chapter starts with a brief review of the sources of growth and moves quickly to identify factors that could contribute to growth through higher pro- ductivity, thereby increasing the range of policy interventions and models that could be put to the test in developing countries. African countries figure promi- nently in this group, and they are among the ones most urgently searching for ways to accelerate growth, either by building manufacturing capacity and generat- ing demand through exports much like the East Asian Tigers or by creatively using hybrid approaches based on a range of activities, with human capital and technol- ogy serving as the principal drivers.13 As is apparent from table 1.1, Sub-Saharan economies have picked up speed14 and pulled ahead of the average growth rate for the world (but not the average for low-income countries), but their per capita GDP growth rates remain the lowest, their per capita incomes are a fraction of global per capita GDP, and their share of global product is only 1.4 percent (tables 1.2 and 1.3). 9 See Ghemawat (2011), Hufbauer and Suominen (2010), James (2009), and Rodrik (2011) for recent views on the state of globalization and its future. 10 Import demand from the EU and the United States is likely to be weaker for some time. As several EU economies and the United States struggle to rectify domestic and external resource imbalances, they could be less prolific sources of innovation, and the offshoring of industry and of tradable impersonal services may slow. Over the longer term, aging and declining populations will be a brake on growth. 11 On the policy lessons from growth economics, see Aghion and Durlauf (2009) and Yusuf (2009). On the contribution of aid to growth performance, see Doucouliagos and Paldam (2009). 12 See Pritchett, Woolcock, and Andrews (2010) on policy implementation failures. 13 Recently, some effort has gone into encapsulating the Chinese and Indian models of development. But codifying and bottling the alchemy responsible for the performance of these two economies is proving difficult, and the so-called Beijing Consensus is a box waiting for usable content. 14 See, for example, the positive assessment of recent performance and of promising trends by Radelet (2010). Looking for Growth 5 Table 1.1 Average Annual GDP Growth, 1995–2001 and 2002–08 Growth (%) Group 1995–2001 2002–08 GDP Low-income countries 4.7 5.9 Sub-Saharan Africa 3.5 5.2 World 3.0 3.1 Per capita GDP Low-income countries 2.3 3.7 Sub-Saharan Africa 0.8 2.7 World 1.6 1.8 Source: World Bank’s World Development Indicators database. Table 1.2 Average GDP Per Capita, 1995–2001 and 2002–08 Amount (current US$) Group 1995–2001 2002–08 Low-income countries 286 405 Sub-Saharan Africa 530 846 World 5,181 7,088 Source: World Bank’s World Development Indicators database. Table 1.3 Average Share of Global GDP, 1995–2001 and 2002–08 Share (%) Group 1995–2001 2002–08 Low-income countries 0.7 0.8 Sub-Saharan Africa 1.1 1.4 Source: World Bank’s World Development Indicators database. Moreover, a disproportionate share of the growth and employment15 in Africa derives from nontradable government services and those provided by hotels and restaurants and by catering, security, construction, personal, janitorial, wholesale, and retail activities (table 1.4). Such services are a source of jobs but 15 The informal sector is the source of a large number of jobs, most of which add little value but collectively account for a significant share of the “true” GDP. 6 Some Small Countries Do It Better Table 1.4 African Growth by Sector, 2002–07 Sector Compound annual growth rate (%) Hotels and restaurants 8.7 Transport and telecommunications 7.8 Construction 7.5 Utilities 7.3 Resources 7.1 Other servicesa 6.9 Wholesale and retail 6.8 Real estate and business services 5.9 Agriculture 5.5 Manufacturing 4.6 Public administration 3.9 Financial intermediation 2.4 Source: McKinsey Global Institute 2010. Note: Data were calculated in 2005 U.S. dollars. The table covers 15 countries that together account for 80 percent of Africa’s GDP: Algeria, Angola, Cameroon, the Arab Republic of Egypt, Ethiopia, Kenya, Libya, Morocco, Nigeria, Senegal, South Africa, Sudan, Tanzania, Tunisia, and Zimbabwe. a.Other services include education, health, social services, and household services. do not promise significant gain in either productivity or innovation.16 Africa’s growth potential from trade is also hampered by a product mix weighted with primary products, with the composition remaining more or less unchanged since 1995 (see tables A.1–A.5 in appendix A). Other small economies in the middle-income range have also made limited headway in diversifying their top five exports. Between 1995 and 2009, Jordan, Mauritius, and Sri Lanka marked time, while countries such as Costa Rica, Morocco, and Tunisia did somewhat better, although their diversification was into higher-tech assembly activities that had low domestic value added (see tables A.6–A.11 in appendix A). 16 Advanced countries such as the United States are in an uncomfortably similar situation, confronting sluggish job growth with the majority of jobs in nontradable services. According to Spence and Hlatshwayo (2011), 97 percent of the jobs created in the United States between 1990 and 2008 were in the nontradable sector, mainly in health care, gov- ernment services, education, and retailing. Jensen (2011) provides a breakdown of increased employment in the United States in business services from 1997 through 2007, showing that the increase was fastest in real estate and leasing and slowest in finance, information, and management. He is more positive regarding the opportunities for growth and trade to be derived from business services. Looking for Growth 7 Thus, a fresh look at the options for Sub-Saharan Africa—and other economies seeking to improve their growth prospects—in addition to the stan- dard East Asian model is badly needed in light of the current understanding of growth dynamics and changing global circumstances. Growth: The Stylized Facts The literature on growth empirics is now so rich that a brief recapitulation of the stylized facts can suffice.17 For low- and middle-income countries, capital was the principal determinant of growth, with labor and total factor productivity (TFP) trailing well behind. Since 1989, capital investment can explain 45 percent of growth, with the bulk of this investment financed from domestic savings (see table 1.5, which provides data for the world as a whole, and figure 1.1, which gives a regional breakdown). Thus, domestic investment and savings are intertwined, with savings enabling investment but not causing it. Moreover, much of the investment in economies that grew most rapidly was financed through the own resources of firms and households or from bank borrowing—in the majority of cases from institutions owned or controlled by the state.18 Table 1.5 Contribution of Capital, Labor, and TFP to World Growth Share (%) 1989–95 1995–2000 2000–06 Capital 54.1 46.4 40.7 Information and communication technologies 12.8 15.6 11.7 Other 41.3 30.8 29.0 Labor 29.6 30.4 23.6 Hours 13.5 22.0 16.1 Quality 16.0 8.4 7.6 TFP 16.3 23.2 35.7 Source: Jorgenson and Vu 2009. 17 Jones and Romer (2009, 3) provide a different set of stylized facts: (a) globalization and urbanization have enlarged the market; (b) growth has been accelerating over the cen- turies, and currently it tends to vary with respect to distances from the technology fron- tier; (c) factor inputs explain less than half the differences in per capita GDP; and (d) human capital per worker is rising, but the relative wages of skilled workers have not declined. 18 Korea and Taiwan, China, began easing government control over the banking sector in the 1980s, but the influence of the state remained pervasive through the 1990s. 8 Figure 1.1 Sources of Economic Growth by Region, 1989–95 and 1995–2003 7.5 5.5 3.5 annual contribution (%) 1.5 –0.5 –2.5 –4.5 –6.5 –8.5 1989– 1995– 1989– 1995– 1989– 1995– 1989– 1995– 1989– 1995– 1989– 1995– 1989– 1995– 1989– 1995– 95 2003 95 2003 95 2003 95 2003 95 2003 95 2003 95 2003 95 2003 world Group of 7 developing Asia non–Group of 7 Latin America Eastern Europe Sub-Saharan North Africa Africa and the Middle East hours labor quality non–IT capital IT capital TFP Source: Jorgenson 2006. Looking for Growth 9 Between 1913 and 1950, the world economy grew by an average rate of 1.82 percent per year. During the second half of the 20th century, growth accel- erated to 3.97 percent per year. This accelerated growth led to a sharp reduc- tion in poverty despite much higher rates of population growth (Maddison 2003). The portion of the population in developing countries living on US$1 a day declined from 40 percent in 1981 to 18 percent in 2004 (Ferreira and Ravallion 2008). The reduction in absolute poverty was steepest in China and India, which registered the fastest economic growth rates. But some of the growth benefits have been undercut by rising inequality. Although global inequality changed little between 1980 and the early 2000s, inequality rose in 30 of the 49 countries for which data are available covering the 1990 to 2004 period (Ferreira and Ravallion 2008; Firebaugh and Goesling 2007). Interest- ingly, thus far, changes in equality seem not to be systematically related to growth or to civic unrest and civil wars (de Dominicis, de Groot, and Florax 2006; Ferreira and Ravallion 2008; Voitchovsky 2011). Upper-middle-income and high-income countries are deriving more of their growth from gains in TFP, and the consensus view among researchers is that, over the longer run, growth is a function of TFP (see figure 1.1).19 It is helpful to keep this in perspective. Jorgenson, Ho, and Samuels (forthcoming) estimate that increasing TFP contributed just 12 percent to U.S. growth between 1960 and 2007, capital contributed 60 percent, and the balance was attributable to labor. How- ever, they acknowledge that growth over the longer term will hinge on productiv- ity enhancing innovation in a few sectors, among which computer production and use and agriculture could be prominent: “Although innovation accounts for a relatively minor portion of economic growth [over the past five decades], this portion is vital for maintaining gains in the U.S. standard of living in the long run” (Jorgenson, Ho, and Samuels, forthcoming). Total factor productivity (or multifactor productivity) has long been a catchall for gains from innovation in a variety of areas, the measurement and individual 19 Comin and Hobijin (2010) observe that differences in the levels of per capita GDP are mostly explained by varying levels of TFP. They then go on to show that rates of growth are also substantially related to the rates of TFP increase, which, in turn, depend on the speed with which countries adopt technologies and narrow gaps. According to findings reported by Hulten (2009), TFP explained one-half of the growth in the United States between 1995 and 2005, but only one-fifth of the growth in the EU—which in the aggre- gate was one-half of the growth achieved by the United States. Growth in the EU relied more on capital and on non–information and communication technology capital. How- ever, once the contribution of intangibles to growth is factored in, the share of TFP in the United States drops to 35 percent, and the role of information and communication tech- nology capital is also diminished. The contribution of TFP to growth once intangibles are included is low in both Japan and the United Kingdom. 10 Some Small Countries Do It Better contributions of which have proven difficult to pin down.20 However, these gains are the key policy targets, and the most interesting research on the sources of growth is precisely on these elusive “quarks.”21 There are many quarks, but six are most amenable to policy action: (a) human capital, variously measured,22 and its quality; (b) technological capability and entrepreneurship and their enhancement through information technology (IT);23 (c) networking; (d) managerial skills and other intangibles determining organizational effectiveness; (e) institutions affect- ing incentives, competition, allocative efficiency, and governance; and (f) the characteristics of urbanization.24 Typically, all six affect production and use of knowledge, resource allocation, and productive utilization. The final section of the chapter discusses these factors further. Growth has been spearheaded in the earlier stages of development by the industrial sector in almost all countries (UNIDO 2009), and though services are the leading source of growth and employment as economies mature,25 industry 20 Although TFP occupies center stage, its slipperiness remains an issue. Growth theorists have struggled to arrive at precise estimates and to isolate the contribution of research and development and of innovation. TFP is not only about technological change, but pre- cise decomposition runs into a thicket of conceptual and statistical problems. A quote from Jorgenson, Ho, and Samuels (forthcoming) can help thread productivity, innova- tion, and quarks together. They state, “Productivity growth is the key indicator of innova- tion. Economic growth can take place without innovation through replication of estab- lished technologies. Investment increases the availability of these technologies, while the labor force expands as population grows. With only replication and without innovation, output will increase in proportion to capital and labor inputs. By contrast, the successful introduction of new products and new or altered processes, organization structures, sys- tems, and business models generates growth of output that exceeds the growth of capital and labor inputs.” 21 The analogy with the quarks being chased by physicists for decades is arguably not farfetched. Measuring the contribution of quarks is a source of immense econometric frustration. Ciccone and Jarocinski (2009) determined that every change in growth data or change in the sample causes apparently robust results to disappear and new quarks to replace old quarks. Thus, from among the almost 150 variables tested in growth regressions, the “real quarks” are still giving researchers a run for their money. 22 Measurement of human capital remains contested territory. As Aghion and others (2009, 1) note, “the relationship between education and growth . . . is fragile at best” because tests run afoul of reverse causality, the use of crude proxies for human capital, and the neglect of intermediating variables that determine how education affects growth. 23 For more about this quark, see Brynjolfsson and Saunders (2010). Between 1995 and 2007, IT-producing and IT-using industries were the principal sources of U.S. growth. 24 By conceptualizing and estimating the magnitude of intangibles, Corrado, Hulten, and Sichel (2009) show that they raised U.S. growth by 10 percent during 1995 to 2003. 25 However, in several late-starting economies with small industrial sectors, services— because of their share in the economy—are responsible for much of the growth. Looking for Growth 11 remains the more productive and innovative of the two major sectors.26 Mean- while, the share of agriculture in GDP everywhere shrinks to relative insignifi- cance, although in Asia and Africa, most of the population is nonurban and its livelihood depends on agriculture and affiliated activities. The recent experience of India, Ireland, and some of the smaller countries in Eastern Europe points to the growth potential inherent in tradable impersonal services and of software.27 For small economies, service-led growth, backstopped by investment in computer literacy, IT, and associated skills, is a real possibility, and for large economies, such growth is a necessary complement to the impetus from other sectors.28 Some countries, including many in Africa and the Middle East, have derived much of their growth from the development and export of natural resource–based products, whether minerals or agricultural commodities. In most instances, min- eral (including energy) extraction and its beneficiation, if any, has been paced by foreign investment and has created enclave sectors that are loosely linked to the rest of the economy and generate few spillovers. Although natural resources can boost economic performance and supplement other sources of growth (as has been the case, for instance, in Malaysia and Indonesia), absent a sound, forward-looking policy environment, large mineral resources can inhibit industrialization and growth by encouraging nontradable activities and by appreciating the real exchange rate. This phenomenon, which is variously described as the “resource curse”29 or “Dutch disease,” has attracted an immense volume of research, but Lederman and Maloney (2008) have questioned whether the longer-term consequences of resource booms for growth are necessarily negative. Although the bulk of aggregate demand derives from consumption followed by investment, many economies, small and large, have supplemented these sources with demand arising from trade. The smaller open and rapidly growing economies have relied (usually for brief periods) on net exports for as much as 40 percent of their overall GDP growth, with 20 percent being closer to the norm (see figure 1.2). Imports have played an almost equally important role, because they are vehicles for 26 Innovation in services is harder to nail down and frequently is not patented. But it may be speeding up and, in the process, displacing thousands of workers doing routine work that newly developed algorithms and machine intelligence can readily undertake. See Bryn- jolfsson and McAfee (2011) and Arthur (2011) on the “Second Economy.” 27 See Ghani (2010) on how services are revolutionizing India’s trade prospects. The prospects of growing services exports (particularly those of the United States) are examined in detail by Jensen (2011). 28 See McKinsey Global Institute (2010) on the contribution of services to growth and employment in developed and middle-income economies. 29 Researchers refer to a mineral resource and energy resource curse and a political resource curse. See Humphreys, Sachs, and Stiglitz (2007) on how countries have avoided the resource curse or minimized its impact. See also Frankel (2010) for a review of resource- based development. 12 Some Small Countries Do It Better Figure 1.2 Percentage Point Contribution of Real Net Exports to GDP Growth in Asia, 1995–2000 and 2000–06 6.0 5.5 5.0 4.5 4.0 percentage points 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0 –0.5 China Hong Kong India Indonesia Japan Korea, Rep. Malaysia Philippines Singapore Taiwan, Thailand SAR, China China 1995–2000 2000–06 Source: Haltmaier and others 2007, 54. Note: China and India data are only through 2005. technology transfer and contribute to technological catch-up (Ding and Knight 2008; Lawrence and Weinstein 2001). Thus, tradable goods and services—mainly manufactures and resource-based products—have underpinned the rapid growth of economies that were able to create a production base of sufficient size through domestic investment, financed in large part from national savings. Foreign direct investment (FDI) in production facilities, infrastructure, and research and development has supplemented domestic investment as well as tech- nology transfer through trade and indigenous efforts at building innovation capac- ity. The contribution of FDI has rarely exceeded 5 percent of GDP, although in a number of the most successful economies, foreign investment was significantly higher,30 and it catalyzed industrialization, helped to promote exports, contributed to an upgrading of the product mix, and is leading to a global distribution of the value chain (see Smeets 2008). For the past three decades, growth has been powerfully aided by the integration of the global economy. In particular, trade liberalization31 and measures that have eased 30 Vietnam is one such example. See Nguyen (2006). 31 Tariffs on manufactured goods fell from an average of 40 percent when the General Agreement on Tariffs and Trade was signed in 1947 to 5 percent in 2000. A compelling definition of globalization by Flynn and Giráldez (2004, 83) is the establishment of permanent trade relations among all segments of the world economy, thereby leading to “an exchange of products continuously and on a scale that generates deep and lasting impacts on all trading partners.” Looking for Growth 13 the flow of capital,32 the circulation of skills,33 and the sharing of information have stimulated economic performance directly and through a variety of externalities. Last but not least, the golden age of growth (since 1950) is indebted to the incentives, innovations, and productivity gains arising from a number of general- purpose technologies (GPTs).34 Two GPTs that have been at the forefront are the semiconductors and IT and of computers and the Internet. These GPTs are the sig- nature technologies of recent times, and each has spawned a host of productivity- enhancing innovations affecting a wide range of activities (Jovanovic and Rousseau 2005).35 As Martin Kenney (1997, 95) observes, “Electronics is being dri- ven not by discrete innovations but rather by incessant waves of branching innova- tions that are generating a constantly proliferating range of products. Through this process new industry sectors are being created, separated, and merged. The increased processing power and functionality of new products in turn permit new tasks to be undertaken by machines. These new capabilities rapidly become needs. For example, whereas an Internet link was formerly a luxury for engineers, scien- tists, and a few computer buffs, it is rapidly becoming a necessity.”36 32 Mishkin (2005) maintains that financial globalization positively influences development but can also trigger crises such as the one that pummeled the global economy from 2008 to 2009. Following that crisis, many researchers view the contribution of financial inno- vations and of financial integration in a different light, given the inadequacy of regulatory mechanisms in most countries and the immense political clout wielded by large financial entities. See Lerner and Tufano (2011). 33 Skill circulation occurs through brain drain, brain gain, and brain circulation. 34 A survey of the literature on GPTs and of past GPTs can be found in Lipsey, Carlaw, and Bekar (2005). Most GPTs play the role of “enabling technologies opening up new opportunities rather than offering complete final solutions. For example, electric motors fostered the more efficient design of factories [and] users of microelectronics benefit from the surging power of silicon by wrapping around integrated circuits, their own technical advances” (Bresnahan and Trajtenberg 1995, 84). The infiltration of small, low- cost microprocessors, such as Intel’s Atom, into treadmills, billboards, coffee machines, and gas dispensers shows how the evolution and diffusion of this protean technology is continuing, driven by cost and other innovations (King 2010). 35 The productivity of these GPTs (as was the case earlier with electrical technology) is magnified, and the number of crossover innovations is enhanced, by the increase in knowledge capital and by an open and competitive environment that is furnished with intellectual property institutions and is conducive to innovation (Lo and Sutthiphisal 2010). 36 In fields such as genetics, biology, climatology, and the social sciences, research is being rendered more productive through innovative uses of computing power to automate the framing and testing of multiple hypotheses with the help of advances in data processing; evaluative algorithms (earlier artificial intelligence programs included Prospector, Bacon, and Fahrenheit); and robotic systems. The latest programs for biological experiments “step through activities needed to conduct a continuously looping procedure that starts with question, carries out experiments to answer the question, evaluates the results, and reformulates new questions” (Waltz and Buchanan 2009, 43; see also Glymour 2004). 14 Some Small Countries Do It Better Hunting for Quarks The factors described in the previous section constitute the determinants of growth from the side of supply and the side of demand. From the perspective of longer-term growth and its sustainability, capital, labor, and the factors influenc- ing TFP are more relevant for policy-making purposes. Here the discourse on growth becomes intertwined with that of development, and one can see the growth pathway becoming one with the development pathway. Inside the TFP Black Box Increasing capital investment in productive activities and maximizing the return from this investment must necessarily be the focus of growth-enhancing policies. The evidence from theory and from East Asian experience suggests that accelerat- ing growth and maintaining a higher tempo depends on an upward shift in the rate of capital accumulation. All of the fast-growing Asian economies relied on higher rates of investment than the average rate for developing countries. Japan led the way, followed by Korea and the first cohort of “tiger economies.” Approxi- mately a decade and a half later, the second cohort of Southeast Asian tigers imi- tated the first. Investment propensities were buttressed by governments that were committed to economic development and were able to back up words with poli- cies that resulted in macroeconomic and political stability and that reduced busi- ness risks.37 Development of the banking sector and improved access to term and trade financing through public and private channels, a widening of the domestic market (and a larger middle class), and expanding opportunities to sell overseas attracted investors, while the strengthening of market institutions reduced entry barriers and stimulated competition.38 By current standards and criteria, the investment climate in the tiger economies was a great deal worse than is the average climate in developing coun- tries today, but this problem did not prevent investment from surging forward.39 Similarly, the business climate was distinctly unpropitious in India when invest- ment began rising after 2000 and in Vietnam following the initiation of (Doi Moi) 37 As Acemog ˘lu (2009, 1) bluntly put it, “Nations are not like children—they are not born rich or poor. Their governments make them that way.” 38 OECD (2006) provides a detailed survey of entry barriers, including a discussion of both structural barriers (resulting from industry conditions linked to scale economies and network effects, for example) and strategic barriers (created by the actions of market participants through exclusive dealings, for example). 39 East Asian developmental states were able to mobilize savings for investment purposes using publicly owned banks (as in China, Korea, and Taiwan, China); public pension funds requiring mandatory contributions (as in Malaysia and Singapore); postal savings systems (as in Japan); and state-controlled insurance schemes and budget-financed national investment funds (as in Korea). Looking for Growth 15 reforms in 1986. The initial policy lesson to be drawn from East Asian experience is that governments committed to development, able to provide leadership, and equipped with the instruments to ensure stability can, with some help from FDI and trading opportunities, initiate long-lasting virtuous growth spirals. In fact, Asian successes in the 1970s through the first half of the 1990s had little to do with the sophistication of policy tools, with logistics and supply-chain management, or with technological innovation.40 Apart from macropolicies to contain inflation, governments relied on tax exemptions, directed credit, and exchange rate incen- tives to encourage investors. They then deployed other longer-range measures to sustain performance. The really interesting lessons from the history of rapidly growing economies are not so much about macropolicies or the factors responsi- ble for the state of the business climate; rather, they are about the measures that triggered a rapid improvement in the business climate and motivated investment behavior over an extended period of time, that contributed to technological catch-up and some incremental process innovation,41 that spurred incremental innovation in a number of interlinked areas, and that enabled structural changes—including, most notably, a rapid and orderly transfer of labor from the primary sector to expanding urban centers. Together these measures reinforced the growth from capital investment by helping to raise factor productivity. Successful developers have emphasized to varying degrees five objectives (the elusive quarks) in their pursuit of growth, all of which relate back to the drivers of TFP identified previously: • Forging a consensus around an outward-oriented growth strategy • Crafting the institutional infrastructure for a competitive economy in coordi- nation with labor, the business community, and other stakeholders while strengthening the administrative capabilities of the state to frame and imple- ment policies42 • Creating an open, networked “learning economy”43 so as to build human capi- tal of the requisite quality, make it easier to absorb ideas and technologies, increase the horizontal diversity of research lines and the establishment of new lines of inquiry, enhance production capabilities through a freer circulation of tacit knowledge, and increase the fruitfulness of domestic innovation (Murray and others 2009) 40 However, declining transportation costs stimulated trade worldwide. 41 According to Parente and Prescott (2000), impediments to technology adoptions are among the principal causes of lagging performance. 42 Jagdish Bhagwati (2010) associates policy making with three i’s: ideas, institutions, and interests or interest groups. 43 Several different facets of the learning economy viewed in the context of globalization are discussed in Archibugi and Lundvall (2001). 16 Some Small Countries Do It Better • Stimulating entrepreneurship44 and organizational efficiency • Internalizing entrepreneurship and organizational efficiency within an expand- ing urban system that is conducive to spillovers and maximizes agglomeration economies Long-Term Strategy and Coordination A modern market economy is an exceedingly complex organism, and for it to deliver above-normal growth and productivity outcomes over a period spanning decades, the state and other significant stakeholders must envision longer-term strategies and attempt to mesh these strategies so that the state can arrive at and effectively implement sound policies. When investment—whether physical or human—and technology are the central elements of strategies, the government needs to be active in coordinating the workings of at least four other bodies: (a) key segments of the business community suitably represented by chambers of industry, business associations, and developers with substantial voice and author- ity; (b) labor unions or other influential representatives able to communicate the concerns of workers and exercise a degree of discipline over their constituency; (c) the financial community in countries where banks and other major financial enti- ties are privately owned or controlled by foreign shareholders; and (d) the educa- tion sector (or, more broadly, the learning economy, which includes preschooling and vocational training), because that sector is responsible for the skills that industry needs if it is to produce, absorb technologies, and conduct research and is a source of ideas to underpin technological advances. Several of the smaller economies—Finland, Ireland, and Singapore among them—have devised consultative arrangements with these other entities to facili- tate coordination, to enable the government to achieve a workable consensus on economic objectives and strategies, and to agree on emergency remedial policies when the nation faces crisis. Almost every country has devised various consulta- tive arrangements with major stakeholders, but few of these arrangements deliver results. In many cases, governments lack the capability to strategize and imple- ment policies. Framing strategies and coordinating plans might also not be a pri- ority for the business sector; sometimes relations can turn adversarial and hostile, and communication breaks down. Not infrequently, elected officials and govern- ment agencies are captured by powerful, rent-seeking elements from the business and financial communities.45 Effective coordination in the interests of long-term growth is something of an art. Peter Evans (1995) believes that it is a function of the “embeddedness” of key government agencies in the business environment, 44 Schoar (2009) differentiates between transformational and subsistence entrepreneurship, with the former being the kind countries want to increase. 45 Regulatory capture is almost the rule rather than the exception in developed economies as well as developing ones. Looking for Growth 17 combined with autonomy to formulate strategy, provide leadership, and build alliances. There are other formulas as well, but needless to say, the coordination of activities and the conduct of policy so as to realize developmental objectives are critical to achieving an above-average economic performance.46 Governments that lack the political will, the organizational capability, and the expertise to coor- dinate and implement risk being caught in what Pritchett, Woolcock, and Andrews (2010) label “state capability traps.” Learning Economy The learning economy has several parts, starting with the schooling (including preschooling47) system and including the vocational training, tertiary education, and research conducted in universities and public institutes, as well as by domestic and foreign businesses; lifelong learning; and the harnessing of digital intelligence and artificial intelligence with the help of a state-of-the-art IT network. Supple- menting these facets is the scientific acculturation imparted by science centers, museums, science exhibitions, and public lectures. Countries initially focus on pri- mary and secondary schooling before devoting attention to the vocational and higher tiers of the education system. What differentiates high-achieving countries from others is the subsequent stress on the quality of schooling at all levels; the resources devoted to increasing access to tertiary education, to developing research universities, and to enhancing research capacity in the economy at large; and the importance such countries attach to bolstering learning and innovation by invest- ing lavishly in IT capacity and encouraging its deep assimilation.48 Many countries (China being an outstanding example) are hard at work fashioning a learning economy49 and inducing links between entities conducting research and training on the one hand and firms on the other. From among them, the front-runners in Europe are Finland and Ireland, whereas in East Asia, Korea and Singapore have pulled ahead of the rest. Each of these countries is anchoring sustainable growth to its own version of a learning economy.50 46 Rodrik (2005) has repeatedly emphasized this point. 47 A child’s initial skill set is correlated with family attributes such as the education of parents and maternal nurturing. These attributes are largely beyond the reach of policy (Cunha and others 2006). 48 By training more engineers, Finland increased patenting activity, according to research by Toivanen and Väänänen (2011). 49 The outstanding and top-ranked scores of 15-year-olds from Shanghai on the 2009 Programme for International Student Assessment tests demonstrate how much can be achieved in a short span of time through determined effort. 50 A study of crossover innovations following the introduction and spread of electricity points to the importance of human capital and of the learning environment in stimulating invention (Lo and Sutthiphisal 2010). 18 Some Small Countries Do It Better Entrepreneurship and Management Investment activity and the translation of ideas into commercially successful technologies is the work of entrepreneurs and managers. Entrepreneurs, whether in the private sector or in the public sector, have a key role in deter- mining how much capital accumulation takes place and its sectorwide distrib- ution. Both of these factors affect growth. Entrepreneurs also bring ideas and technologies into the marketplace and test their commercial worth. If entrepre- neurship is weak, technological change and innovation also slow, irrespective of the stock of technologies waiting to be exploited and also of the productivity of domestic research activities.51 Dynamic economies are necessarily highly entre- preneurial ones with a culture that strongly rewards initiative and risk taking and is relatively tolerant of failure.52 The challenges for late-starting economies are how to inculcate a more vibrant entrepreneurial culture in the private and public domains53 through wider participation, especially of the highly educated elites and members of the diaspora, and how to partially erase the stigma associated with the failure of businesses. Failure is a powerfully inhibiting factor in many countries, because four out of five start-up activities do fail within a couple of years. Thus, giving the unbowed entrepreneurs additional chances (including access to credit) is vital if business activity is to flourish in good times and revive quickly after bad times. Entrepreneurship needs to be complemented by deep managerial skills if it is to sustain business performance beyond the start-up phase and grow companies, to fully exploit the potential of mainstream as well as frontier technologies, and to wring the maximum productivity from factor inputs.54 Research has consistently underscored the wide differences in productivity and profitability among firms within the same industry in a single country, where all have access to a common technology set. The bulk of these differences are ascribed to the quality of man- agement, which is determined by training, experience, and the incentive environ- ment within a firm, the industry, and the market at large. Clearly training matters, but the other two factors are no less significant. The desirable mix will differ among countries, and achieving it is a complex endeavor that depends partly on policy and institutions and partly also on the competitive forces at work in the business community. 51 Japan now confronts this problem as it struggles to break away from two decades of slow growth. 52 Tolerance of failure does not imply that ineptitude is not penalized. 53 The scale and diverse activities of the public sector in most countries makes it essential to infuse dynamism into public bodies. 54 Entrepreneurs who start up firms rarely prove to be good managers who can help firms to grow. Looking for Growth 19 Competition and Openness The next issue is market conditions influencing openness and competition. Although the advantages of competition have long been recognized, and openness—especially to trade—is accepted as a means of stimulating competi- tion, technology transfer, technological spillovers, productivity gains, and faster growth, policy makers must struggle against vested interests and newly emerg- ing demands for protection if they are to dismantle existing barriers to trade and curb the emergence of new barriers. It is the same with domestic competi- tion. Theory is relatively explicit in its support for untrammeled competition, but practice is fraught with complications. Certain natural monopolies need to be regulated, and regulation of many other industries (to protect consumers) has a bearing on the degree of competition. Laws governing competition and their interpretation and implementation by the courts also determine the deci- sions and behavior of firms. It appears that small economies that are highly dependent on trade are more likely to favor competitive policies and institu- tions, often because they have little choice. But even in small economies, public ownership; procurement practices; local regulations and standards; labor mar- ket rules affecting the entry, growth, and exit of firms; and financial market con- straints can selectively dampen competition, the turnover of firms, and the emergence of “global champions.” The test for policy makers seeking to maxi- mize productivity and technological gains is to strive after the goal of a compet- itive market economy but to be mindful of the need to accommodate industrial adjustment as well as the orderly exit of firms, both large and small; the transi- tory concerns of infant industries; the desirability of nurturing new technolo- gies; and the avoidance of finance- and regulation-induced asset bubbles, which are a prelude to crises. The Networked Economy The literature on development is giving greater attention to networking,55 with the focus increasingly on the urban sector, where agglomeration stimulates pro- ductive and innovative activities through local and global networking. With urban populations growing, urban GDP accounting for between 60 and 80 percent of GDP, and the Internet having created a host of globe-spanning communities, networking is a force to be reckoned with.56 Cities are as old as civilization, but as densely networked drivers of growth, cities have arrived fairly recently on the 55 Castells and Himanen (2002) discuss the Finnish model of a networked, information- based welfare state and compare it with Singapore and Silicon Valley to show how they emerged from different starting points. 56 Manuel Castells (2000) was among the earliest to draw attention to the emergence of the globe-spanning, information-driven network society. 20 Some Small Countries Do It Better policy landscape. It was long apparent that industry concentrated in urban centers and that there was a correlation between urbanization and develop- ment;57 however, during the past 20 years, research has accumulated showing that industrial composition and the size of cities can raise productivity through agglomeration, urbanization, and scale economies reinforced by knowledge diffusion through networking.58 The productivity of cities is thus a complex outcome of several factors, with livability, cultural and recreational amenities, and openness seen as contributing to learning, local innovation, and start-up activities.59 These findings require that policies related to growth, productivity, and innovation factor in the contributory role of the urban environment. Growth, learning, and innovation strategies must now be jointly cast within an urban framework, and the success of policies to raise growth and to pro- mote technological change is interlinked with the characteristics, quality, and 57 Polèse (2005, 1430) noted that many studies have “repeatedly demonstrated the dispro- portionate contribution of urban areas to national income and product.” For example, “greater São Paulo accounted for 8.6 percent of Brazil’s population but generated 36.1 percent of national GDP. For all nations, the contribution of urban areas to GDP or income is greater than their share of the national population.” UN (2008) describes how the wealth of nations is concentrated in metropolitan cities, with cities such as Seoul, Bangkok, São Paulo, and Karachi accounting for a disproportionate share. See also Henderson (2010). 58 The largest cities are the most influential in creating spillovers in information and technology. These knowledge spillovers in larger urban areas also increase the rate of firm creation in emerging industries (Polèse 2005). Carlino, Chatterjee, and Hunt (2007) find that patenting rises with increasing employment intensity in cities. And Cortright and Mayer (2001) observe not only that patenting and venture funding are concentrated in a few metropolitan areas in the United States but also that most patents are issued to a handful of firms. This finding is confirmed by Acs, Anselin, and Varga (2001), who observe a clustering of patents in 10 states and in a few counties within those states. Not surprisingly, the leading metro areas in the United States are also the principal sources of the nation’s manufactured exports, accounting for 62 percent of total exports (Istrate, Rothwell, and Katz 2010). A networking of things via information and communication technology could take productivity to an even higher plane, for example, through smart roadways and electronic communications among vehicles and between vehicles and sources of information that would affect the decisions of drivers. 59 Ten large metro regions in the United States are responsible for a third of all patents, and the research on agglomeration economies has pointed to the productivity gains that can accrue to large cities from scale, diversity, and density of activities and from the apparent superlinearity (albeit modest) of innovations in relation to the size of the city (Carlino, Chatterjee, and Hunt 2007; Carlino and Hunt 2009). Looking for Growth 21 ease of networking.60 If cities do not actively enable economic change, growth will falter. This observation represents a new departure in thinking that is slowly being internalized: the pathway to growth runs through indus- trial and networked cities. Looking at the “Sifire” Family of Models The five drivers of TFP—and of growth more broadly—direct our attention to the experience of countries widely considered as being in a class of their own by hav- ing compressed development into a remarkably short period of time, mainly by massively upgrading human resources and harnessing knowledge capital to the fullest extent.61 Capital was no less important for these countries, but the speed of technological catch-up, which was made possible by investment in the learning economy and in institutional and organizational capabilities and technology, sig- nificantly increased the return from capital. The three economies that are the dramatis personae of this study are Singapore, Finland, and Ireland, referred to collectively as the Sifire group, or Sifire for short. Why select these countries and not others? There are several reasons. Between 1985 and 2005, the three Sifire countries demonstrated a remarkable capacity to learn and, by improving the quality of learning, to achieve technological catch-up, develop manufacturing capabilities of the first rank, and increase their ability to innovate. Demographically, they are of comparable size. Ireland, the smallest, had a population of 4.4 million in 2008, as compared with 5.3 million for Finland, the largest of the three countries (table 1.6).62 In 1985, Sifire could be classified as middle income, with per capita GDPs ranging from US$6,000 to US$11,000. By 60 The “creative classes” will gather in selected urban centers, and the historical function of cities is to act as gathering places for the best and the brightest (Florida 2002). Hidalgo (2010a) describes how a network contributes to the diffusion of development through the product space. He notes that the value is in the network connecting different parts rather than in the individual factors and components. “Firms and institutions are not only large collections of individuals. They are networks of individuals that interact through hierar- chies, but mostly despite them. The ability of a firm to be productive depends not only on the talents of its employees, but largely on the way they interact” (Hidalgo 2010b, 2). In the same way, the effectiveness of urban networks can be a determinant of the productiv- ity and innovativeness of the city. 61 See Ashton and others (2002) on how the East Asian tiger economies managed this achievement. 62 Small countries have proliferated since the middle of the 20th century, and of the 193 independent countries that exist today, 87 have populations of less than 5 million. Hence, the Sifire group is representative of a large number of economies, extending from the very poor to the richest (that is, Luxembourg, which had a population of just 400,000 in 2009 and a per capita GDP of US$80,000). 22 Some Small Countries Do It Better Table 1.6 Population of the Sifire Group, 1985 and 2008 Population Country 1985 2008 Finland 4,902,000 5,313,399 Ireland 3,540,000 4,425,675 Singapore 2,736,000 4,839,400 Source: World Bank’s World Development Indicators database. 2008, they were among the countries with the highest incomes as a result of steady and relatively high rates of growth in per capita incomes (table 1.7).63 Singapore’s economy grew the fastest on average, followed by Ireland’s, with Finland’s econ- omy in third place (table 1.8).64 The growth performance of Sifire was closely linked to competitiveness, derived in large part from institutional factors and the quality of the countries’ human resources. Of the three countries, Singapore has been in the lead since 1989 according to all criteria, followed by Finland and Ireland. Table 1.9 provides rankings for 1989 and 1992, and table 1.10 presents the rankings for 2003. Aside from competitiveness in general, the countries had high scores for government and business efficiency, both of which have underpinned economic performance. Sifire countries share structural characteristics, and their economic perfor- mance, which is significantly buoyed by the opportunities presented by regional and global markets, places them in the ranks of the world’s most successful economies. These similarities are convenient for the purposes of analysis and the teasing out of lessons for potential fast followers.65 The political and economic diversity of the Sifire group adds richness to the lessons. Singapore, a city-state, 63 Here is how Ireland’s leading historian Robert Fitzroy Foster (2008, 7) describes the decade extending from 1995 to 2005: “Output . . . increased by 350 percent, . . . personal disposable income doubled, exports increased fivefold, trade surpluses accumulated into billions, employment boomed, immigrants poured into the country. . . . The country had apparently become vastly rich.” 64 A decomposition of growth rates by Crafts (2008) indicates that between 1990 and 2003 TFP rose fastest in Ireland (2.24 percent per year); Finland was next, with TFP growing 1.49 percent; and Singapore, whose TFP increased by 0.9 percent, followed. Ireland’s economy more than tripled in nominal terms between 1990 and 2003, and exports grew by 4.5 times. (Harris 2005). 65 Fast followers is a term used to describe firms in Taiwan, China, which have shown themselves unusually quick to absorb and advance technologies. See Kraemer and others (1996) and Mathews (2005). Looking for Growth 23 Table 1.7 GDP Per Capita of the Sifire Group, 1985 and 2008 Amount (US$) Country 1985 2008 Finland 11,253 51,323 Ireland 5,826 60,460 Singapore 6,485 37,597 Source: World Bank’s World Development Indicators database. Table 1.8 Average Annual GDP Growth of the Sifire Group, 1985–2008 Growth (%) Country 1985–89 1995–99 2000–04 2005–08 Finland 4.0 4.6 2.9 3.2 Ireland 3.7 9.5 6.2 4.3 Singapore 6.4 6.0 5.0 5.9 Source: World Bank’s World Development Indicators database. Table 1.9 IMD World Competitiveness Rankings of the Sifire Group, 1989 and 1992 Country Dynamism of the economy Human resources Overall ranking 1989 Finland 5 7 6 Ireland 10 17 16 Singapore 1 1 1 1992 Finland 11 9 10 Ireland 4 10 9 Singapore 1 1 1 Source: IMD 2010. Note: In 1989, country rankings were calculated for two separate groups: (a) 23 member countries of the Organisa- tion for Economic Co-operation and Development (including Finland and Ireland) and (b) 10 newly industrialized countries (including Singapore). In 1992, the same division of groups applied, except that Pakistan, South Africa, and the República Bolivariana de Venezuela were added to the second group. uniquely highlights the extraordinary possibilities for well-managed and diversi- fied industrial cities that creatively exploit the benefits of connectivity. Finland demonstrates the workings of an advanced democratic system that has perfected the political and labor market institutions for consensus build- ing around key economic objectives and the capacity to arrive at significant 24 Some Small Countries Do It Better Table 1.10 World Economic Forum and IMD Competitiveness Rankings of the Sifire Group, 2003 World Economic Forum IMD world IMD business IMD government growth competitiveness competitiveness efficiency efficiency Country index (2001–02) ranking (2003) ranking (2003) ranking (2003) Finland 1 3 2 1 Ireland 11 11 6 13 Singapore 4 4 5 3 Sources: IMD 2010; WEF 2010. Note: The World Economic Forum ranked 75 countries; IMD ranked 51 countries. macroeconomic results by coordinating the initiatives of a number of small urban centers. 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An abundance of sparsely populated arable land is responsible for New Zealand’s prosperity, which is based on the export of fruit, meat, and dairy products.2 However, there are rel- atively few instances of small, resource-poor economies entering the ranks of high-income countries within two to three decades through the export of manufactures or services. Singapore, Finland, and Ireland (Sifire) are among the select group that beat the odds. Although each country’s past is necessarily unique, there are enough overlapping strands and shared circumstances to construct a composite story highlighting the causal factors that affected all three economies to varying degrees—a story, moreover, that is of continuing relevance for low- and middle-income developing countries in the early decades of the 21st century. 1 Botswana is one of two African countries belonging to the exclusive club of fast-growing economies, the other being Mauritius. See Beaulier (2003). 2 New Zealand’s largest firm is Fonterra, a dairy cooperative. Fonterra accounts for almost a third of global exports of dairy products. 31 32 Some Small Countries Do It Better Globalization: The Vital Backdrop The 1980s are an appropriate starting point. That was when a second wave of global- ization3 was deriving momentum from trade liberalization, the loosening of capital controls, and the diffusion of innovations sparked by powerful new general-purpose technologies and, arguably, the Pax Americana.4 The increase in cross-border trade, principally of manufactures and raw materials, stemmed from the confluence of several factors, among which four deserve special attention. First, starting with the General Agreement on Tariffs and Trade (GATT), a series of international trade negotiations—with the Geneva Round in 1947 being the first5—were whittling away at the tariff and nontariff barriers to trade, and in the process, they widened the opportunities for export-oriented firms in the lower- middle-income and middle-income countries, which had begun building a compet- itive manufacturing base. Between 1980 and 1990, global trade rose by 5.0 percent per year. This figure accelerated to 6.1 percent from 1990 through 1995, and the completion of the Uruguay Round in 1993 further promoted liberalization.6 Second, a steady decline in the costs of surface transportation reinforced the effects of lower tariff barriers. This reduction in costs arose from technological advances such as containerization, ship design, and diesel engine technology and from advances in the handling of cargo at ports.7 It was further aided by stable or 3 An earlier wave crested at the beginning of the 20th century and was gradually reversed by the wars and depression that scarred the first five decades of that century. 4 A number of the key global institutions such as the World Bank, the International Monetary Fund, the General Agreement on Tariffs and Trade, and the World Trade Organization were created by the United States through the exercise of its political power, and these institutions reflected the American vision of the world economy. 5 Twenty-three countries met in Geneva to finalize the GATT in October 1947. Its initial benefits were enlarged through a series of eight trade rounds, culminating in Uruguay in 1993 with the creation of the World Trade Organization. The Doha Round, which started in 2001, is not yet concluded. 6 According to Bordo and Rousseau (2011), trade liberalization was reinforced by the formation of the European Common Market and the gradual dismantling of capital controls after 1972. 7 The modern shipping container (the workhorse 20-foot equivalent unit, or TEU) is the brainchild of Malcolm McLean, a trucker from North Carolina, who saw the container as a way of simplifying and speeding up the loading and unloading of cargo. Because of the TEU and associated innovations, the cost of shipping has fallen 10-fold since the late 1980s, and thanks to computers, shipping freight across the world has become a seamless, intricately choreographed activity, with loading, customs clearance, unloading, stacking, and placing containers on tractor trailers or railcars all precisely managed by computer systems (Levinson 2006). Huge container ships powered by mammoth diesels are the workhorses that haul the 20- and 40-foot containers across the oceans. And were it not for the advances in transport technologies and computerization, East Asia would have struggled to become the workshop of the world, and international trade would have never scaled these dizzying heights (Smil 2010). How Sifire Compressed Development 33 declining prices for fossil fuels. The costs of air shipment declined 2.52 percent annually from 1980 to 1993 with the entry into service of larger, more fuel- efficient freight carriers, such as the DC-10, the MD-11, and the Boeing 747, and with advances in logistics. Third, the growth of trade was boosted by the offshoring of manufacturing from the European countries, Japan, and the United States to industrializing economies, where wages, rents, and other costs were lower. Major retailers in the United States took the lead,8 followed by manufacturers, lured by the profits to be earned from shifting production overseas. An international production system began to take shape, initially under the tutelage of multinational corporations (MNCs), but increasingly, this system was complemented by the rise of Asian con- tract manufacturers, such as Flextronics and Hon Hai, and integrators, among which Li & Fung is the most prominent. Fourth, the initial round of production offshoring and outsourcing to suppliers in emerging economies was followed by a far-reaching elaboration, specialization, and geographic dispersion of production, made possible by growing expertise in manag- ing complex manufacturing and product integration processes, the profits to be earned by extending the value chains, and the greater ease of doing so with the help of newly devised information technologies. Induced by the trade rounds referred to ear- lier, a series of technological, institutional, networking, and process-related advances that stimulated trade ushered in a new era of globalization that was arguably more inclusive and prosperous than the globalization of the early 20th century. There were four additional facets to the globalizing trend starting in the 1980s. One, already alluded to, was financial globalization, which arose from the loosen- ing of capital controls, as well as from financial innovations and institutional developments that increased the salience of the banking and finance sector in the advanced countries and encouraged their banks and finance houses to join manu- facturing firms in seeking opportunities overseas. Finance, like water once it begins to flow and spread, is difficult to keep out, and spread it did, as the indus- try acquired a voice (particularly in the United Kingdom and United States), mobilized political support, and began making the case that rapid development was predicated on easier access to an elastic supply of international capital and to financial instruments that differed according to the varying needs of savers and investors.9 The integration of financial markets, which triggered the flow of 8 Major retailers in the United States are among the largest importers, and as the retail sec- tor has become more concentrated since the mid 1990s, imports from industrializing countries such as China and Mexico have soared (Basker and Van 2010). 9 The contribution of financial development to growth is supported by empirical research reviewed by Demirgüç-Kunt and Levine (2008) and Levine (2005). Aghion, Fally, and Scarpetta (2007) underscore the role of finance in supporting the entry and growth of firms, and Philippon and Véron (2008) show that access to financing can significantly influence the appearance and the fortunes of high-tech manufacturing and services providers. 34 Some Small Countries Do It Better portfolio finance, coincided with the growth of foreign direct investment (FDI) from US$56 billion in 1985 to US$343 billion in 1995 and US$955 billion in 2005 (United Nations Global Compact 2006). A second facet was the deepening of manufacturing capabilities in a number of developing countries. Once concentrated in a few advanced economies, modern manufacturing activities began striking roots in many more economies helped by the multiplication and deepening of trade channels, the nuclei for industrializa- tion created by FDI, and the spread of international value chains. The third facet of globalization of relevance to the Sifire story is the coalescence of trading blocs, which began generating their own virtuous spirals through greater interdependency and intraregional and intraindustry trade. By helping meld most of the European economies into a single market with its own currency and increasingly uniform standards and regulations, the European Union (EU) magnified the benefits inherent in integration for the participating countries (Barysch 2004). In addition to the gains to be realized from globalization, the European economies enlarged the continentwide benefits by creating a market of more than half a billion consumers. Other regional and bilateral trading arrange- ments also proliferated after the 1980s,10 notably in East Asia, and although their incremental contribution to the ongoing multilateral changes is debated, on bal- ance they did not undermine globalization. They may very well have helped open a few doors and thickened the incentives for firms engaging in cross-border activ- ities or considering such activities. Globalization’s fourth significant facet is the diffusion of general-purpose tech- nologies (GPTs).11 The role of technology differentiates this second round of global integration from the first. GPTs such as electricity and the internal combus- tion engine began spurring innovations in the late 19th and early 20th centuries, but it would be fair to say that their significant effects were felt in the decades fol- lowing World War I.12 Lower transport costs, made possible by steam-driven ships certainly shaved transport costs,13 but GPTs were not the force behind the first 10 As of May 15, 2011, the World Trade Organization had received notification of 489 regional trade agreements. See http://www.wto.org/english/tratop_e/region_e/region_e.htm. 11 GPTs are distinguished by their potential for evolution, applicability across a wide range of uses in numerous products and processes, and complementarities with existing or emerging technologies. See Brynjolfsson and Saunders (2010, 95). 12 Electricity, the internal combustion engine, communication technologies, and new materials that shaped the 20th century first made an appearance in the latter part of the 19th century, but the full harnessing and growth these innovations generated filtered through several decades, extending well into the 20th century (Hummels 2007; Smil 2005). 13 James (2009) links the era of globalization extending from the 1880s until the eve of World War I to the momentum imparted by the iron and steel industry and the revolution in transport resulting from steam-based power and iron-hulled ships with screw propellers (see Temin 1999). How Sifire Compressed Development 35 globalization. The second globalization has undoubtedly benefited from the spate of technological advances unleashed by the semiconductor and the Internet, in addition to the continuing innovations arising from earlier GPTs, which are by no means a spent force. Computers, other electronic and telecommunication devices, and digital technologies have penetrated virtually every corner of the economy, and the presence of the Internet is pervasive. These GPTs are responsible for twin revolutions in manufacturing and in services. And these revolutions have had global consequences. The nature of the technologies has facilitated the dispersal of manufacturing, most notably in East Asia, through standardization and modular- ization of products and intermediates and the codification of production tech- niques. The twin revolutions have made possible the outsourcing and offshoring of impersonal services, thereby enabling countries such as India to build entirely new and thriving services sectors specializing in business process outsourcing, information technology–enabled services, and software that barely existed before 1990. The Internet and the web have also raised networking to an entirely new plane. Networking is as old as human society, but as currently practiced, thanks to advances in information technology (IT), it has become a major force driving change (Rennie and Zorpette 2011).14 GPTs lent impetus to the industrial miracles in East Asia, for example, and without them it would be difficult to imagine that international value chains could have evolved to the extent they have and that logistics and supply-chain management could ever have reached such a level of sophistication and produc- tive efficiency. By harnessing the potential of the GPTs, countries were able to maximize the returns from other elements of globalization. Countries that became efficient producers of manufactures or proved adept at exploiting the Internet and digital technologies, enlarged the gains from trade, attracted more capital, and reaped lasting economic gains. 14 Lucky (2000, 260, 262) believes that the new IT is much more potent than the telegraph and the telephone and is affecting the pace of science more decisively. To illustrate the point, he observes that although the solar eclipse that proved Albert Einstein’s conjectures was observed on May 29, 1919, “Einstein had still not heard of the results as late as September 2nd. Then on September 27th, he received a telegram from Hendrik Lorentz informing him that Arthur Eddington had found the predicted displacement of starlight.” Lucky points out that the telegraph, the telephone, and the wireless were all one-to-one topologies connecting two users. Radio and television are one-to-many topologies that broadcast to a great many users. The power of the new media derives from their “many to many” topologies. “They allow the sharing of information in textual, graphic, and multi- media formats across these communities, and they empower users within these commu- nities to build their own applications. It is this empowerment of the periphery that has opened the floodgates of innovation to millions. . . . The key idea of the Internet—a simple, common core protocol with the intelligence at the periphery—was the critical ingredient of the culture from which the Internet arose.” 36 Some Small Countries Do It Better The remarkable productivity of the GPTs, their ubiquity, and their dispersion across the world take us to the fifth facet of globalization, which is the role of ideas—their production and their rapid as well as widespread dissemination through the many channels created by IT-induced networking. The first round of globalization also drew some of its energy from the production and circulation of ideas on trade, technology, and political systems. In contrast, the ongoing global- ization might never have achieved its current tempo had a substantial deepening of learning economies not occurred in Europe and the United States before World War II.15 The massive expansion of these learning economies in the post- war decades and their effectiveness in generating ideas, some of which struck commercial roots, gave rise to new markets and triggered the emergence of com- panies that supplied these markets. Investment in education at all levels and in research within specialized institutions16 and in the business sector,17 coupled with the successful cultivation of a culture of innovation, produced a payoff that lifted growth rates in the second half of the 20th century and supported the gains in productivity that have increasingly sustained them since. It is important to recognize the multidimensional characteristics of technolog- ical change and innovation made possible by investment in systems of learning and research. The revolution caused by advances in semiconductors, electronics, and telecommunication technologies is widely associated with new products and the ways products are manufactured. Undoubtedly, these advances have con- tributed significantly to economic change, but product innovation was powerfully reinforced by numerous collaborative innovations in other areas—for example, in services, institutions, organizations, and habits and lifestyles. GPTs have proven to be an extraordinarily potent transformative force because the learning economy generated a cross-disciplinary matrix of supporting and intersecting innovations that enormously magnified the influence of the core technologies. Globalization, with some assistance from these very same GPTs, is a vehicle for disseminating ideas and technologies to countries that built modern learning and innovation systems capitalizing on the new opportunities much faster than the laggards. Globalization has promoted innovation by opening national systems and mobilizing talent from throughout the world to refine and extend existing 15 Goldin and Katz (2009) attribute the great advances of the U.S. economy in the 20th cen- tury to the spread of schooling after 1910 and the further boost to education in the imme- diate decades after World War II. 16 Such research received an enormous boost during World War II and the Cold War that followed from spending on research for military purposes, especially in the United States. See Markusen and others (1991) on military industrialization in the United States and Singer (2009) on defense-related technologies. 17 Following Thomas Edison’s lead (and that of German companies), large U.S. firms, notably in the chemicals industry, began creating research labs early in the 20th century. How Sifire Compressed Development 37 technologies and to develop new technologies. This globalization of innovation activities18 is a vital step, because the continuous deepening of knowledge in every field is demanding even greater specialization from researchers (with increasing investment of time). Advances in science and technology that require the pooling of expertise drawn from several subdisciplines necessarily involve the labor of teams made up of a number of specialists, and over time, the size of teams grows. National systems of learning and innovation nurture these specializations, but it is globalization that has spurred networking and collaboration by encouraging both face-to-face and electronic interaction among specialists; by giving birth to virtual communities of researchers; by making innovation a global enterprise that, bolstered by an array of publishing activities, straddles disciplines; and by supporting channels permitting the exchange and circulation of ideas or research results. Globalization facilitates faster technological catch-up and the building of production capabilities, and it can stimulate innovation if countries invest in the knowledge infrastructure to absorb ideas and technologies and engage in their further development. Globalization powerfully affected the fortunes of late developers by supplying some of the scaffolding for the economic renaissance in Finland, Ireland, and Singapore. Absent global integration along the lines previously described and the incentives and pressures such globalization generated, it is difficult to imagine how these small countries could have squeezed so much economic transforma- tion into less than two decades. Globalization, however, was an enabling element, albeit a major one. Other countries were equally well positioned to move forward but did not, which is what makes the Sifire experience so eminently instructive. Old Light For each of the Sifire countries, the most exciting and formative period extended from the mid 1980s through the 1990s, but some of the preconditions of later development must be sought in the two preceding decades. Three deserve the most attention. One was a process of consensus building among the key stakeholders— the government, the business community, and labor—regarding development objectives for small countries with limited natural resources. This complex process of aligning the objectives and winning the commitment of stakeholders was resolved in Singapore by the early 1970s. The political economy of devel- opment was on a firm footing in Finland, also by the mid-1970s, in part because virtually all members of the Finnish Parliament were engaged in discussing and determining economic policy programs (Dahlman, Routti, and Ylä-Anttila 2006). 18 For more on the globalization of innovation, see Athreye and Cantwell (2007); Athukorala and Kohpaiboon (2010); Carlsson (2006); Jaruzelski and Dehoff (2008); Lewin and Couto (2007). 38 Some Small Countries Do It Better Ireland, however, took longer to arrive at a workable understanding of how to pur- sue development. A start was made in the 1950s with the partial abandonment of the protectionist policies adopted after 1932, which had begun stifling growth and employment generation,19 and the process continued in the 1960s when investment in education won political favor. Support for European Economic Community (EEC) membership helped push the cause of export-led economic modernization, an interest that was aroused in the late 1950s following the pub- lication of Albert Hirschman’s (1958) influential The Strategy of Economic Devel- opment.20 But for three decades thereafter, progress was slow because of the persistence of entrenched attitudes and vested interests, particularly those of rural property owners (Girvin 2010). It was not until the latter part of the 1980s that Charles Haughey managed to arrive at a durable agreement with all social partners on the management of the economy, a program for maintaining social stability, and a rebranding of Ireland as a country that was hospitable to MNCs and was moving away from narrow nationalism and Roman Catholicism toward a more progressive culture (Foster 2008). Consensus building in those earlier years created the understanding and social capital21 for constructive political interaction and economic management.22 The rules of the game for all parties were hammered out and gradually internalized, a process that helped to strengthen the sinews of administrative capabilities in the public sector and to contain uncertainties for decision makers in the business community, local as well as foreign. Each country tested the mechanisms for achieving political and macroeconomic stability and bestowed on them a degree of legitimacy. A second precondition was the priority given to education and, in particular, to its quality. Of course, the level of commitment varied among the three coun- tries, but the need for sound primary and secondary general education and the advantages of imparting vocational training to a fraction of the workforce were understood in all, with Finland and Singapore being the most committed. Early on, decision makers recognized the role of human resources in developing these 19 See Durkan (2010) on the genesis of protectionism in the 1930s and the move toward openness. The Irish Export Board was founded in 1952. 20 Hirschman’s persuasive case for export industries that could lead through backward and forward links to a quickening of development and employment generation caught the attention of Seán Lemass and T. K. Whitaker, who, with the assistance of Louden Ryan, were responsible for guiding Ireland’s industrial policy in the 1950s (Walsh and Whelan 2010). 21 Ireland has traditionally been a tightly knit society with dense links facilitating the diffu- sion of social knowledge. Social capital can help bolster collective action, which is often undersupplied. 22 Mac Sharry and White (2001) refer to the social partnership between the various interest groups in Ireland that helped resolve the fiscal crisis. This very same compact produced the consensus behind the opening of the economy, the joining of the EU, and the com- mitment to Europeanization (see also O’Toole 2009). How Sifire Compressed Development 39 economies and planned accordingly. The future contribution of tertiary educa- tion was also perceived by the late 1980s as a means of supplying higher-order skills for a modern economy, and resources were channeled into expanding exist- ing facilities and creating new ones. A history of industrialization, however modest, was a third precondition. With- out it, a country will struggle to accelerate growth, irrespective of the opportunities presented by external development and domestic shocks. The bar need not be set too high. Industrial capabilities in Finland, Ireland, and Singapore were fairly mod- est in the 1960s and the 1970s, and the base of manufacturing was narrow, but all three countries had been exposed to modern industrial practices by their proxim- ity to major industrial nations and through indigenous manufacturing activities and trade. Moreover, Singapore was an important logistics hub and a former British naval base, with extensive repair and support facilities that served to embed engineering and metalworking skills. Thus, rapid development in Sifire was preceded by • The gradual articulation of a consensus on economic direction, leading to the development of political institutions for engaging stakeholders and resolving differences. Hence, the countries could maintain economic focus. • Investment in the education system to provide universal primary education, to expand the coverage of secondary and vocational schooling, to raise quality standards, and to expand the tertiary-level knowledge economy. • An accumulation of modern industrial capabilities in the late 1960s and 1970s. There is no sound empirical basis for specifying preconditions appropriate for triggering rapid development in any one country or set of countries sharing broadly similar characteristics. And the three preconditions described earlier need not have sufficed. Success was the outcome of several additional factors, none of which was sufficient in itself, although in these three countries, the combination of factors proved to be a viable mix. Crises and Consequences Whether it is countries or companies that are affected, a crisis can catalyze a chain of decisions and changes with potentially far-reaching consequences. New leader- ship with a compelling vision that galvanizes reforms, removes bottlenecks, and triggers a round of investment is one outcome. A crisis by driving home the seri- ousness of the situation confronting a country—or a corporation—can also lead to the articulation of a longer-range strategy and the commitment to its system- atic implementation by mobilizing existing institutions and organizations or by establishing new ones with an eye to the proposed strategy. Of course, not all crises lead to fruitful outcomes. Crises can result in panic, confusion, acrimonious political bickering, and ill-conceived decisions; a decline in the quality of gover- nance; and the derailing of good long-term strategies. Indeed, though crises can 40 Some Small Countries Do It Better present opportunities, seizing those opportunities is conditional on having cer- tain capabilities in place, on possessing policy-making skills, on successfully assembling coalitions to back and implement new initiatives, and on establishing a fund of political goodwill that allows contending parties to bury their differ- ences and overcome resistance from entrenched interests whose rents are threat- ened. In addition, every country can use a dose of luck. During the 1980s and the 1990s, Ireland, Finland, and Singapore faced and responded to crises in ways that stimulated development. In the mid 1980s, Singapore realized that with domestic labor costs rising and competition mount- ing from other Southeast Asian economies, the low-cost assembly and processing model of industrialization would be unable to deliver the growth rates the city- state was seeking. A drastic slowing of the economy in the mid 1980s convinced the authorities of the need to contain the spiraling costs and, at the same time, begin switching tracks by diversifying into new products and services and upgrading existing activities.23 A severe fiscal crisis starting in the late 1980s—the result of political mismanagement—forced Ireland to adopt the Tallaght Strategy24 in 1987. The changes adopted would eventually enable Ireland, with the help of MNCs and its EU partners, to transition to a higher growth path. Finland was compelled to engage in bank restructuring and scramble for an alternative growth model following a severe financial crisis, which erupted in 1990, and the collapse of its principal export markets in the Soviet Union and Eastern European countries (see Honkapohja and others 2009). In short order, Finland needed to reduce its reliance on resource-based products and to groom new lead- ing sectors with long-run potential in European and global markets. Each of the countries had already established mechanisms for managing development—a process had begun in the 1960s in most countries, including some of the most backward, and was still ongoing. But for Sifire, the crises induced an overhaul and focusing of these mechanisms in three important respects. First, the advantages of defining a development path through a consul- tative process became more apparent. Crises helped crystallize options and prod decision makers to choose among alternatives by systematically gathering and evaluating data and by canvassing the views of market participants. Second, the crises highlighted the desirability of mechanisms to reduce invest- ment risks for domestic and foreign investors and thereby raise the level of investment through better coordination of the decisions of key players, of public investments, and of policy incentives. A development strategy was only a first step to be followed by others: mobilizing investor sentiment behind the strategy 23 Singapore’s industrial diversification and development of core technologies is graphed by Felipe (2010) using the product space technique pioneered by Hidalgo and Hausmann (2008). 24 The strategy included tax, welfare, and competition reforms. How Sifire Compressed Development 41 appeared to require extramarket institutions for achieving a degree of syn- chronicity, with a government agency acting as a convener, a clearinghouse for proposals, and a source of financing, as well as a source of signals to help orches- trate business decisions.25 The effectiveness of a long-term strategy and of coordinating mechanisms rested on a third factor, which was the governments’ capacity to implement deci- sions, to follow through with promises, and to ensure that incentives were actually delivered with the minimum of transaction costs. Crises in these small economies underlined the advantages of public organizations with a limited number of clear objectives, a readiness to engage with key stakeholders, streamlined structures with few layers, and strict accountability.26 The lessons emerging from the 1980s that the three countries variously put into practice point to the following: (a) the valuable guidance that can be pro- vided by a development strategy and institutions for consultation and coordina- tion, (b) the advantages of enhancing policy implementation capabilities through organizational reforms and simplification of procedures,27 and (c) the reduction of transaction costs weighing on the business community. The now ubiquitous “one-stop agency” was born. Investing in Growth Effective coordination with a follow-through of policies can induce the level of public and private investment in productive assets that is a significant source of growth directly through embodied technical progress and learning by doing. It was apparent in the 1980s that the growth rates Sifire sought hinged on a suffi- cient volume of domestic and foreign investment. Governments in each of the countries worked closely with the business community to build a competitive pol- icy environment and to channel resources into industry. Finland’s strategies and incentive policies focused on the domestic business sector, because the country had indigenous industrial capabilities and could build on them. Neither Ireland or Singapore had such capacities. To deepen the industrial system and move up the value chain in manufacturing and services, both countries required the foreign investment and technologies that only MNCs could provide. Ireland lacked domestic growth engines; Singapore had few, but most were publicly owned. Hence, development strategy, governance, and policy implementation were 25 Such a role to compensate for the myopia and failures of the market has received much attention from Rodrik (2005) and earlier in the East Asian context from Amsden (1989, 2007); Amsden and Chu (2003); and Wade (1990). 26 See Mader, Myers, and Kelman (2009) on government efficiency. 27 This kind of streamlining is the hallmark of the Doing Business Indicators, Investment Climate Assessments, and Benchmarks of Competitiveness. 42 Some Small Countries Do It Better deliberately designed to attract MNCs that would provide ready-made jobs and growth and, over time, spillovers to stimulate local firms and promote start-up activities.28 Both countries offered foreign investors a full suite of incentives. In addition, they engaged in intensive international marketing campaigns, seeking potential investors to ascertain their requirements and doing their utmost to meet those requirements through domestic investment in training, infrastructure, urban services, and amenities to attract private capital. All three countries recognized the importance of investment in manufacturing by medium-size and large firms because those firms create better-paid jobs and benefit from scale economies, access to global markets, and the capacity to con- duct research and development (R&D).29 This two-pronged approach of incen- tivizing private investment, both domestic and foreign, and buttressing it with public investment worked well in Sifire. Governments also catered to new entrants and smaller firms in the interests of a dynamic churning of the industrial sector.30 Also, new entrants are not infrequently the vehicles for introducing disruptive, often low-cost technologies that larger firms are inclined to shun, but once these technologies are proven, large firms embrace, improve, scale up, and market them. Singapore’s investment policy resulted in much higher rates of capital spending than is found in either Finland or Ireland. Its large government-linked corporations were more responsive to incentives, and longer-term financing was more readily available from public banking institutions and sovereign wealth funds. Singapore also succeeded in attracting a substantial flow of foreign capital into manufacturing. To burnish the country’s attractiveness to foreign companies, the state spent lavishly on urban, transport, and communication infrastructure and on industrial parks. EU structural funds31 enabled Ireland to ramp up spending on infrastructure and education services, for example, and to partially offset the shortfall in 28 MNCs provided an avenue for integrating local networks of indigenous firms with global corporate networks. This process of global integration is embedded, in O’Riain’s (2000, 158) words, “in a set of neo-corporatist institutions that have managed the relation to the global economy of both the macro-economy and of unionized workers [in Ireland].” 29 The important role of medium-size and large transnational firms from emerging economies is apparent from Aguiar and others (2009) and Verma and others (2011). 30 A churning resulting in a turnover and replacement of firms throughout the food chain differentiates the U.S. economy from Japan’s, which has maintained a relatively stable hierarchy of firms for decades. These entrenched behemoths have relied heavily on the domestic market for the sale of consumer electronics and computers and have seen their market share erode in overseas markets since the mid 2000s. 31 After joining the EEC in 1973, Ireland received €17 billion from the EEC’s (now EU’s) structural funds between 1978 to 2003. These amounts may have added 0.5 percent yearly to the growth of gross domestic product in the 1990s (UNIDO 2005, 78). These structural funds, which were created to support the EU’s regional development policy, were the European Regional Development Fund and the European Social Fund. How Sifire Compressed Development 43 infrastructure spending between 1980 and the early 1990s,32 but investment never soared to the levels reached in Singapore. Smaller flows of FDI to Ireland might also be linked to a focus on software and services rather than on hardware, although Dell, Intel, Fujitsu, Hewlett-Packard, and other electronics heavy- weights, mostly from the United States, did set up production units in Ireland.33 Finland’s investment rate was comparable to Ireland’s, although it pulled in much less FDI. As a consequence, growth never rose to the levels seen in Singapore and briefly in Ireland. In contrast to Singapore, Finland and Ireland were able to promote more domestic entrepreneurial activity and new entry, resulting in siz- able and vibrant pools of small and medium-size enterprises, a point that will be discussed later. However, in all three countries, much of the economic weight was concentrated in large corporations, both domestic and foreign. Learning and Innovation Countries respond to crises in different ways. Many turn to short-term fixes that frequently fail to correct systemic weaknesses and eliminate deep-seated distor- tions. A minority are prompted to take a hard and critical look at their economic fundamentals, to try to break away from a past trajectory, and to chart a new course. Finland, Ireland, and Singapore are among the countries that were able to take a longer view after a crisis and reorient their strategies. By the 1980s, it was becoming apparent that by betting on the technologically dynamic industrial subsectors—principally electronics, telecommunications, chemicals, and pharmaceuticals—small countries could improve their longer- term growth prospects. Technological expertise was not a substitute for capital. Instead, it could multiply the returns from capital spending through heightened productivity and innovation. Making technology into a primary driver of the economy called for raising the capabilities of all segments of the workforce, from factory workers to managers to researchers and professionals of all stripes—what 32 Investment in telecom facilities was sufficient and facilitated IT-based development in the 1990s. 33 “A relatively low-cost, young, well-educated Irish labor force combined with a 10 percent tax rate—the lowest manufacturing tax rate in Europe and about one-third of that in the U.S.—has been attracting multinational manufacturers to Ireland for some time. . . . In 1996, IBM opened its European strategic operating site in Ireland, a $350m investment. Other major [original equipment manufacturers], including Dell Computer, Hewlett- Packard, Microsoft, and 3Com, have major operations in Ireland. Intel also has roots there, opening its first 0.25 nanometer microprocessor facility serving Europe” (Cornell 2001). UNIDO (2005, 80) observes that “inward FDI was greatly stimulated by Irish tax policy, the more so once Ireland was within the EU. [American companies have also been attracted by] agglomeration benefits . . . knowledge spillovers and thick labor markets.” 44 Some Small Countries Do It Better might be described as an O-ring approach.34 With the complexity of production techniques rising through the 1990s and IT infiltrating the workplace, maximiz- ing manufacturing productivity demanded larger inputs of hard and soft skills.35 The quality of management was correlated with technology adoption, efficient resource use, incremental innovation, and human resource development (Bloom and others 2010). Better-educated individuals were more likely to engage in entre- preneurial activity and to start up high-tech activities (Berry and Glaeser 2005). They also hired more skilled workers and favored research. Investment in tertiary and vocational education increased the porosity of an economy to the latest tech- nologies and nudged it closer to the production frontier. More important, this process of absorption and the concomitant closing of technology gaps strength- ened the case for domestic R&D and encouraged technology deepening, not just in narrowly defined scientific fields, but more generally through innovation across the board in, for example, organization, marketing, health services, and teaching. In embracing technology as a driver of long-term growth, Sifire successfully engaged in building capabilities. This success is the core of the Sifire model and resulted in the making of a networked learning and innovation system (LIS) of the front rank. Finland and Singapore, if not Ireland, can claim to have created world-class systems. The foundation of a world-class system comprises universal primary and secondary education with high quality standards. Some research suggests that the quality of secondary school students measured by international test scores such as TIMSS (Trends in International Mathematics and Science Study) and PISA (Programme for International Student Assessment) are among the more significant determinants of growth (see chapter 3) (Hanushek and Kimko 2000). Allied with vocational training for those who do not enter secondary school or do not earn higher degrees, this grounding in quality education and 34 The O-ring theory of economic development was popularized by Kremer (1993), who based it on the failure of a small rubber seal, which Richard Feynman dramatically iden- tified as the culprit in the Challenger space shuttle disaster in 1986. 35 Technology development has been geared to the factor and skill endowments of advanced countries, and research has pointed to a skill bias (see Acemog ˘lu 1998; Acemog ˘lu and Zilibotti 2001; Caselli 1999). The rapid catch-up by Sifire was facilitated by a buildup of skills to extract the maximum productivity advantage from the latest technologies and to create the capacity to tweak and extend these technologies through indigenous innovation. The diffusion of information and communication technologies and the increased share of IT-based capital investment have served to increase the demand for highly skilled workers as against those with midrange skills (Michaels, Natraj, and van Reenen 2010). Moreover, the bias of technological change overall appears to favor the substitution of capital and digital technologies for labor and jobs for the most skilled over jobs for those with a modest level of skills (Brynjolfsson and McAfee 2011). How Sifire Compressed Development 45 training is the basis for a competitive learning economy and preparation for ter- tiary-level training. Since the 1980s, the increasing skill bias of technology and the displacement of midlevel white-collar workers engaged in routine tasks by IT have meant that to find employment many more technical and white-collar workers need tertiary- level qualifications, with a higher percentage of researchers requiring doctoral degrees (Autor and Dorn 2011; Michaels, Natraj, and van Reenen 2010). The Sifire strategies anticipated the demand for such higher-level skills—especially science, technology, engineering, and mathematic (STEM) skills—to achieve competitive- ness in technology-intensive activities. The countries moved quickly to begin expanding the capacity and quality of universities, although achieving both out- comes could take many years. Priority was also given to research capacity in selected universities, with a focus on science and engineering disciplines. All three countries put a premium on math and science skills at the high school and college levels in anticipation of future demand from the activities that were to comprise the backbone of the economies. Policy makers in Sifire were conscious that an LIS needed to work with and cater to the productive sectors and contribute to their competitiveness. Doing so meant fulfilling three requirements. First, teaching institutions and vocational schools had to be sensitive to market signals regarding types of skills in demand and had to ensure that their graduates cleared the bar of quality. To satisfy busi- nesses and other employers, universities needed employers’ inputs and support when designing curricula and course offerings and in complementing these courses with faculty staffing, internship arrangements, scholarship support, and postdoctoral positions. Creating effective feedback loops between the university sector and the business community was a major hurdle, and surmounting it was facilitated by the intermediation of key government agencies.36 Such coordination and feedback are widely accepted as a necessary objective, but one that often proves elusive. The Sifire strategy came closer to obtaining the sought-after results and minimizing the mismatching of skills. Second, the research universities needed to become a fruitful source of ideas, of interdisciplinary capabilities, and of some patentable technologies of commercial value that would lead to local start-ups. Academia was never assumed to be the principal source of ready-to-market technologies. It would train researchers and engage in basic research, thereby adding to the fund of usable knowledge. Also, academia would devote some resources to upstream applied research financed by its own resources, government funding, and contractual arrangements with firms. University-industry links that led to a circulation of knowledge and researchers 36 With 20 universities, Finland’s planned higher education system enjoys limited autonomy and staffing. The courses offered are strongly influenced by forecasts of labor market demand, very much along the lines followed by Singapore (OECD 2007). 46 Some Small Countries Do It Better and a flow of financing to universities were a significant ingredient of the strategy. Furthermore, universities were viewed as a source of entrepreneurship to help transfer innovation to the business sector.37 The LIS saw universities playing a vital supporting role with businesses, espe- cially the large firms doing the bulk of the applied research and commercial innovation. In Ireland and Singapore, the focus of development agencies and education institutions was initially on serving the MNCs. In Finland, Nokia took the lead, in conjunction with the National Board of Education, the Ministry of Education, and the Future Committee of the Parliament, in persuading the Acad- emy of Finland to accelerate the initiative to become a knowledge society by mobilizing universities and public research entities (OECD 2007).38 In other words, these small economies adopted a business-first learning and innovation strategy. Third, in building a world-class LIS, small economies must accept a high degree of openness39 and be ready to compete with the best—or risk losing their most talented people.40 The experience of Sifire puts the spotlight on an impor- tant lesson, which is the need to set high standards for an LIS and to adopt inter- national pay scales to ensure that the LIS is “sticky” and avoids a net loss of the best minds. High standards come at a price; they entail building a costly infra- structure of libraries, lab facilities, and office space and staffing universities with qualified and expensive employees able to impart state-of-the-art knowledge.41 The top echelon of knowledge workers have seen global opportunities multiply and, as a result, are exceedingly mobile. Their home-country bias is frequently outweighed by the package of incentives and the quality of the working and living conditions that are to their satisfaction. In addition to university and research facilities, “stickiness” is a function of two other elements of the LIS. First is the dynamism of the business sector, its offer of technological challenges, and its commitment to competing on the basis of innovation. Second is the creativity of the urban environment. Ireland and Singapore have relied on high-tech MNCs 37 MIT and Stanford were the prototypical entrepreneurial universities, and they remain the leaders all others seek to emulate. See, for instance, Etzkowitz (2002); Kaiser (2010); Lecuyer (2006); Lenoir and others (2005); and Leslie and Kargon (2006). 38 This effort was broadened in 2000, with the Academy acting in tandem with Tekes (the Finnish Funding Agency for Technology and Innovation), other agencies, and the University of Helsinki to push interdisciplinary research, partnerships, and lifelong learning. 39 See Alesina and Wacziarg (1997). Countries with populations of less than a million average a ratio of imports to gross domestic product of 60 percent, three times the ratio for developing countries in general. 40 Ireland suffered from a continuing drain of workers that was reversed only in the mid 1990s. 41 See the papers on the making of world-class universities in Altbach and Salmi (2011). How Sifire Compressed Development 47 and international services providers to craft a suitably attractive technological ambience.42 Finland has depended more on home-grown companies, most notably Nokia,43 and start-ups that have demonstrated international competitiveness. Creative Cities All three countries have worked hard at improving their urban environments so as to make them more appealing to footloose knowledge workers.44 The weather does not favor Dublin,45 Helsinki, or Singapore, but each has had some success in acquiring the cachet of a creative city and an innovative hotspot. Helsinki is the Design Capital of 2012 and Turku is one of the European Capitals of Culture 2011. Investment in urban transport, good-quality housing, recreational ameni- ties, services and security, connectivity, and cultural activities has helped put these cities on the map. Finland’s Centers of Expertise Program, launched in 1994, was the start of a continuing regional policy to increase the competitiveness of its cities. Singapore has made a name for itself as an air-conditioned city (George 2000). And because innovative activities and virtually all manufacturing and ser- vices are concentrated in relatively few urban areas, urban design, livability, and attractiveness are intrinsic to the success of an LIS. This need was not as apparent in the 1980s, but with globalization and brain circulation, the quality of cities is a central thread of an LIS and is seen as such by Sifire. Information and communication technologies (ICTs) are the GPTs responsible for much of the huge burst of innovation during the past three decades. Early in the game, Sifire perceived the potential and began designing strategies accordingly to seize opportunities as they arose. Computer literacy and, more generally, IT readiness were among the objectives given prominence in equipping the work- force. They have yielded rich dividends. First, Sifire targeted the development of ICT-based industries and, through domestic and foreign investment, built the production base that has been a major source of growth, of gains in productivity, and of diversification. Second, by taking the lead in building an ICT infrastructure 42 Both countries have had some success in creating a stable of home-grown companies. Irish firms are well represented in industries such as agroprocessing and food, cosmetics, construction, packaging, and equipment manufacturing (O’Riain 2000). Singapore’s banks, transportation companies such as Neptune, engineering companies, and con- glomerates such as Keppel Corporation now have international standing. 43 The launch of a GSM (Global System for Mobile Communications) phone in 1992, the Nokia 1011, initiated Nokia’s climb to the apex of the global telecommunication industry. 44 Richard Florida (2005) and, more recently, Edward Glaeser (2011) have emphasized the growth potential and resilience of human capital–intensive knowledge cities. Others (including Glaeser) are drawing attention to the contribution such cities can make to the greening of the planet (Kahn 2010). 45 In Dublin, at any time, it is either raining or rain is imminent. 48 Some Small Countries Do It Better and encouraging the assimilation of IT in a wide range of activities, these small economies have reaped significant returns. ICT has helped transform (and flatten) organizational structures, skill profiles, work routines, and modes of interaction and collaboration. It has also reduced transaction costs of business, simplified governance, and provided innovation opportunities across a multitude of industries, including health care (Atkinson and others 2010; Brynjolfsson and Saunders 2010). Other countries grasped the potential of ICT, but Sifire extracted greater mileage than most by integrating ICT into development strategies encompassing industrialization and a closely interlaced LIS. The potential of IT has become increasingly apparent to nations and firms, and most have moved to exploit such technologies with varying degrees of success. The largest produc- tivity gains from learning and greater openness to ideas have accrued to countries that have made IT an integral component of ongoing development by making incremental changes in many different areas and by evaluating and making subsequent modifications in light of lengthening knowledge and the steady driz- zle of innovations. What Sifire Got Right An upswing in global integration was apparent in the early 1980s, and a round of industrial change seemed to be in the offing, but it was hard to identify the likely winners among the middle- and lower-middle-income countries. Finland, Ire- land, and Singapore were some of the contenders, but 30 years ago they did not strike observers as being the most advantaged. The three countries proved more adept than their competitors in anticipating and seizing opportunities. By aug- menting human capital and intangible assets and by providing the framework for networking, they encouraged technological assimilation and innovation even as a cornucopia of discoveries associated with new GPTs created industrial niches for profitable new products and tradable services. Globalization and the pace of technological change served as the enabling con- ditions for these countries—as they did for others as well—but Sifire’s widening lead over other countries emerged from the forging of domestic consensus in sup- port of long-term-development strategies that were keyed to the quality of human capital, intangible factors, and an open, productively networked system of innova- tion and learning. The focus on human capital committed these countries to building their education and training assets. The importance attached to intangi- bles and the soft infrastructure undergirding development meant that institutions and capabilities supporting planning, coordinated policy making, policy imple- mentation, the evaluation of results, and the integrity of governance mechanisms were given due attention. In conjunction with public investment policies and the incentive regime, intangible capital and networks contained business uncertain- ties and promoted private investment. How Sifire Compressed Development 49 The incentive regime and the quality of the infrastructure—hard and soft— proved to be a fertile environment for businesses. Major MNCs set up shop in Ireland and Singapore, and Finland was able to grow its own successful compa- nies. Smaller firms also flourished in the two European countries and to a lesser extent in Singapore. The capstone of this development strategy was the LIS, which through gov- ernment intermediation and the cultivation of feedback loops helped to match the requirements of the business sector for varieties of human capital with the supply produced by education and training institutions. The feedback loops con- necting the training with the business sectors communicated information on standards of education quality and the employment readiness of graduates needed to maintain industrial competitiveness. The LIS also served to optimize the level and distribution of R&D among the various entities conducting research and attempted to strike a balance among technology absorption, basic research, and the different categories of applied research and to arrive at work- able arrangements for financing the research. Learning was assigned a central role in the development strategy in the interests of broad-ranging economic competitiveness, which was the surest path to growth. 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At the beginning of the period, they trailed the advanced economies by a wide margin and appeared handicapped by their small- ness and lack of natural resources. However, within a matter of two decades, they had pulled abreast of the front-runners of the early 21st century. As noted in the previous chapters, these economies were able to catch two important economic waves in the latter half of the 20th century—the electronics and information tech- nology (IT) revolutions and globalization—by adopting growth strategies that developed production geared toward exports of electronics, telecommunications, software, chemicals, and pharmaceuticals while continuing to sustain competi- tiveness in a number of traditional industries. In Ireland and Singapore, foreign direct investment (FDI) was the key driver of industrial change and exports. Finland relied less on FDI inflow than Ireland and Singapore. The performance of all three countries was crucially linked to the growth of regional and U.S. markets. Ireland and Finland benefited from the European Union (EU), and Singapore benefited from being a part of the fastest-growing region of the world. All three economies anchored their growth strategies to the deepening of edu- cation. In the early stages, they focused on good primary and secondary education (including vocational education) to cater to expanding industrial sectors. From the late 1990s, as the three began approaching technology frontiers, tertiary edu- cation began receiving equal attention. Changes in Economic Structure The three Sifire countries started as resource-based and processing economies. In 1970, one-half of Finland’s industrial output was from the food, textile, wood, and pulp and paper industries (see figure 3.1). By 2000, the shares of these four 55 56 Some Small Countries Do It Better Figure 3.1 Finland’s Industrial Composition, 1970–2007 2007 2000 1990 1980 1970 0 20 40 60 80 100 composition (%) food, beverages, and tobacco textiles, leather, and footwear wood and cork pulp, paper, printing, and publishing chemicals, rubber, plastics, and fuel other nonmetallic minerals basic metals and fabricated metals machinery not elsewhere classified electrical and optical equipment transport equipment manufacturing not elsewhere classified and recycling Source: United Nations Industrial Development Organization’s INDSTAT3 database. industrial subsectors had decreased to less than one-third and to about one- fourth of industrial production in 2007, largely because of the phenomenal growth of the information and communication technology (ICT) sector. How- ever, the traditional industries remain vital to the economy, and firms such as Patria (military vehicles and defense hardware), KONE (elevators and escala- tors), Wärtsilä (marine engines and power-generating equipment), Neste Oil (fats and oils), UPM (pulp and paper), Huhtamaki (paper and packaging), Valio (dairy products), Amer Sports (garments), and Stora Enso (paper and card- board), each with a turnover of more than €1 billion, are no less important than the ICT-based ones. Twenty-five companies account for half of all exports, and Elements of a Learning Economy 57 after Canada, Finland is the largest exporter of paper and cardboard. Electronics and electrical industries (including telecommunication equipment) began taking root in the 1960s, assisted by the links between technology-intensive producers of forest-based products and nascent engineering and electronics industries, with rapid growth occurring in the 1980s and 1990s (Dahlman, Routti, and Ylä- Anttila 2007).1 By the late 1990s, electronics accounted for almost one-third of total exports (Saarinen 2005). During the 1970s,2 Ireland was still mainly an agricultural economy, one of the poorest in Europe.3 Industrial activities were initially dominated by the food sub- sector, followed by the textile, wood, and pulp and paper sectors (see figure 3.2). Once the high-growth strategy gained traction in the 1980s, development was spearheaded by FDI in high-tech subsectors such as ICT, chemicals, and pharma- ceuticals and by internationally traded services (Rios-Morales and Brennan 2009),4 while domestic firms concentrated on traditional and food-processing industries (Barrios, Görg, and Strobl 2005).5 As the involvement of multinational corporations (MNCs) expanded, so also did the industrial footprints of the ICT, pharmaceutical, and chemical subsectors. Nevertheless, Ireland’s traditional strengths in the food-processing industries and construction materials are as important as those of Finland. Firms such as the Kerry Group (a leading supplier 1 The telecom industry in Finland was relatively unregulated from the very beginning. The landline network was never monopolized by a national company, unlike in other coun- tries. Also, free competition was allowed in the telecommunication equipment market (Ojala, Eloranta, and Jalava 2006). Finland dismantled the state monopoly in telecommu- nication, first by liberalizing telefax transmission in 1988. The cellular phone business was open to competition from the beginning, which enabled Nokia to develop its capabilities and to supply telecommunication equipment to overseas vendors at competitive prices (Häikiö 2002). 2 Twenty years earlier, in the 1950s, Ivan Fallon (2007) remembers growing up in a country with “barefoot children, an all-powerful Catholic Church, endless poverty, and mass emi- gration.” He also recalls, “Poetry, song, and a respect and knowledge of age-old culture and mythology.” 3 In the early 1960s, Irish industry comprised mainly producers of food, drinks, tobacco, textiles, and footwear. Half of food exports were live cattle. 4 The Encouragement of External Investment Act of 1959 repealed restrictions on foreign ownership of industry (White 1983). Ireland was one of the first countries in Europe to actively seek FDI (Ruane and Görg 1999). 5 FDI policy in Ireland focused on greenfield investment and new industrial segments to minimize competition with domestic firms. In addition, FDI was used to diversify Ireland’s economic structure and also the geographic distribution of industry. Many FDI projects were directed to areas outside of Dublin and Cork, the traditional manufacturing bases in Ireland. Part of the aim to attract FDI was to absorb redundant workers from agricultural sectors (Ruane and Görg 1999). 58 Some Small Countries Do It Better Figure 3.2 Ireland’s Industrial Composition, 1970–2007 2007 2000 1990 1980 1970 0 20 40 60 80 100 composition (%) food, beverages, and tobacco textiles, leather, and footwear wood and cork pulp, paper, printing, and publishing chemicals, rubber, plastics, and fuel other nonmetallic minerals basic metals and fabricated metals machinery not elsewhere classified electrical and optical equipment transport equipment manufacturing not elsewhere classified and recycling Source: United Nations Industrial Development Organization’s INDSTAT3 database. of food ingredients and flavors); the Linden Food Group (a meat processor); Diageo (which supplies premium drinks, including Guinness); and CRH (a major producer of construction materials) serve as Ireland’s standard bearers. In 1970, the Singaporean economy depended highly on rubber, petrochemical, and food products and produced hardly any electronic products (see figure 3.3). By 2000, the electronics subsector contributed almost half of the industrial out- put, and the share of chemical products had risen significantly. In contrast, the shares of the petroleum product, rubber, and food sectors had declined. This redrawing of the industrial map was the direct outcome of diversification guided by strategic investments in human capital, infrastructure, and smart urbanization that attracted FDI. Elements of a Learning Economy 59 Figure 3.3 Singapore’s Industrial Composition, 1970–2007 2000 1990 1980 1970 0 20 40 60 80 100 composition (%) electronic products chemicals and chemical products transport equipment machinery and equipment fabricated metal products printing instrumentation products petroleum products food, beverages, and tobacco rubber and plastics products other products Source: Department of Statistics, various years. The Rise of High-Tech Exports The changing composition of domestic industries in the Sifire countries was mir- rored by the mix of exports. Among Finland’s top 10 export commodities in 1970, nine products were from the wood subsector and the pulp and paper subsector; ships were the only export commodity that was not resource based (see table 3.1). By 2000, telecommunication equipment had displaced lumber as the leading export (see table 3.2). Resource-based products continued to be well represented among the top 10 export commodities, but their composition also had begun shifting toward medium- and high-tech products. Unlike Finland, the export composition of Ireland was radically altered between 1970 and the end of the century. In 1970, Ireland’s main exports were food products, such as meat and butter, along with clothing and medical instruments—a mix very different from that of Finland (see table 3.3). With the exception of medical instruments, all of the other leading exports from the 1970s had been displaced by the end of the century (see table 3.4). Instead, the list was dominated by high-tech products (electronics and telecommunication 60 Some Small Countries Do It Better Table 3.1 Finland’s Top 10 Exports in 1970, by Value Value Technology Rank Description (US$ million) class 1 Lumber, sawn, planed, and so forth: conifer 217.1 RB1 2 Sulfate wood pulp 161.0 RB1 3 Newsprint paper 150.3 RB1 4 Ships and boats, other than warships 147.6 MT3 5 Other printing and writing paper, machine made 128.3 RB1 6 Machine-made paper and paperboard, simply finished 114.8 RB1 7 Kraft paper and kraft paperboard 106.0 RB1 8 Plywood, including veneered panels 97.8 RB1 9 Sulfite wood pulp 79.6 RB1 10 Paper and paperboard in rolls or sheets not elsewhere specified 65.4 RB1 Source: United Nations Commodity Trade Statistics Database. Note: MT3 = engineering products; RB1 = agriculture-based products. Table 3.2 Finland’s Top 10 Exports in 2000, by Value Value Technology Rank Description (US$ million) class 1 Telecommunication equipment not elsewhere specified 9,685.6 HT1 2 Other printing and writing paper, machine made 3,263.1 RB1 3 Machine-made paper and paperboard, simply finished 2,053.9 RB1 4 Paper and paperboard in rolls or sheets not elsewhere specified 1,599.3 RB1 5 Lumber, sawn, planed, and so forth: conifer 1,459.2 RB1 6 Electric power machinery 1,385.1 Other 7 Ships and boats, other than warships 1,035.2 MT3 8 Sulfate wood pulp 916.5 RB1 9 Passenger motor cars, other than buses 787.9 MT1 10 Motor spirits, gasoline, and other light oils 721.8 RB2 Source: United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; MT1 = automotive products; MT3 = engineering products; RB1 = agriculture-based products; RB2 = resource-based products. equipment) and pharmaceutical compounds and products (see Honohan and Walsh 2002). Singapore’s principal exports in 1970 were predominantly resource-based products. The country’s location and ports enabled Singapore to develop a thriv- ing petrochemicals industry and to earn handsome returns from ship repair—an activity that led to the highly lucrative manufacturing of oil-drilling platforms Elements of a Learning Economy 61 Table 3.3 Ireland’s Top 10 Exports in 1970, by Value Value Technology Rank Description (US$ million) class 1 Meat of bovine animals, fresh, chilled, or frozen 118.8 PP 2 Bovine cattle including buffalo 109.6 PP 3 Petroleum, crude and partly refined 52.6 PP 4 Butter 29.4 RB1 5 Chocolate and other food preparations of cocoa 25.7 RB1 6 Clothing of textile fabric, not knitted or crocheted 22.7 LT1 7 Bacon, ham, and other dried, salted, or smoked pig meat 22.1 RB1 8 Ores and concentrates of zinc 22.0 RB2 9 Medical instruments not elsewhere specified 21.6 MT3 10 Beer including ale, stout, and port 20.2 RB1 Source: United Nations Commodity Trade Statistics Database. Note: LT1 = textiles and fashion products; MT3 = engineering products; PP = primary products; RB1 = agriculture- based products; RB2 = resource-based products. Table 3.4 Ireland’s Top 10 Exports in 2000, by Value Value Technology Rank Description (US$ million) class 1 Organic and inorganic and heterocyclic compounds 14,206.0 RB2 2 Statistical machines cards or tapes 9,748.1 HT1 3 Office machines not elsewhere specified 8,050.4 HT1 4 Thermionic valves and tubes, transistors, and so forth 4,165.6 HT1 5 Phonograph records, recorded tapes, and other sound recordings 4,020.7 LT2 6 Medicaments 3,725.7 HT2 7 Telecommunication equipment not elsewhere specified 3,174.8 HT1 8 Synthetic perfume and flavor materials and concentrates 1,592.2 RB2 9 Chemical products and preparations not elsewhere specified 1,418.3 MT2 10 Medical instruments, not elsewhere specified 1,243.7 MT3 Source: United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; HT2 = other high-technology products; LT2 = other low-technology products; MT2 = process industries (chemicals and basic metals); MT3 = engineering products; RB2 = resource- based products. and other structures by Keppel Offshore & Marine6 (see table 3.5). The export composition of Singapore, like that of Ireland, changed markedly between 1970 and 2000. Although petrochemical products remained in the top 10, other 6 See Keppel’s website at http://www.kepcorp.com/en/content.aspx?sid=80 for more infor- mation about the company. 62 Some Small Countries Do It Better resource-based products were replaced by high-tech products—mainly electron- ics and telecommunication equipment (see table 3.6). The change in export composition of the three countries is striking evidence of technological catch-up and, in Finland’s case, of pushing the frontiers of technol- ogy by dint of investment in learning (see figures 3.4–3.6). In 1970, more than half Table 3.5 Singapore’s Top 10 Exports in 1970, by Value Value Technology Rank Description (US$ million) class 1 Natural rubber and similar natural gums 383.2 PP 2 Motor spirits, gasoline, and other light oils 143.3 RB2 3 Lamp oil and white spirits 66.3 RB2 4 Residual fuel oils 66.0 RB2 5 Distillate fuels 52.7 RB2 6 Lumber, sawn, planed, and so forth: nonconifer 34.2 RB1 7 Pepper and pimento 34.1 PP 8 Coffee, green or roasted 30.0 PP 9 Palm oil 28.3 RB1 10 Lubricating oils and greases 25.3 RB2 Source: United Nations Commodity Trade Statistics Database. Note: PP = primary products; RB1 = agriculture-based products; RB2 = resource-based products. Table 3.6 Singapore’s Top 10 Exports in 2000, by Value Value Technology Rank Description (US$ million) class 1 Statistical machine cards or tapes 6,828.2 HT1 2 Distillate fuels 3,788.6 RB2 3 Thermionic valves and tubes, transistors, and so forth 3,674.6 HT1 4 Telecommunication equipment not elsewhere specified 2,027.5 HT1 5 Office machines not elsewhere specified 2,024.5 HT1 6 Lamp oil and white spirits 1,907.9 RB2 7 Motor spirits, gasoline, and other light oils 1,854.6 RB2 8 Radio broadcast receivers 1,575.9 MT3 9 Phonographs, tape and other sound recorders, and so forth 1,419.4 MT3 10 Residual fuel oils 1,335.0 RB2 Source: United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; MT3 = engineering products; RB2 = resource-based products. Elements of a Learning Economy 63 Figure 3.4 Finland’s Composition of Exports by Technology Class, 1970 and 2000 a. 1970 b. 2000 HT2 RB2 RB2 HT1 LT1 LT2 HT1 MT1 MT2 RB1 RB1 MT3 HT2 LT2 LT1 other LT2 PP PP MT1 other MT2 MT3 Source: Authors’ calculations using data from the United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; HT2 = other high-technology products; LT1 = textiles and fashion products; LT2 = other low-technology products; MT1 = automotive products; MT2 = process industries (chemicals and basic metals); MT3 = engineering products; PP = primary products; RB1 = agriculture-based products; RB2 = resource-based products. Figure 3.5 Ireland’s Composition of Exports by Technology Class, 1970 and 2000 a. 1970 b. 2000 RB2 HT1 HT2 LT1 RB2 RB1 HT1 LT2 MT1 MT2 RB1 MT3 PP other other MT3 HT2 MT2 LT1 PP MT1 LT2 Source: Authors’ calculations using data from the United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; HT2 = other high-technology products; LT1 = textiles and fashion products; LT2 = other low-technology products; MT1 = automotive products; MT2 = process industries (chemicals and basic metals); MT3 = engineering products; PP = primary products; RB1 = agriculture-based products; RB2 = resource-based products. of Finland’s and Ireland’s exports and close to three-quarters of the exports of Singapore were of resource-based or processed goods. By 2000, they accounted for less than one-third of the exports of Finland and Ireland and less than one-fourth of Singapore’s exports. What was so notable by the end of the century was the sheer scale of high-tech exports from these economies, clearly demonstrating the 64 Some Small Countries Do It Better Figure 3.6 Singapore’s Composition of Exports by Technology Class, 1970 and 2000 a. 1970 b. 2000 RB2 HT1 HT2 LT1 PP RB1 LT2 MT1 other RB2 MT2 MT3 MT3 other RB1 MT2 HT1 MT1 LT2 LT1 HT2 PP Source: Authors’ calculations using data from the United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; HT2 = other high-technology products; LT1 = textiles and fashion products; LT2 = other low-technology products; MT1 = automotive products; MT2 = process industries (chemicals and basic metals); MT3 = engineering products; PP = primary products; RB1 = agriculture-based products; RB2 = resource-based products. diversification of industry and the huge strides in manufacturing and technologi- cal capabilities.7 Education Sector: An Overview The economic transformation from 1970 onward was made possible by the accu- mulation of human capital in these countries.8 On average, public spending on education by Sifire was approximately 4 percent of gross domestic product (GDP) between 1980 and 2000. Finland and Ireland were already a little higher as early as the 1970s. Singapore was somewhat lower. Public spending on education by Organisation for Economic Co-operation and Development (OECD) countries 7 Further diversification into the creative industries might be a necessary step for all three economies, and Finland is showing the way with recent successes in the electronic games industry by companies such as Rovio Mobile (the producer of Angry Birds) and Rocket Pack. 8 In wooing foreign investors, Ireland emphasized the youthfulness of its workforce, and although MNCs attached importance to the low corporate income tax rates Ireland offered, the quality and English-language skills of Irish workers were an important draw. The increase in Ireland’s working-age population is related to the legalization of contra- ception in 1980, which led to a sharp decline in fertility. This youth dividend contributed to Ireland’s performance from 1990 to 2005. However, lower rates of fertility will result in rapid aging in the coming decades (Bloom and Canning 2003). Elements of a Learning Economy 65 Table 3.7 Public Expenditure on Education, 1970–2006 Share (%) Indicator 1970 1980 1990 1995 2000 2006 Finland Share of GDP 5.7 5.1 5.4 7.0 6.0 6.1 Share of total government expenditure — 10.9 11.9 12.2 12.2 12.6 Ireland Share of GDP 4.6 5.8 4.7 5.0 4.3 4.8 Share of total government expenditure 10.8 10.9 10.2 13.5 13.5 14.0 Singapore Share of GDP 3.2 2.7 3.0 3.1 3.7 3.2a Share of total government expenditure 11.7 8.1 19.5 23.5 — 11.6a Source: World Bank’s EdStats database. Note: — = not available. a. Data are for 2009. has averaged about 5 percent of GDP since 1975 (see table 3.7). Finland has con- sistently remained above this level, and both Ireland and Singapore are below the OECD norm. OECD countries have allocated about 12.5 percent of public spend- ing to education, with Finland almost on par with the OECD average. Ireland has allocated more to education since 1995. The smaller size of the government sector in Singapore and initially lower allocation for education explains why its ratio is the smallest. Budgetary allocation was raised in the 1990s. Once private spending is factored in, overall outlay on education is higher than the global aver- age. The notable factor about education in Finland is that it is entirely free at all levels, while this is not the case in the other two countries. Table 3.8 shows the share of public spending on education allocated to the primary, secondary, and tertiary levels. As early as 1960, the average years of schooling in Finland and Ireland were already relatively high: nearly six years and just exceeding six years, respectively. Singapore, at slightly more than four years, was well short of the other two (see figure 3.7). From early on, these countries made expansion of education access a policy priority.9 With rising enrollments at all levels of education, the average 9 Singapore’s first Five-Year Plan gave priority to free primary education, with an emphasis on mathematics, science, and technical subjects. Spending was increased after 1965, and the government redoubled its efforts to recruit teachers and instituted a free textbooks program (Goh and Gopinathan 2008). 66 Some Small Countries Do It Better Table 3.8 Share of Public Expenditure for Education, 1970–2007 Share of total public education expenditure (%) Education level 1970 1980 1992 2001 2007 Finland Primary — — 25.8 21.6 20.4 Secondary 44.4 38.8 38.0 40.1 42.6 Tertiarya 8.8 18.0 28.5 32.9 31.4 Ireland Primary — 22.6 27.2 31.9 35.1 Secondary 34.3 34.0 37.6 34.4 34.3 Tertiarya 11.7 15.3 19.9 28.6 23.4 Singapore Primary — — — 28.1 21.6 Secondary 31.5 35.2 27.1 29.1 24.8 Tertiarya 13.8 14.6 24.6 26.9 34.4 Source: World Bank’s EdStats database. Note: — = not available. Figure 3.7 Average Years of Schooling for People 15-Years-Old and Above, 1960–2000 12 10 8 number of years 6 4 2 0 1960 1965 1970 1975 1980 1985 1990 1995 2000 Finland Ireland Singapore Source: Barro and Lee 2000. Elements of a Learning Economy 67 Figure 3.8 Public Expenditure per Student 12,000 amount (US$ for 2000) 10,000 8,000 6,000 4,000 2,000 0 0 6 0 6 99 06 00 06 00 00 00 00 19 20 20 20 d,2 d,2 d,2 d,2 , , , , lan lan lan lan ore ore CD CD Fin Fin Ire Ire ga p ga p OE OE Sin Sin primary secondary tertiary Source: World Bank’s World Development Indicators database. years of schooling in the Sifire countries increased. Finland passed Ireland in 1985, and by 2000, it was the leader, with years of average schooling equaling 10 years compared to 7 in Singapore. In 2000, Finland was spending about US$4,000 on primary school students, US$5,600 on secondary school students, and US$9,000 on students enrolled in a tertiary-level institution. Singapore’s outlay in 2000 was US$1,600 on primary, US$2,700 on secondary, and US$8,500 on tertiary education. By the turn of the century, these countries were assigning greater importance to tertiary education than were the OECD countries as a group (see figure 3.8). In 2006, all three con- siderably increased the spending per student in secondary education to almost 40 percent of total education expenditure. Per student expenditure for primary education increased, but by a smaller amount. Spending on tertiary education rose further between 2000 and 2006, with Singapore showing the largest increase. Primary Education Preschool and primary education—in terms of quantity and quality—are the foundation for later academic prowess and scientific literacy.10 High enrollment in primary education is desirable to support an expansion of secondary and tertiary education in line with development needs, and the quality of primary education has a profound bearing on later academic achievement. Ireland and Singapore achieved close to universal primary education by 1970,11 and Finland did so by 10 The contribution of schooling to nation building motivated investment in Finland in the early decades of the 20th century. 11 Mass primary education was the first objective of the Singapore government during the “survival-driven” phase of development—1959 to 1978 (Shanmugaratnam 2009). 68 Some Small Countries Do It Better Table 3.9 Primary Enrollment, 1970–2007 Share of eligible population (%) Indicator 1970 1980 1990 1995 1999 2002 2007 Finland Gross enrollment 82 98 99 99 99 102 98 Net enrollment — — 98 99 99 100 96 Ireland Gross enrollment 107 101 103 102 104 104 105 Net enrollment 93 90 90 91 93 95 97 Singapore Gross enrollment 105 108 104 95 — — — Net enrollment 94 99 96 93 — — — Source: World Bank’s World Development Indicators database. Note: — = not available. 1980 (see table 3.9). As is apparent from the test scores presented later in this chapter, Sifire countries have achieved outstanding results. Secondary Education Net enrollment in secondary education rose smartly in Finland and Ireland, from 71 percent and 63 percent, respectively, in 1970 to 93 percent and 80 percent, respectively, in 1990. Singapore brought up the rear with a rate of 44 percent, which was the average for middle-income countries at that time. Gross enroll- ment rates in all three countries were far higher because of the presence of older students (see table 3.10). A large fraction of secondary-level students in Finland have pursued vocational training—30 percent and more (see table 3.11).12 In comparison, vocational and technical enrollments were lower in Ireland and Singapore but were by no means trivial. Arguably, the building of industrial skills through attention to vocational and technical training assisted the growth of Sifire in the 1980s and 1990s. Singapore, in particular, benefited from this growth. Singapore has offered vocational training as a viable option for students who are not academically inclined and made determined efforts to erase the status gap between general and 12 An even larger percentage of students in Switzerland rely on vocational and technical training as the stepping-stone to a rewarding career. A full two-thirds select from 230 course offerings, either by enrolling part time and combining classroom instruction with apprenticeships at participating host companies or by enrolling full time in a vocational education and training program at a trade or commercial school. The success of Swiss industry is closely linked to the quality and supply of technical skills produced by the var- ious training institutions. Elements of a Learning Economy 69 Table 3.10 Secondary Enrollment, 1970–2007 Share of eligible population (%) Indicator 1970 1980 1990 1995 1999 2002 2007 Finland Gross enrollment 102 98 114 116 121 126 111 Net enrollment 71 — 93 93 95 94 97 Ireland Gross enrollment 74 89 99 113 107 108 113 Net enrollment 63 78 80 86 84 85 88 Singapore Gross enrollment 46 60 68 73 — — 63.2 Net enrollment 44 — — — — — — Source: Singapore data are from World Bank’s EdStat and KAM databases; other data are from World Bank’s World Development Indicators database. Note: — = not available. Table 3.11 Vocational and Technical Enrollment, 2003–2007 Share of total secondary enrollment (%) Country 2003 2005 2007 Finland 35.8 28.6 29.1 Ireland — 15.9 16.2 Singapore — — 12.0 Source: World Bank’s EdStats database. Note: — = not available. vocational education.13 Through planning and effective use of employer feedback, Singapore has attempted to match the skills offered by vocational schools with the needs of the private sector. In the initial stage, Singapore collaborated with various major foreign investors on the training of technicians for their factories. The authorities persuaded these investors to train twice the number they required and gave them the first pick of the graduates. The surplus was used as a resource to attract new investors. This strategy relieved constraints on the growth of targeted industrial clusters. It worked until the number of training centers sponsored by the various investors (and their governments) grew to where consolidation became desirable. Thus was born the Nanyang Polytechnic, which became part of 13 Singapore started with the Technical Education Department in the Ministry of Educa- tion, created in 1968. In 1979, the Vocational and Technical Training Board was estab- lished. A third step was the setting up of the Institute of Technical Education in 1992. For more information about the institute, see its website at http://www.ite.edu.sg/. 70 Some Small Countries Do It Better the polytechnic system—the Institute of Technical Education (ITE)—in Singa- pore under the Ministry of Education.14 The approach to determining the num- bers to be trained thereafter involved all the other polytechnics that were engaged with employers (through formal governance arrangements at the institutional level) and factored in projections of labor demand as well as the demands of stu- dents. Once the innovation phase of technical training was over, Singapore’s insti- tutions focused on mainstreaming and operating a system that was created as a matter of routine to anticipate and meet the evolving demand for skills steadily and efficiently. A rate of employment for graduates approaching 90 percent testi- fies to the success of the ITE. Although Finland began attempting to develop its vocational training system as early as the 1970s, serious reform efforts began gaining momentum only in 1991 with the passage of legislation to set up 22 polytechnics. This legislation was formalized in 1995. The Ministry of Education operates 25 regional, multidiscipli- nary, and relatively autonomous polytechnics that cater to the needs of local industry and help promote regional development.15 A number of institutions in Ireland provide vocational training. There are vocational education committee schools, community schools, and local and Department of Employment training centers. Graduates are also eligible for apprenticeship programs. The system benefits from being embedded in a national qualifications framework and from the close collaboration of employers (through the ICT Ireland Skillnet) with social partners and concerned government depart- ments. However, the quality of instructors and students is low; feedback and eval- uation are less rigorous than in Singapore, for example, and the overall gover- nance is weaker (see Kis 2010). Quality of Primary and Secondary Education Although the data on quality of education across countries are sparse, two inter- national tests can be used to compare student quality. Unfortunately, until recently, Singapore participated only in the Trends in International Mathematics and Science Study (TIMSS),16 while Finland and Ireland participated in the 14 Training courses are provided in five areas: engineering, business, ICT, applied sciences, and health sciences. 15See OECD (2003) for details on the Finnish polytechnic system. A list of the polytech- nics can be found on the ministry’s website at http://www.minedu.fi/OPM/Koulutus/ ammattikorkeakoulutus/ammattikorkeakoulut/?lang=en. 16TIMSS is an international assessment of the mathematics and science knowledge of fourth- and eighth-grade students around the world. TIMSS was developed by the International Association for the Evaluation of Educational Achievement to allow participating nations to compare students’ educational achievement across borders. TIMSS data have been collected in 1995, 1999, 2003, and 2007. Elements of a Learning Economy 71 Table 3.12 Singapore’s TIMSS Ranks and Scores, 1995–2007 2007 2003 1999 1995 Test Rank Score Rank Score Rank Score Rank Score Science Fourth grade 1 587 1 565 n.a. n.a. 7 547 Eighth grade 1 567 1 578 2 568 1 607 Math Fourth grade 2 599 1 594 n.a. n.a. 1 625 Eighth grade 3 593 1 605 1 604 1 643 Sources: Mullis, Martin, and Foy (2008); Martin, Mullis, and Foy (2008). Note: n.a. = not applicable. Fourth grade assessment was not done in 1999. OECD Programme for International Student Assessment (PISA).17 Nevertheless, the available information does convey a sense of the quality of education in Sifire relative to comparators. Singapore participated in PISA in 2009 for the first time. In science, in 2007, students from Singapore led the pack in tests aimed at fourth and eighth graders (see table 3.12). They were also ranked first in the 2003 test. In math, Singaporean students ranked second and third for fourth and eighth graders, respectively, in 2007. Since 1995, Singapore has excelled in math and sci- ence for fourth and eighth graders. Whereas TIMSS has two subject areas, PISA contains three: math, science, and reading.18 Finland has consistently ranked at or near the top in all categories in the last four rounds of PISA (see table 3.13 for the ranking and test scores in 2009). Compared with Finnish students, Irish students do not fare well, except in science. Their scores for science are above the OECD average. However, their scores for reading are close to the average for OECD countries, and their scores for math are below the OECD average. Singapore, for the first time, participated in the 2009 PISA.19 Singaporean students, much like their counterparts from Finland, per- formed outstandingly in all three subjects. Tertiary Education Tertiary-level enrollments in Finland and Ireland were near the European aver- age in the 1970s, with Singapore at about half that level (see table 3.14). Finland 17 The OECD’s PISA surveys 15-year-olds in the principal industrial countries. Every three years, it assesses how far students near the end of compulsory education have acquired some of the knowledge and skills essential for full participation in society (science, read- ing, and math). OECD originally created PISA for its own needs, but the assessment is now used as a major policy tool for countries around the world. 18 PISA is administered by OECD and is aimed mainly at assessing student achievements in OECD countries, but it is open to nonmembers. The first assessment was done in 2000. 19 Shanghai also participated in PISA 2009, and students from Shanghai placed first for all three subjects. 72 Some Small Countries Do It Better Table 3.13 PISA Ranks and Scores, 2000–09 Finland Ireland Singapore Test Rank Score Rank Score Rank Score 2009 Science 2 554 20 508 4 542 Reading 3 536 21 496 5 526 Math 6 541 32 487 2 562 2006 Science 1 563 20 508 n.a. n.a. Reading 2 547 6 517 n.a. n.a. Math 2 548 22 501 n.a. n.a. 2003 Science 1 548 16 505 n.a. n.a. Reading 1 543 7 515 n.a. n.a. Math 1 544 20 502 n.a. n.a. 2000 Science 3 538 9 513 n.a. n.a. Reading 1 546 5 526 n.a. n.a. Math 4 536 15 502 n.a. n.a. Source: OECD 2009. Note: n.a. = not applicable. was the first of the three to expand its tertiary education sector at a rapid pace. Between 1970 and 1980, the enrollment rates more than doubled, and since then they have continued to increase, reaching 94 percent in 2007, one of the highest in the world. The expansion of the tertiary education sector in Ireland came a decade later. A serious push started in the 1980s, but the most rapid increase occurred in the early 1990s. By 2000, the gross enrollment rate in Ireland was almost 50 percent. Singapore also began expanding tertiary enrollment in the early 1990s. With almost 50 percent of secondary school graduates going on to earn university degrees, the gross enrollment rate more than doubled over the course of the decade (see table 3.14).20 Between 1980 and 2001, the proportion of the workforce with tertiary-level qualifications rose in all three countries. The increase was greatest in Finland and least in Ireland (see table 3.15). Equally important for the purposes of increasing technological and manufacturing capabilities was the high percentage of students who majored in science, engineering, and math, a testimony to the quality of 20 One-fourth of the Singapore government’s expenditures are on education and, of this amount, 40 percent is for tertiary education (Shanmugaratnam 2009). Elements of a Learning Economy 73 Table 3.14 Tertiary-Level Education Gross Enrollment Rates, 1970–2007 Gross enrollment rate (%) Country 1970 1980 1990 1997 2000 2005 2007 Finland 13 32 45 74 83 92 94 Ireland 12 17 28 43 49 58 61 Singapore 6 8 18 44 — — 56 Source: Singapore data are from World Bank’s EdStat and KAM databases; Finland and Ireland data are from the World Bank’s World Development Indicators database. Note: — = not available. Table 3.15 Labor Force with Tertiary Education, 1995–2006 Share of total labor force (%) Country 1995 2001 2006 Finland 20.7 31.6 33.7 Ireland 24.3 25.8 42.1 Singapore 33.2 37.9 — Source: World Bank’s World Development Indicators database. Note: — = not available. instruction and the scientific literacy imparted in primary and secondary schools.21 Close to one-half of tertiary-level students in Singapore were enrolled in sci- ence and engineering fields in 2007. In Finland, science and engineering fields have attracted about one-third of the student body, whereas in Ireland, about one- fifth of students are enrolled in science and engineering fields (see table 3.16). Data on degrees awarded provides additional insight into the accumulation of scientific capital. Close to 20 percent of degrees awarded to university graduates in Finland in the early 1980s were in the fields of science and technology. Later in the decade, there was a steep decline, with only a handful of graduates earning degrees 21 From the 1970s, the number of students studying science, technology, and IT-related sub- jects in Ireland steadily increased, and by the 1990s, the ratio of such students to the total number enrolled in tertiary education was the highest in the EU. This increase catered to demand generated by MNCs and was not in support of domestic research and develop- ment, which remained low. Almost 40 percent of tertiary-level students took two-year nonuniversity courses in science and technology subjects, which helped quickly boost the supply of skilled workers at low cost. However, even in the mid 1990s, half of the labor force was not competent to participate in the knowledge economy because the IT skills of teachers and students were low (Crafts 2005; O’Toole 2009). 74 Some Small Countries Do It Better Table 3.16 Tertiary-Level Enrollment Composition, 2007 Finland Ireland Singapore Students Students Students Field enrolled Ratio (%) enrolled Ratio (%) enrolled Ratio (%) Education 15,961 5.2 10,610 5.6 5,794 3.1 Humanities and arts 45,171 14.6 27,984 14.7 16,531 8.9 Social sciences, business, and law 70,275 22.7 41,964 22.0 65,542 35.1 Science and engineering 113,299 36.6 40,553 21.3 87,306 46.8 Agriculture 6,893 2.2 2,367 1.2 0 0.0 Health and welfare 42,376 13.7 24,852 13.1 10,307 5.5 Services 15,188 4.9 9,261 4.9 1,147 0.6 Nonspecified programs n.a. n.a. 32,758 17.2 n.a. n.a. Source: United Nations Educational, Scientific, and Cultural Organization Institute for Statistics. Note: n.a. = not applicable. in science and engineering (figure 3.9). This downturn was quickly reversed, and by the mid 1990s, 28 percent of students in Finland were receiving degrees in sci- ence and engineering fields compared with 35 percent in Ireland and 54 percent in Singapore in 2000 (table 3.17). Since then, the share of graduates in science and engineering fields has been largely maintained in Finland and Singapore, although in Ireland, the share had dropped to 24 percent by 2007, and the trend in enrollments points to a further decline in the future (table 3.18). To maintain their competitive edge, both Finland and Singapore are emphasiz- ing cross-disciplinary education, which straddles science, engineering, design, and business studies and equips students with technical and entrepreneurial skills.22 Singapore has created a new university to meet this objective, and Finland merged the Helsinki University of Technology, the School of Economics, and the Univer- sity of Art and Design to create a highly selective, legally private, and potentially world-class Aalto University.23 A point that bears noting is that both Ireland and Singapore have demonstrated a readiness to adopt flexible immigration and visa issuance policies. Such policies allow them to tap the international market for skills, thus overcoming domestic shortages and skill mismatches, and, in Singapore’s case, to accommodate the pursuit of diversification into high-tech 22 Encouraging risk taking and entrepreneurship is a key objective; in Finland, as in many East Asian economies, failure in business has long been viewed as an inerasable stigma. 23 Finland has discovered that a small country cannot afford 20 universities and 25 polytechnics and is currently engaged in a process of rationalization through merger. See Aarrevaara, Dobson, and Elander (2009). Elements of a Learning Economy 75 Figure 3.9 Composition of Graduates in Finland, Tertiary Education, 1981–99 100 90 80 composition (%) 70 60 50 40 30 20 10 0 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 19 19 19 19 19 19 19 19 19 19 19 19 19 19 19 19 19 19 19 agriculture education health humanities and arts science and engineering social sciences, business, and law Source: Finnish Ministry of Education’s KOTA database (https://kotaplus.csc.fi/online/Haku.do). Table 3.17 Composition of Tertiary Education Graduates, 2000 Share of total graduates (%) Humanities Social sciences, Science and Country Education and arts business, and law engineering Agriculture Health Services Finland 7 12 23 28 3 22 6 Ireland 6 16 31 35 1 8 3 Singapore 1 8 25 54 0 8 1 Source: For Finland and Ireland, United Nations Educational, Scientific, and Cultural Organization Institute for Statis- tics; for Singapore, Ministry of Education. Note: Data for Singapore are for 1999. For Singapore, humanities and arts include social sciences. activities. In 2006, foreigners comprised close to a third of Singapore’s labor force—90,000 of whom were skilled workers (Yeoh 2007). Similarly, in 2006, for- eigners accounted for an eighth of Ireland’s labor force—almost a quarter of a million workers—when a decade earlier there had been hardly any.24 In adopting this approach, Ireland and Singapore have followed the example of Switzerland, a country that has long relied on foreign sources to close frictional skill and knowl- edge gaps and sustain industrial momentum. As a consequence, more than a fifth of Switzerland’s population is foreign born.25 24 Some 345,000 workers from the 10 countries that joined the EU on May 1, 2004, were reg- istered to work in Ireland in 2006 (Migration News 2006). 25 Switzerland’s student pool has a high share of foreigners, and well more than a third of doctoral degrees from Swiss institutions are awarded to foreign students. Swiss firms recruit from this pool; hence, immigration and labor market regulations, including work permits, are key issues (OECD 2006, 39, 81). 76 Some Small Countries Do It Better Table 3.18 Composition of Tertiary Education Graduates, 2007 Share of total graduates (%) Humanities Social sciences, Science and Country Education and arts business, and law engineering Agriculture Health Services Finland 7 15 23 29 2 19 6 Ireland 7 25 28 24 1 12 2 Singapore 4 11 22 51 0 7 1 Source: For Finland and Ireland, United Nations Educational, Scientific, and Cultural Organization Institute for Statistics; for Singapore, Ministry of Education. Note: For Singapore, humanities and arts include social sciences. Research Output Adequate, good-quality science, technology, engineering, and mathematics skills are a necessary precondition for technological catch-up and innovation. Another precondition is a research culture that stimulates technology absorp- tion, knowledge deepening, and innovation. In addition to the direct benefits, research creates jobs, produces the human capital needed to put new ideas into practice, and brings into existence a physical and social infrastructure support- ive of innovation. The research output of universities and research institutes points to the scale and sophistication of the scientific establishment and to its capacity to both absorb ideas from abroad and push the frontiers of science and technology. Universities are at the core of the scientific establishment, and their research caliber can be gauged from a number of indicators. One is through tallying the number of papers published in scientific and technical journals. In 1981, researchers in Finland published 2,173 scientific and technical journal articles (table 3.19). This output is respectable but not outstanding. (For instance, the number published by German residents was 26,837.) Researchers in Ireland pub- lished 700 papers in 1981, and those in Singapore published 124. In all three coun- tries, the pace of publication picked up in the 1990s. Singapore’s output doubled every five years starting in 1981, although it started from a low base. Nonetheless, by 1995, the scientific output of Singapore matched that of Ireland, and by 2000, it surpassed Ireland and was a little under half of Finland’s output. This trend reflects Singapore’s effort to expand the tertiary sector and to improve the quality of both teaching and research. Citations to papers are an index of quality. By field of specialization, Finland has the greatest influence on agricultural sciences, physics, and clinical medicine (see table 3.20). For instance, papers in the agriculture sciences by Finnish researchers received 57 percent more citations than the world average in that field. As a share of total world publications, the top fields for Finland are environment Elements of a Learning Economy 77 Table 3.19 Scientific and Technical Journal Articles, 1981–2005 Number of articles Country 1981 1985 1990 1995 2000 2005 Finland 2,173 2,485 3,071 4,077 4,844 4,811 Ireland 700 653 902 1,218 1,581 2,120 Singapore 124 289 572 1,141 2,361 3,609 Source: World Bank’s World Development Indicators database. Table 3.20 Impact of Finnish Papers, 2004–08 Field Share of world publications (%) Impact (%) Agricultural sciences 0.95 57 Physics 0.80 57 Clinical medicine 1.04 43 Environment and ecology 1.77 34 Geosciences 1.00 32 Plant and animal sciences 1.03 26 Engineering 0.77 20 Mathematics 0.66 13 Pharmacology and toxicology 0.82 10 Psychiatry and psychology 0.96 6 Source: Thomson Reuters’s Science Watch (http://sciencewatch.com/dr/sci/09/oct18-09_2/). Note: The data are based on 43,795 papers that listed at least one author’s address in Finland between 2004 and 2008. The impact is calculated as the relative number of Finnish citations to the world average in each field. and ecology, space science, and computer sciences. The latter two are not listed in the table because of their low-impact value. Ireland has many high-impact papers in material sciences, immunology, and physics (see table 3.21). By share, papers in the agriculture sciences are ranked highest, followed by those in space science and microbiology. Part of the reason for Ireland’s strong performance in agriculture sciences is the traditional focus on this sector and the establishment in 2003 of the Science Foundation Ireland, which aims to raise Ireland’s profile in the biosciences and ICT. Part of the foun- dation’s responsibility is to recruit promising scientists and engineers from over- seas (Rios-Morales and Brennan 2009). Thomson Reuters’s Science Watch, the source for the data in tables 3.20 and 3.21, did not analyze the impact of papers from Singapore; however, engineer- ing is one of the strengths of tertiary institutions in the city-state. Nanyang Technological University ranked eighth, and National University of Singapore 78 Some Small Countries Do It Better Table 3.21 Impact of Irish Scientific Papers, 2004–08 Field Share of world publications (%) Impact (%) Materials science 0.36 59 Immunology 0.52 49 Physics 0.45 44 Agricultural sciences 1.12 30 Chemistry 0.29 26 Space science 0.78 19 Geosciences 0.40 18 Engineering 0.43 14 Microbiology 0.71 11 Neuroscience and behavior 0.42 11 Source: Thomson Reuters’s Science Watch (http://sciencewatch.com/dr/sci/10/feb7-10_2/). Note: The data are based on 22,789 papers that listed at least one author’s address in Ireland between 2004 and 2008. The impact is calculated as the relative number of Irish citations to the world average in each field. ninth, in the top 20 engineering institutions in the world, on the basis of citations received by papers published between 1999 and 2009.26 Ranking of Universities The university scorecard, which is based on a number of criteria, provides another window on technological and innovation capacity. By these criteria, the three countries are well positioned, although not anywhere near the forefront. Among Sifire institutions, the National University of Singapore occupied 30th place in 2009, followed by Trinity College Dublin at 43rd, Nanyang Technological Univer- sity at 73rd, and University College Dublin at 89th (see table 3.22). The highest- ranking university in Finland was the University of Helsinki, at 108th. Innovation Capabilities Sifire invested very little in research and development (R&D) during the 1970s and early 1980s, and innovation capability was modest. At that time, the main economic activities in the three countries were not R&D intensive. Finland’s 26 The highest-ranking Asian institution (seventh place) was the Chinese Academy of Sci- ence. The University of Tokyo ranked 17th, and the Indian Institutes of Technology ranked 11th. See http://sciencewatch.com/inter/ins/10/10febTOP20ENG/. Elements of a Learning Economy 79 Table 3.22 Ranking of Universities, 2009 University Country Rank National University of Singapore Singapore 30 Trinity College Dublin Ireland 43 Nanyang Technological University Singapore 73 University College Dublin Ireland 89 Source: QS World University Rankings (http://www.topuniversities.com/). Table 3.23 R&D Expenditure, 1996–2007 Share of GDP (%) Country 1996 2000 2003 2006 2007 Finland 2.5 3.3 3.4 3.4 3.4 Ireland 1.3 1.1 1.2 1.3 — Singapore 1.4 1.9 2.1 2.4 — Source: World Bank’s World Development Indicators database. Note: — = not available. economy was still heavily dependent on relatively low-tech resource sectors,27 Ireland’s on agriculture and food, and Singapore’s on light manufactures. R&D Spending Once Sifire embraced a human capital– and technology-led strategy, the tempo of research rose, and Finland and Singapore increased their R&D spending from the mid 1990s (see table 3.23).28 By 2007, Finland was spending 3.4 percent of GDP on R&D, comparable to high R&D spenders such as Japan and the Republic of Korea. The process leading to this research focus began in the 1980s, when Finland established the Finnish Funding Agency for Technology and Innovation (Tekes) to distribute funding for R&D. In 1987, Tekes functions were augmented by the cre- ation of the Science and Technology Policy Council. Thereafter, the share of inno- vation supported by public funding rose from less than 20 percent to more than 27 It is not the case that there were no research activities in these areas. The first commercial R&D lab in Finland was established by Alko Oy (the national alcohol company) in 1908. In the 1930s and 1940s, forest industry firms established several joint research labs to share costs of research in such areas as export facilitation, weathering, strength, quality, and so forth (Saarinen 2005). 28 A rapid increase in R&D in Finland was adopted as a policy goal starting in the 1990s, with the aim of reaching 2.9 percent of GDP by 1999 (Ojala, Eloranta, and Jalava 2006). 80 Some Small Countries Do It Better Table 3.24 Researchers in R&D, 1984–2006 Number of researchers per million people Country 1984 1987 1996 2000 2003 2006 Finland — — — 6,733 7,998 7,681 Ireland — — 1,764 2,239 2,513 2,882 Singapore 879 1,211 2,538 4,140 4,744 5,713 Source: World Bank’s World Development Indicators database. Note: — = not available. 80 percent of GDP (Saarinen 2005). Singapore also increased its spending on R&D in the 1990s, and by 2006, outlay on R&D reached 2.4 percent of GDP. In contrast, Ireland’s R&D expenditure has remained around 1 percent of GDP for the past 15 years. Researchers As R&D spending rose, so also did the number of researchers in Finland and Sin- gapore (see table 3.24). In 1984, there were fewer than 1,000 researchers per mil- lion people in Singapore. By 2006, the number had ballooned to more than 5,700. Finland followed suit with the number of researchers rising from 5 for every 1,000 workers in 1991 to 22 for every 1,000 workers, or almost three times the OECD average (OECD 2010). Even though R&D spending as a share of GDP did not increase in Ireland, the number of researchers climbed from 1,764 in 1996 to 2,882 in 2006, in step with the growing volume of resources devoted to research. Patents Scientific publications are one indicator of research output; patents are a second and more sensitive indicator of the commercial potential of research (see table 3.25). In 1970, the U.S. Patent and Trademark Office (USPTO) granted 46 patents to Finnish residents, 12 to Irish residents, and none to Singaporean residents.29 Compared to the 4,439 patents granted to German residents at that time, the numbers granted to Sifire were small. Much has changed, beginning in the late 1990s. With respect to total patents granted from 1963 to 2009, Finland ranks 16th, Singapore 23rd, and Ireland 28th. Finnish residents garnered the largest number of patents from the mid 1980s onward (see table 3.25), with Singapore and, to a lesser extent, Ireland picking up speed after 1995. But even though the 29 The numbers of patents granted by national patent offices are not comparable because of differences in grant decisions. For international comparison, it is better to use a patent office as a base. Here, data from USPTO are used. USPTO assigns “nationality” of a patent on the basis of the resident country of a first-named inventor of the patent. Elements of a Learning Economy 81 Table 3.25 U.S. Patents Granted by Country of Origin, 1970–2008 Number of patents granted Country 1970 1975 1980 1985 1990 1995 2000 2005 2008 Finland 46 98 121 200 304 358 618 720 824 Ireland 12 15 16 30 49 47 121 156 164 Singapore 0 1 3 9 12 53 218 346 399 OECD average 527 768 739 983 1,300 1,238 1,897 1,771 2,014 Source: Data from USPTO. Note: OECD average excludes the United States. Table 3.26 Top 10 Technology Classes by the Number of Patents Granted to Residents of Finland in the 1980s Class number Class title Number of patents 162 Paper making and fiber liberation 128 210 Liquid purification or separation 52 73 Measuring and testing 42 29 Metalworking 35 250 Radiant energy 35 34 Drying and gas or vapor contact with solids 32 414 Material or article handling 31 144 Woodworking 31 241 Solid material comminuting or disintegration 30 423 Chemistry of inorganic compounds 27 Source: Data from USPTO. number of patents granted to Sifire residents during this period rose, compared to the OECD average (excluding the United States),30 the numbers were still rela- tively small. It is not surprising that Finnish residents received most of their patents for technology related to paper making in the 1980s. Not a single patent was for technologies associated with electronics or telecommunication equipment, for which Finland is now famous (see table 3.26). But starting in the 1990s, once Nokia had emerged as an ICT powerhouse, the composition of patenting changed swiftly. Between 2005 and 2009, the technology classes of patents granted to Finnish residents reveal that the bulk of patents are concentrated in 30 The figure for the United States was excluded because for U.S. entities USPTO is a domes- tic patent office and because U.S.-based organizations tend to apply to USPTO for patents more often than foreign-based entities. 82 Some Small Countries Do It Better Table 3.27 Top 10 Technology Classes by the Number of Patents Granted to Residents of Finland between 2005 and 2009 Share of total Class number Class title Number of patents patents granted (%) 455 Telecommunications 781 18.6 370 Multiplex communications 494 11.7 375 Pulse or digital communications 190 4.5 162 Paper making and fiber liberation 128 3.0 709 Multicomputer data transferring (electrical computers and digital processing systems) 117 2.8 713 Support (electrical computers and digital processing systems) 72 1.7 128 Surgery (includes class 600) 70 1.7 424 Drug, bioaffecting, and body-treating compositions (includes class 514) 66 1.6 379 Telephonic communications 64 1.5 187 Elevator, industrial lift truck, or stationary lift for vehicle 61 1.4 Source: Data from USPTO. telecommunication and related technologies, consistent with the changing com- parative advantage. Four classes out of 10 listed in table 3.27 are in telecommuni- cations, and 2 are in data transfer. Only 3 percent of all patents are in paper and pulp, although this sector remains one of Finland’s key industries and several of the country’s largest firms are producers of forest-based products, firms such as Stora Enso, UPM, and Metsäliitto. Ireland had begun showing some capabilities in electronics and communi- cation technologies by the late 1980s along with technologies associated with the medical industry (drugs and surgery), as was evidenced by the patent sta- tistics (see table 3.28). The trend became more firmly entrenched in the 1990s, and it is highly visible in the data for 2005 to 2009 (see table 3.29). Patents obtained by Irish residents are concentrated in computers, semiconductors, and telecommunications, with continuing strength in medical fields, especially surgical instruments. During the 1980s, Singapore received few patents from the USPTO, and most were related to machinery (see table 3.30). It is difficult to imagine from these earlier data that Singapore would emerge as an important innovator in elec- tronics and the semiconductor industry, which is what transpired in less than two decades. By 2009, Singapore was clearly specialized in semiconductor and computer-related technologies (see table 3.31). In fact, all the top 10 classes belong to a broad definition of electronics, IT, and telecommunication devices. Elements of a Learning Economy 83 Table 3.28 Top 10 Technology Classes by the Number of Patents Granted to Residents of Ireland in the 1980s Class number Class title Number of patents 156 Adhesive bonding and miscellaneous chemical manufacture 12 340 Communications: electrical 10 424 Drug, bioaffecting, and body-treating compositions 9 318 Electricity: motive power systems 9 360 Dynamic magnetic information storage or retrieval 8 128 Surgery 8 525 Synthetic resins or natural rubbers (part of the class 520 series) 7 250 Radiant energy 7 526 Synthetic resins or natural rubbers (part of the class 520 series) 6 200 Electricity: circuit makers and breakers 5 Source: Data from USPTO. Table 3.29 Top 10 Technology Classes by the Number of Patents Granted to Residents of Ireland between 2005 and 2009 Share of total Class number Class title Number of patents patents granted (%) 341 Coded data generation or conversion 36 4.4 424 Drug, bioaffecting, and body-treating compositions (includes class 514) 33 4.0 370 Multiplex communications 29 3.5 606 Surgery (instruments) 24 2.9 709 Multicomputer data transferring (electrical computers and digital processing systems) 23 2.8 327 Miscellaneous active electrical nonlinear devices, circuits, and systems 20 2.4 375 Pulse or digital communications 20 2.4 128 Surgery (includes class 600) 19 2.3 455 Telecommunications 18 2.2 257 Active solid-state devices (for example, transistors, solid- state diodes) 17 2.1 Source: Data from USPTO. 84 Some Small Countries Do It Better Table 3.30 Top 10 Technology Classes by the Number of Patents Granted to Residents of Singapore in the 1980s Class number Class title Number of patents 89 Ordnance 7 166 Wells 5 29 Metalworking 3 273 Amusement devices: games 3 118 Coating apparatus 2 405 Hydraulic and earth engineering 2 47 Plant husbandry 2 206 Special receptacle or package 2 361 Electricity: electrical systems and devices 2 351 Optics: eye examining, vision testing, and correcting 2 56 Harvesters 2 173 Tool driving or impacting 2 Source: Data from USPTO. Table 3.31 Top 10 Technology Classes by the Number of Patents Granted to Residents of Singapore between 2005 and 2009 Share of total Class number Class title Number of patents patents granted (%) 438 Semiconductor device manufacturing: process 307 15.5 257 Active solid-state devices (for example, transistors, solid-state diodes) 237 11.9 360 Dynamic magnetic information storage or retrieval 99 5.0 385 Optical waveguides 42 2.1 330 Amplifiers 41 2.1 375 Pulse or digital communications 39 2.0 324 Electricity: measuring and testing 38 1.9 439 Electrical connectors 35 1.8 455 Telecommunications 32 1.6 327 Miscellaneous active electrical nonlinear devices, circuits, and systems 29 1.5 Source: Data from USPTO. Elements of a Learning Economy 85 Table 3.32 Top 10 Assignees by the Number of Patents Granted to Residents of Finland in the 1980s First-named assignee Number of patents Individuals 513 Valmet Oy 173 Outokumpu Oy 120 Oy Wärtsilä Ab 94 Oy Tampella Ab 90 A. Ahlström Osakeyhtiö 68 Neste Oy 42 Enso-Gutzeit Oy 39 Elevator GmbH 32 Labsystems Oy 25 Source: Data from USPTO. A glance at the top 10 entities that actually hold the right to patents assigned to Finnish residents in the 1980s reveals that most patents were granted to individu- als, followed by Valmet, a state-owned machinery maker;31 Outokumpu, then a mining company; Wärtsilä, a diesel engine maker; and Tampella, a heavy industry manufacturer (see table 3.32). Since the beginning of the 21st century, Nokia has dominated innovation in Finland and has received more than half of all patents granted to Finnish assignees between 2005 and 2009 (see table 3.33).32,33 Even though there was no concentration on specific technology classes in Ire- land, the data on assignees indicate clearly that electronics, IT, telecommunication, and medical firms are the major areas of specialization (see tables 3.34 and 3.35). 31 Valmet merged with Rauma in 1999 to become Metso. 32 Nokia opened its first R&D unit in 1960 (Saarinen 2005), and it accounts for one-third of R&D expenditures and about half of business R&D (Ojala, Eloranta, and Jalava 2006). Finland’s grasping of first-mover advantages through innovation are discussed by Lester (2005). 33 Nokia sits at the center of Finland’s ICT cluster in Oulu and other cities, which consists of almost 6,000 firms. Some 300 of those firms are first-tier subcontractors to Nokia (see OECD 2000). The ICT cluster is by far the most innovative segment of the economy, with firms receiving technical know-how from Nokia. It generates 10 percent of Finland’s GDP, with Nokia accounting for 3.5 percent alone (Ylä-Anttila 2007; Ylä-Anttila and Palmberg 2007). However, the cluster is weakly interlinked with the rest of the economy (Daveri and Silva 2004). 86 Some Small Countries Do It Better Table 3.33 Top 10 Assignees by the Number of Patents Granted to Residents of Finland between 2005 and 2009 First-named assignee Number of patents Share of total patents granted (%) Nokia Corporation 1,964 54.9 Metso Paper Inc. 185 5.2 Nokia Mobile Phones Ltd. 153 4.3 Individuals 124 3.5 KONE Corporation 92 2.6 ABB Oy 77 2.2 Nokia Networks Oy 73 2.0 Telefonaktiebolaget LM Ericsson 44 1.2 ASM International NV 43 1.2 Instrumentarium Corp. 33 0.9 Source: Data from USPTO. Foreign subsidiaries play a significant role in national R&D in Ireland34 (Rios- Morales and Brennan 2009); hence, many assignees are MNCs.35 Similarly, many assignees in Singapore are well-known foreign manufacturers of electronics and semiconductors. Such companies already topped the list of assignees in the 1980s (see table 3.36), and the dominance of well-known MNCs has become more apparent in recent years (see table 3.37). What is notable is the relatively large share of patents assigned to the Agency for Science, Technology, and Research (A*STAR)36—a public research organization—and to the National University of Singapore. Furthermore, none of the assignees are as dominant as in Finland and Ireland, pointing to a broader base of innovation activities in Singapore resulting from R&D by MNCs in several fields. This broader base also reflects on the quality of the research talent and the infrastructure in Singapore. 34 From early on, Ireland relied on foreign subsidiaries for R&D. In 1995, foreign sub- sidiaries accounted for 65 percent of business R&D expenditure. In 1993, foreign firms accounted for 95 percent of R&D expenditures in the pharmaceutical industry, 78 percent in the software industry, and 64 percent in the automotive industry (Kearns and Ruane 2001). 35 USPTO classifies the nationality of a patent by the nationality of the first inventor. Therefore, if the first-mentioned inventor is residing in Ireland, the patent is considered Irish even though it may be assigned to a firm located elsewhere. 36 A*STAR is Singapore’s principal research organization and the driving force behind programs for building research capability, such as the Biopolis project. Elements of a Learning Economy 87 Table 3.34 Top 10 Assignees by the Number of Patents Granted to Residents of Ireland in the 1980s First-named assignee Number of patents Loctite (Ireland) Limited 38 Kollmorgen Technologies Corporation 10 Institute for Industrial Research and Standards 6 Elan Corporation Plc 7 Analog Devices Inc. 7 Gallaher Limited 4 Institute for Industrial Research and Standards 4 Security Imprinter Corporation 3 National Research Development Corporation 3 SPS Technologies Inc. 3 Source: Data from USPTO. Table 3.35 Top 10 Assignees by the Number of Patents Granted to Residents of Ireland between 2005 and 2009 First-named assignee Number of patents Share of total patents granted (%) Analog Devices Inc. 104 21.3 Individuals 67 13.7 Boston Scientific Scimed Inc. 25 5.1 Medtronic Vascular Inc. 23 4.7 Nortel Networks Limited 22 4.5 Loctite (R&D) Limited 19 3.9 Donnelly Corporation 16 3.3 Intel Corporation 16 3.3 TDK Corporation 15 3.1 3Com Corporation 14 2.9 Source: Data from USPTO. Innovation Facilitator International trade mediates technology flow through the imports, FDI, and direct trading of technologies.37 Imports, particularly of capital goods, transfer embed- ded technologies. FDI stimulates exporting activities and builds technological 37 See Nabeshima (2004) for the various channels of technology transfer. 88 Some Small Countries Do It Better Table 3.36 Top 10 Assignees by the Number of Patents Granted to Residents of Singapore in the 1980s First-named assignee Number of patents General Electric Company 7 Chartered Industries of Singapore Private Ltd. 7 U.S. Philips Corporation 5 Motorola Inc. 4 Sun Industrial Coatings Private Ltd. 4 Eastern Oil Tools Pte. Ltd. 3 Metro Plastic Industry Pte. Ltd. 2 VARTA AG 1 Everbloom Biotechnology Ltd. 1 Polycore Optical Pte. Ltd. 1 Source: Data from USPTO. Table 3.37 Top 10 Assignees by the Number of Patents Granted to Residents of Singapore between 2005 and 2009 First-named assignee Number of patents Share of total patents granted (%) Chartered Semiconductor Manufacturing Ltd. 184 11.4 Micron Technology Inc. 154 9.5 Agency for Science, Technology, and Research 136 8.4 Seagate Technology LLC 118 7.3 National University of Singapore 78 4.8 Marvell International Ltd. 72 4.4 STATS ChipPAC Ltd. 62 3.8 Individuals 62 3.8 Hewlett-Packard Development Company LP 58 3.6 STMicroelectronics Asia Pacific Pte. Ltd. 54 3.3 Source: Data from USPTO. capabilities38 through spillovers, demonstration effects, training of workers, demand for higher-skilled workers, and technical assistance given to upstream and downstream firms. Both imports and FDI exert competitive pressures on domestic firms, thereby increasing the incentives for domestic firms to innovate to survive in more competitive market conditions. Openness also encourages a more active 38 See the recent literature reviews by Saggi (2006) and Smeets (2008) on research on FDI spillovers. Elements of a Learning Economy 89 Figure 3.10 Openness to Trade, 2001–08 500 450 400 trade (as a % of GDP) 350 300 250 200 150 100 50 0 2001 2002 2003 2004 2005 2006 2007 2008 Finland Ireland Singapore Source: World Bank’s World Development Indicators database. participation in the global market for technology through direct sales and pur- chases of technologies by domestic firms. Technology absorption and its global cir- culation are increasingly supported by investments in ICT infrastructure that con- tribute to connectivity, stimulate business activity, and raise productivity and innovativeness. Openness to Trade and FDI Small, open economies that rely on trade to sustain growth and openness have been a key to Sifire’s success. Singapore, an entrepôt, tops the charts with trade as a share of GDP reaching 450 percent in 2008 (see figure 3.10). Ireland protected its domestic producers against U.K. imports from the 1930s through the mid-1960s.39 This situation changed after Ireland signed the Anglo-Irish Free Trade Area Agree- ment in 1965 (Ruane and Görg 1999). The process of tariff reductions continued once Ireland joined the European Economic Community and was completed in 1978 (Rios-Morales and Brennan 2009; Ruane and Görg 1999). Its trade-to-GDP ratio was 150 percent in 2007. Finland also has been an open economy, with a 39 During that period, FDI was prohibited by the Control of Manufactured Products Act. However, firms (especially U.K. firms) that were established before 1932, were allowed to continue their operations in Ireland. Hence, the act only limited the future inflow of FDI. Restrictions on FDI were abandoned once it became apparent that protected domestic manufacturing industries were failing to grow (Ruane and Görg 1999). 90 Some Small Countries Do It Better Figure 3.11 Imports of Goods and Services, 2001–08 250 200 imports (as a % of GDP) 150 100 50 0 2001 2002 2003 2004 2005 2006 2007 2008 Finland Ireland Singapore Source: World Bank’s World Development Indicators database. trade-to-GDP ratio of 84 percent in 2008. Imports of goods and services as a share of GDP were 215 percent, 69 percent, and 40 percent, respectively, in Singapore, Ireland, and Finland (see figure 3.11). Singapore has traditionally relied on FDI as a key instrument of industrializa- tion. On average, Singapore has attracted FDI equivalent to about 12 percent of GDP since 1980 (see figure 3.12). FDI inflows to Ireland and Finland were much smaller until the late 1990s. Foreign investors started to show interest in Ireland as a viable destination from 1990 onward, with FDI booming between 1998 and 2002. After 2004, the net inflow dipped into negative territory, because of a sub- stantial divesture in 2004 and 2005. FDI flows seem to have reversed course and become positive in 2007, but they fell off again following the onset of the financial crisis in 2008. Ireland’s strategy was to attract FDI in high-tech industries and to promote links to domestic firms, mainly with the help of tax incentives, so as to maximize technology spillovers and domestic value added.40 From 1956 to 1980, MNCs 40 Using data on manufacturing establishments in Ireland from 1972 to 2000, Barrios, Görg, and Strobl (2005) found that the effect of inward FDI on domestic industry was nonlin- ear. At the beginning, the competition effect dominated, with the result that the number of domestic firms declined as more foreign firms entered the sector. However, as the share (continued on next page) Elements of a Learning Economy 91 Figure 3.12 Net Foreign Direct Investment Flows, 1980–2008 30 net FDI flows (as a % of GDP) 25 20 15 10 5 0 –5 –10 –15 –20 80 982 984 986 988 990 992 994 996 998 000 002 004 006 008 19 1 1 1 1 1 1 1 1 1 2 2 2 2 2 Finland Ireland Singapore Source: World Bank’s World Development Indicators database. were exempted from the corporate income tax.41 From 1980 to 2010, a 10 percent tax was applied on profits accruing from manufacturing, but only for those firms that were established before 1998. Since 2003, a corporate income tax of 12.5 per- cent has been levied on trading income, and a 25 percent rate applies to passive income and income from foreign trade. In addition, financial support is given in (continued from previous page) of MNCs increased, this trend seems to have had positive spillover on the net entry of domestic firms. For instance, MNCs dominated office machines and computers, accounting for 93 percent of all establishments in the sector from 1997 to 2000. How- ever, this sector also had the highest net entry of domestic firms, averaging 17 percent between 1972 and 2000 (Barrios, Görg, and Strobl 2005). The longer MNCs were in Ire- land, the more jobs they created. For every 100 jobs in MNCs, the local economy gained 100 additional jobs in services and 10 in manufacturing. The share of domestic pur- chases of raw materials and components by MNCs rose from 15 percent of their total purchases in the mid-1980s to 21 percent by 1997 and 24 percent for electronics firms (UNIDO 2005). 41 Tax relief on exports profits was first introduced in 1956 (White 1983). This policy was initially set to end in 1990, but Ireland had to change the rule because of the complaints from the European Commission that the tax policy was against the Treaty of Rome (Ruane and Görg 1999). 92 Some Small Countries Do It Better the form of employment and training grants.42 To promote inward FDI, Ireland established the Industrial Development Agency in the late 1960s.43 Enterprise Ire- land was established in 1993 to foster links between MNCs and local firms (Rios- Morales and Brennan 2009).44 Before 1997, FDI flows to Finland amounted to less than 1 percent of GDP. However, following the lifting of remaining restrictions on capital flows, Finland has begun attracting FDI, with flows peaking in 1998 at 7 percent of GDP. Since then, FDI inflows have fluctuated in the 3 to 5 percent range, becoming negative in 2008 because of the global slowdown. Sifire countries have supplemented technology transfers embodied in imported equipment through FDI and through information flows with technol- ogy licensing. But unlike many other developing countries, they have skillfully extracted the maximum advantage because they have marshaled the scientific and network capital and assiduously built their manufacturing capabilities. Starting in the 1990s, Ireland has been actively acquiring foreign technologies, measured by royalty payments (see figure 3.13). Singapore also increased its acquisition of for- eign technologies starting in the late 1990s. Finland, in contrast, has participated less actively in the purchase of technologies, although royalty payments began increasing in the 2000s. Royalty payments as a share of GDP also point to similar trend. Payments by Ireland and Singapore surged between the mid 1990s and the early 2000s (see figure 3.14). ICT All three economies perceived the long-term potential of ICT and focused on developing skill-intensive IT and telecommunication industries with the objective 42 Interviews with MNCs from the United States reveal that the education of the workforce was the second most important factor in their decision to invest in Ireland (Barry 2007). (First was the low corporate income tax rate.) To persuade Intel to establish a production facility in Ireland, the Industrial Development Agency used every carrot and, to clinch the deal, commissioned interviews with 300 engineers of Irish origin (with the experience sought by Intel), most of whom were working in the United States. The Industrial Devel- opment Agency was able to convince Intel that 80 percent of the engineers would return to Ireland if offered an attractive job by a reputable company (Mac Sharry and White 2001). The importance of an educated workforce and the availability of good technical skills surface repeatedly in studies of the determinants of FDI. Costa Rica, for example, also used the promise of abundant skills as a lure for Intel (see Spar 1998). 43 The 1969 Industrial Development Act created the present-day agency (White 1983). 44 IDA’s Linkage Program brought MNCs in contact with local firms and helped increase the multiplier effects of FDI. Elements of a Learning Economy 93 Figure 3.13 Royalty Payments, 1975–2007 35 30 payments (US$ billion) 25 20 15 10 5 0 19 5 1977 19 9 19 1 19 3 19 5 19 7 19 9 19 1 93 19 5 19 7 20 9 20 1 03 20 5 07 7 7 8 8 8 8 8 9 9 9 9 0 0 19 19 20 Finland Ireland Singapore Source: World Bank’s World Development Indicators database. Figure 3.14 Royalty Payments as Share of GDP, 1975–2007 0.12 0.1 payments (as a % of GDP) 0.08 0.06 0.04 0.02 0 19 5 19 7 79 19 1 83 19 5 19 7 89 19 1 19 3 19 5 19 7 20 9 20 1 20 3 20 5 07 7 7 8 8 8 9 9 9 9 9 0 0 0 19 19 19 19 Finland Ireland Singapore Source: World Bank’s World Development Indicators database. 94 Some Small Countries Do It Better Table 3.38 Exports of ICT Goods, 1998–2006 Share of total exports of goods (%) Country 1998 2002 2006 Finland 20.0 22.0 18.9 Ireland 29.0 30.8 22.4 Singapore 55.1 52.6 45.6 Source: World Bank’s Information and Communications for Development database. Table 3.39 Exports of ICT Services, 1998–2007 Share of total exports of services (%) Country 1998 2000 2002 2004 2007 Finland 18.1 5.4 7.1 7.0 8.4 Ireland 33.7 45.5 38.2 36.4 30.1 Singapore — 2.4 2.5 2.2 3.1 Source: World Bank’s Information and Communications for Development database. Note: — = not available. of establishing a presence in the global market.45 ICT-related products amounted to more than 40 percent of Singapore’s total exports in 2006. The share of ICT- based exports was 22.4 percent in Ireland and 18.9 percent in Finland in the same year (see table 3.38). Ireland also excels in the export of ICT services. In 2007, close to one-third of services were related to ICT in Ireland (see table 3.39). The share of ICT-based services for Finland and Singapore are smaller: 8.4 percent and 3.1 percent, respectively. Sifire’s strength in exports of ICT goods and services is linked to the domestic investment in ICT infrastructure. From 2003 to 2008, Ireland, on average, spent more than 4 percent of its GDP on ICT; Finland spent more than 6 percent; and Singapore, more than 7 percent (see table 3.40). 45 Investment in ICT contributed 0.6 to 0.8 percentage points to total factor productivity growth in Finland during 1995 to 2000 and 0.6 percentage points to Ireland’s growth. See Honkapohja and others (2009). According to Atkinson and others (2010), the U.S. economy added US$1.6 trillion to its GDP between 1995 and 2006 on the strength of investment in and use of ICT. Every dollar invested by large firms in ICT increased the company’s market value by US$25, with ICT workers (and capital) contributing far more to a firm’s productiv- ity than non-ICT workers. Korea also derived 20 percent of its growth from investment in ICT. Among the business models and processes linked to ICT are supply-chain manage- ment (raised to a fine art by Walmart), marketing of a wide range of products to benefit (continued on next page) Elements of a Learning Economy 95 Table 3.40 ICT Expenditure as a Share of GDP, 2003–08 Share of GDP (%) Country 2003 2004 2005 2006 2007 2008 Finland 6.9 7.6 7.6 7.7 7.3 6.5 Ireland 4.9 4.9 4.8 4.8 4.5 4.6 Singapore 10.1 9.7 9.6 8.7 7.5 7.1 Source: World Bank’s Information and Communications for Development database. Table 3.41 Internet Users, 1995–2008 Number of users per 100 people Country 1995 2000 2003 2005 2007 2008 Finland 13.9 37.2 65.9 72.6 79.0 82.5 Ireland 1.1 17.8 30.8 37.5 57.0 62.7 Singapore 2.8 32.3 54.4 61.9 67.7 69.6 Source: World Bank’s Information and Communications for Development database. As a result, the number of people in the Sifire countries who have Internet con- nections has increased tremendously. In 1995, only a handful of people had Inter- net connections in Ireland and Singapore, and even in Finland the figure was low (see table 3.41). Internet connections in Finland increased from 13.9 percent in 1995 to 72.6 percent in 2005, and in Singapore, from 2.8 percent to 61.9 percent. The diffusion of the Internet was slower in Ireland, with the penetration rate in 2005 only about half of Finland’s rate. By 2008, at 62.7 percent, Ireland was approaching Singapore but was still well behind Finland. Noteworthy also is the speed of broadband diffusion in these countries. In Singapore, almost all Internet users were connected by broadband by 2008 (see table 3.42). Similarly, for Ireland, 79 percent of Internet users were using broad- band connection. Although recent figures for Finland are not available, it would be safe to assume that broadband represents the vast majority of connections. (continued from previous page) from the “long tail” (as is practiced by Amazon), more sophisticated pricing models, self- service kiosks, mass customization (a specialty of Dell), IT-enabled service, and collabora- tive design and innovation. InnoCentive, for example, has used crowd sourcing to garner solutions to scientific problems, and is one of the leading practitioners of the open, contest- and prize-based approach to innovation that is now attracting much attention. For more information, see Travis (2008) and Hotz (2009). On the contribution of ICT to growth in OECD countries, see Jorgenson, Ho, and Stiroh (2005, 2008) and van Ark, Inklaar, and McGuckin (2003). 96 Some Small Countries Do It Better Table 3.42 Fixed Broadband Subscribers, 2000–08 Share of total Internet subscribers (%) Country 2000 2001 2002 2003 2004 2005 2006 2008 Finland 5.7 14.1 25.9 37.3 57.1 — — — Ireland 0.0 — 1.0 3.5 18.6 34.8 57.6 79.0 Singapore 8.1 7.8 13.4 19.0 24.3 29.1 34.1 90.9 Source: World Bank’s Information and Communications for Development database. Note: — = not available. Table 3.43 International Internet Bandwidth, 1999–2007 Bits per second per person Country 1999 2003 2007 Finland 129.7 3,463.7 17,220.6 Ireland 63.6 5,040.2 15,228.6 Singapore 213.5 3,782.4 22,783.4 Source: World Bank’s Information and Communications for Development database. With high investment in ICT infrastructure, the Sifire countries also increased their connectivity to other countries. In fewer than 10 years, the international Internet bandwidth available to each person increased more than 100-fold (see table 3.43). High connectivity to other countries is essential if the Sifire group wishes to remain competitive in both manufacturing and IT-enabled services. And it is vital for international networking, which is increasingly the lifeblood of open innovation systems. Concluding Observations Sifire successfully managed the economic transition from primary- and resource-based production systems to more high-tech economic structures. All three countries did so by leveraging technological advances in key subsectors with the rise of advances in electronics and telecommunication (from fixed line to mobile), thereby opening new industrial pathways. Globalization in general— and for Finland and Ireland, integration with the EU—widened market opportu- nities that were essential for their industrial development. Without access to large external markets, these small countries would not have been able to grow as rapidly and consistently as they have done. More important, they were able to anticipate the changes in economic struc- ture, match the upcoming labor demand with quality education, and capitalize on Elements of a Learning Economy 97 the externalities inherent in networking. Sifire first focused on providing universal primary education and expanded secondary and tertiary education as demand for higher skills began rising. High levels of enrollment in the science and engineering fields enabled the Sifire countries to accelerate industrialization and assisted in the progressive upgrading of new and traditional industries. References Aarrevaara, Timo, Ian R. Dobson, and Camilla Elander. 2009. “Brave New World: Higher Education Reform in Finland.” Higher Education Management and Policy 21 (2): 87–104. Atkinson, Robert D., Stephen J. Ezell, Scott M. Andes, Daniel D. 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Spar, Debora. 1998. “Attracting High Technology Investment: Intel’s Costa Rican Plant.” Washington, DC. FIAS Occasional Paper 11, Foreign Investment Advisory Service, World Bank, Washington, DC. Travis, John. 2008. “Science by the Masses.” Science 319 (5871): 1750–52. UNIDO (United Nations Industrial Development Organization). 2005. Industrial Develop- ment Report 2005: Capability Building for Catching-Up—Historical, Empirical, and Policy Dimensions. Vienna, Austria: UNIDO. van Ark, Bart, Robert Inklaar, and Robert H. McGuckin. 2003. “The Contribution of ICT- Producing and ICT-Using Industries to Productivity Growth: A Comparison of Canada, Europe, and the United States.” International Productivity Monitor 6 (Spring): 56–63. White, Padraic A. 1983. “A Concept of Industrial Development in the 1980s.” Journal of the Statistical and Social Inquiry Society of Ireland 24 (5): 51–59. Yeoh, Brenda S. A. 2007. “Singapore: Hungry for Foreign Workers at All Skill Levels.” Migra- tion Information Source, January. http://www.migrationinformation.org/Profiles/display .cfm?ID=570. Ylä-Anttila, Pekka. 2007. “Finland’s Knowledge Economy Today.” In Finland as a Knowledge Economy: Elements of Success and Lessons Learned, ed. Carl Dahlman, Jorma Routti, and Pekka Ylä-Anttila, 9–16. Washington, DC: World Bank. Ylä-Anttila, Pekka, and Christopher Palmberg. 2007. “Economic and Industrial Policy Transformations in Finland.” Journal of Industry Competition and Trade 7 (3–4): 169–87. 4 Governance and Growth Theories of endogenous growth have pointed to the growth-inducing effects of technological externalities, or spillovers, arising from the accumulation of human capital. But experience has taught us that realizing the sought-after growth is not just a matter of increased spending on education and research. Growth can help build the human capital and research infrastructure, but the externalities may not follow. Here the inexact science of institutions comes into play. Institutions pro- vide a matrix of the rules and organizations to guide the accumulation of resources along with their allocation and use. With stronger, better-designed insti- tutions, countries can arrive at superior outcomes. Where institutions are weak or mostly informal, economic activities can be severely constrained, with interper- sonal transactions predominating. Worse still, ineffective or missing institutions or ones that lead to dysfunctional behavior can be welfare subtracting. Once entrenched, institutions with dysfunctional behavior are difficult to rectify and erase, thereby making it harder for organizations and individuals to engage in activities requiring complex and long-term contracts underpinned by mecha- nisms for effective enforcement. Moreover, distorted rules and corrupt organiza- tions generate perverse incentives. A large literature, using a variety of proxies, has attempted to demonstrate the relationships between institutions and growth with some success, although doubts remain. Many of those doubts arise from the choice of explanatory vari- ables and the econometric tests used. However, with regard to the Sifire group, a robust case can be made that governance institutions had a big hand in building human capital and in augmenting spillovers. The term institution can refer to a set of rules affecting behavior, and it can also refer to an organization. An important category of institutions affects governance. A definition proposed by Avinash Dixit (2009, 5) is illuminating. According to Dixit, economic governance is “the structure and functioning of the legal and 101 102 Some Small Countries Do It Better social institutions that support economic activity and economic transactions by protecting property rights, enforcing contracts, and taking collective action to provide physical and organizational infrastructure.” Whether economic gover- nance promotes growth is a function of the commitment and credibility of the government and the primacy it attaches to economic results; the quality of the organizational infrastructure responsible for planning, administering, and coor- dinating development; and the implementation capability of key public and pri- vate entities that are engaged in resource mobilization, allocation, production, and technological change. A leadership that sets its sights on effectively harnessing technology for develop- ment can initiate a virtuous spiral, and, as was argued earlier, a crisis can catalyze such determined action.1 But when governance institutions are weak, the process of accumulating and deepening technology can be slow to gather momentum or can fail altogether. The nature of the institutional base can have a strong bearing on the development of organizational capability, which is the handmaiden of eco- nomic performance. The state need not play the lead role in providing governance as a part of its public function; private parties can also do so. However, as Dixit observes, “In most countries, we find a mixture of the formal legal system and a rich and complex array of informal social institutions of governance. These mix- tures reflect the country’s level of economic development and in turn help to deter- mine its economic prospects” (Dixit 2007b, 3; see also Dixit 2007a). The Sifire countries were fortunate in that during the decades before the 1980s governance institutions were able to mature, and these mature institutions helped strengthen the organizational capabilities of the state. In each case, institutional efficacy and sustained growth was spearheaded by a major government entity vested with substantial authority. It is also notable that the economic system as a whole could respond speedily to the stimuli provided. Education and training could be ramped up, the physical and research infrastruc- ture expanded, and the business community galvanized to work closely with other parts of the economy to realize ambitious growth objectives. This chapter shows how the Funding Agency for Technology and Innovation (Tekes) in Finland, the Industrial Development Agency (IDA) in Ireland, and the Economic Develop- ment Board (EDB) in Singapore helped to plan and implement effective strategies once the commitment to growth and the necessity of yoking it to knowledge and human capital had been resolved (on EDB’s achievements see Chan 2011). By the 1980s, the three countries had developed the basic institutional ecosystem of a modern economy, with well-staffed and well-functioning organizations. Sifire shared these characteristics with many other industrializing countries, but in mak- ing the system deliver results, Sifire proved to be a cut or several cuts above the rest. 1 See Kanbur (2009) for a recent view on crises and the proposition that recurrent crises might be the new normal. Governance and Growth 103 The vulnerability of small countries surrounded by more populous and pros- perous neighbors can help to focus national attention on competitiveness in the interests of achieving comparable living standards.2 Small countries can be readier to mobilize domestic resources, and when they have few resources, the value of human capital is more apparent. Also, small economies are quicker to realize that domestic supplies and markets must be supplemented by resources from abroad and access to foreign markets. Thus, the more enterprising small economies are oriented outward and have a strong sense of how their fortunes are linked with those of the regional economy and, in recent decades, to those of the global econ- omy as well. They can see how their future depends on close interaction with other countries at many different levels to augment their narrow base of capital, labor, skills, and ideas and to tap external market opportunities. Interaction with other countries on terms advantageous to small economies depends on competitiveness—the creation of a business environment that is attractive to foreign investors; of cities that offer services, amenities, and lifestyles that will pull in tourists and long-stay knowledge workers; and of specialized tech- nologies and skills for producing differentiated and quality manufactures and ser- vices. Such countries must also have the agility to keep one step ahead of other economies by diversifying into activities with greater potential as returns from existing activities begin to erode. To consistently deliver results in each of these areas over many years is a tall order. However, Sifire countries have proved more adept than most other small economies. And their innovation in managing devel- opment must be given a major share of the credit. The starting point for each of the three countries was a leadership that forged a consensus on economic objectives and the means for achieving them. Such lead- ership is most apparent in the case of Singapore, where Lee Kuan Yew was the undisputed and justly admired driving force, and his party, the People’s Action Party (PAP), dominated and continues to dominate the polls.3 To lesser degrees, the broad strategy pursued by the political leadership in Finland and Ireland but- tressed institutional and organizational capabilities. In Ireland, the Fianna Fáil government was able to achieve common cause with the opposition Fine Gael 2 A comparison between Jamaica and Singapore by Lerner (2009) reminds us that too few countries have risen to the challenge. When they gained independence in 1965, the two countries were comparable in populations and per capita gross domestic products (GDPs)—US$2,650 versus US$2,850. But four decades later, Singapore had a per capita GDP of US$31,400 while Jamaica had a per capita GDP of US$4,800. Lerner lists various factors that weighed in Singapore’s favor, such as governance, human capital, and macrostability, but gives special importance to entrepreneurship, which he believes Singa- pore was far more successful in inculcating. 3 Lee Kuan Yew resigned his cabinet position as minister mentor on May 14, 2011, following elections that saw the PAP’s share of the popular vote decline to 60.1 percent. 104 Some Small Countries Do It Better Party and enter a social partnership with businesses and labor by adopting a con- ciliatory and cooperative approach (Economist 2004; Honohan and Walsh 2002).4 Labor was willing to accept wage restraint in exchange for more policy influence because unions were weakened by the huge increase in unemployment in the mid 1980s. The result was the resumption of a policy dialogue among the principal stakeholders and the forging of what Seán O’Riain has called the “flexible develop- ment state” to differentiate it from the more bureaucratic development states in East Asia (O’Riain 2000, 158). Unemployment approaching 20 percent in the early 1990s also helped build a political consensus in Finland around a knowledge- based strategy. This consensus was bolstered institutionally by the Finnish parlia- ment’s creation of the Committee for the Future in 1993 to conduct a dialogue with the government to find solutions for emerging problems. Such leadership and its continuity allowed a vision to be shaped and long-term programs to be initiated and implemented. As these examples illustrate, rather than being held hostage to short-term political exigencies and vicissitudes, the Sifire countries were able to work steadily toward longer-term objectives. A leadership committed to a firm economic agenda that enjoyed broad sup- port could strengthen the economic governance institutions and deepen the orga- nizational capabilities to enforce rules, uphold the law, and frame as well as imple- ment policies. In fact, it was in the area of organizational capabilities that Sifire countries were innovative and able to establish new benchmarks of excellence. Few would question the efficacy of the market mechanism in allocating resources and incentivizing production. But few also would deny that markets are myopic and can fail to coordinate the actions of multiple participants, especially when such coordination needs to be orchestrated over a period of years. Markets cannot easily accommodate scale economies and externalities. The Sifire countries are all market economies; however, the governments in these countries realized that to run ahead of the pack they would need more than what the markets alone could deliver. The crises of the 1980s added to the urgency of taking measures to avoid stagnation. The answer seemed to lie in creating organizational capabilities that could help to enlarge the information set of current or prospective market participants, to contain risks, to sweeten incentives for certain activities with per- ceived long-term potential, and to work to coordinate the actions of various par- ties whose joint effort was necessary to realize longer-term objectives. Coordinators Small economies have an advantage in that they can set their sights lower and seek simpler solutions that are frugal in the use of resources. The Sifire group needed 4 The corporatist Irish approach was in marked contrast to the confrontational strategy adopted by Margaret Thatcher’s government in the United Kingdom. Governance and Growth 105 to define a route to a more knowledge-intensive economy with solid long-term growth prospects. Transparent and effective governance institutions were the nec- essary foundations of such an economy. And to complement those institutions, governments needed organizations with the authority and capabilities to take a long-term perspective and implement policies promptly.5 Each country adopted a two-pronged approach of streamlining governance and market institutions and entrusting a single agency with the task of delivering the key elements of a growth strategy. Other economic agencies were also structured to support the lead strate- gic agency and ensure the integrity of the governance institutions. To promote the development of indigenous technologies that would contribute to the competitiveness of Finnish firms, the government of Finland established Tekes in 1983 to stimulate technology development and to encourage innovation. Tekes has a broad and ambitious mandate to look ahead and identify the promis- ing areas for technological advance—including industrial diversification—and to coordinate the working of the innovation system with the help of catalytic fund- ing of research and development (R&D). (See figure 4.1, which presents the main components of the Finnish innovation system.) Tekes is guided by the Research and Innovation Council (known as the Science and Technology Policy Council prior to 2009). Tekes is chaired by the prime minister6 and works closely with gov- ernment agencies; with the Academy of Finland, which promotes basic research; with Sitra (the Finnish Innovation Fund); and with universities, firms, and private financiers.7 Tekes pushes the government’s innovation agenda and attempts to keep Finland at the leading edge of technological change in selected areas of spe- cialization. With a budget of €500 million provided by the Ministry of Trade and Industry, Tekes has financed up to 2,000 projects annually—mostly R&D activities undertaken by firms, but a quarter or more are initiated by universities and other research bodies. Tekes’s role in the renaissance of Finnish technology is widely recognized. By combining strategic foresight on fruitful areas for medium-term R&D with net- working and coordination skills and implementation capacity, this modestly scaled agency with a staff of 400 (about a fifth of whom are stationed in the leading 5 Hung (2000, 199) notes that the institutional environment most conducive to industrial development comprises a policy network embracing all public agencies concerned with industrial issues, a business system that encourages firms to establish relationships with each other, and a technology institution to “trigger social dynamics, develop technology paradigms, and define innovation directions.” 6 A recent report on the Finnish innovation system has called for greater involvement by the Prime Minister’s Office in making innovation policy. Such efforts, the report states, should go beyond the chairing of the Research and Innovation Council by the prime minister (Ministry of Education and Ministry of Employment and the Economy 2009). 7 Greater collaboration between universities and industry has been one of Tekes’s policy imperatives (Srinivas and Viljamaa 2003). 106 Some Small Countries Do It Better Figure 4.1 Finnish Innovation System: Organizations and Coordination public sector Parliament policy makers government Science and Technology Policy Council Ministry of Ministry of other ministries Education Trade and Industry financing Academy of Tekes Sitra Finland operators universities polytechnics research institutes private sector business research funds foundations industry enterprises institutes and academic societies Source: Dahlman, Routti, and Ylä-Anttila 2006. Organisation for Economic Co-operation and Development countries) has made Finland one of the world’s most innovative nations and has fueled its growth for almost two decades. Tekes added value, not just by providing low-interest loans and grants for research, but also by expanding information channels and increas- ing information flows. It did so by developing international contacts and collabo- rative links with talented research teams in Finland and abroad and by convening seminars, study visits, and training programs. Sitra, founded in 1967 by the Bank of Finland with an endowment of FIM 100 million (approximately €700 million), morphed into a venture capital fund in the 1980s and helped pioneer venture capitalism. However, over the past decade, Sitra, which is independent of government control and has the leeway to engage in experimentation and to attempt to fix networking failures, has redefined its mis- sion to complement the activities of other parts of the innovation system. Sitra now sees its role as looking ahead, coming up with ideas for future urban lifestyles, and helping to design models of service delivery by working closely with private companies and other stakeholders. One example is the Low2No project in Governance and Growth 107 the Helsinki harbor area, a low-carbon initiative that is attempting to pilot a new approach to urban design. Sitra’s objective, like that of other similar organizations in Sweden (Vinnova) and Denmark (MindLab), is to encourage forward thinking and fuel innovation by catalyzing ideas and supporting commercial initiatives through partnerships and cofinancing (Ministry of Education and Ministry of Employment and the Economy 2009, 25). Ireland’s Industrial Development Agency was established as a branch of the Department of Industry and Commerce in 1949. When Ireland began casting around for a growth strategy with a focus on foreign direct investment (FDI) by multinationals, IDA emerged as the lead agency to target potential investors and market Ireland’s institutional advantages, location, and human resources. (See fig- ure 4.2 for the organizational configuration of the Irish innovation system.) IDA’s strategy, similar to that of Tekes, is grounded in Ireland’s perceived areas of comparative advantage—current or prospective—and is aimed at attracting investment into niches that could potentially house dynamic industrial clusters. To interest investors, IDA worked closely with Irish providers of infrastructure and skills. Bringing urban infrastructure services to world-class levels was one of the agency’s principal objectives. Improving and expanding the technical and soft skills of the Irish workforce was a second objective. Progress in these areas was vital to the success of IDA’s efforts at persuading multinational corporations (MNCs) to establish production and research facilities in Ireland and to house their regional headquarters in Dublin. Such progress was also essential to per- suade MNCs and other firms to steadily upgrade their activities so as to pull the Irish economy higher up the value chain. IDA’s efforts were reinforced by the Sci- ence Foundation of Ireland, which was created in 2000 to manage the €646 mil- lion Technology Foresight Fund. The fund’s purpose was to multiply the ties between the research and business communities in conjunction with the Pro- gramme for Research in Third-Level Institutions (UNIDO 2005, 81). In 2009, IDA’s expenditures amounted to €230 million, derived mostly from the exchequer and supplemented with funds from the European Union (EU) and sales of property (IDA 2009). The relatively modest outlay built organizational capabilities that enabled Ireland to emerge from obscurity to become the Celtic tiger economy, viewed as the equal of some of the East Asian economies, in a mat- ter of two decades. Singapore’s EDB, a statutory body formed in 1961, is the oldest of the three agencies and, arguably, has the strongest track record (figure 4.3). From as early as the 1960s, it was apparent to Singapore’s leaders that to thrive, the city-state needed a steady flow of FDI. Although its location was an enduring asset, Singa- pore could secure prosperity only by crafting a near-ideal business environment and the best-trained workforce in Southeast Asia. EDB’s mission was to engineer an efficient and low-transaction-cost environment and to work with other agen- cies and the education system to raise the quality of Singapore’s labor. Much like Tekes, EDB has looked ahead, consulted widely, and planned strategically with an Figure 4.2 Irish Science and Technology Structures 108 government Cabinet Commitee on Science and Technology National Competitiveness Council Chief Scientific Interdepartmental Committee on Expert Group on Advisor Science, Technology, and Innovation Future Skills Needs Science Advisory Council Enterprises Feedback Group Other government departments Department of Enterprise Department of Education with science and technology Trade, and Employment and Science budgets Health Research Higher Education Technology Ireland Group Research Group Forfa’s Higher Education Teagasc Authority IDA Irish Research Council Council for Forest for Science, and Engineering, Research and Development Enterprise and Technology and Irish Ireland Research Council for the Marine Institute Humanities and Social Sciences Science Foundation Ireland Health Research Board Environmental Protection Agency enterprise sector third-level sector Technology Ireland member organization Higher Education Research Group member organization Health Research Group member organization Source: EU Community Research and Development Information Service (http://cordis.europa.eu). Governance and Growth 109 Figure 4.3 The EDB Network Urban redevelopment A*STAR authority Spring Singapore International Enterprise Economic Jurong Town Singapore Development Board Corporation Singapore Tourism Ministry of Trade and Singapore Government Board Industry Information Source: EDB Singapore and Kumar and Siddique 2010. eye to the likely maturing and migration of existing industries and the need to replace them with industries further up the value chain. Each shock or crisis has further underscored the need for strategic thinking and a rapid response. EDB’s experience has demonstrated how well-resourced and experienced organizations with implementation skills can help a small economy forge ahead industrially in a highly competitive global environment by charting a strategy, serving as an inter- face between MNCs and local agencies, and acting to realize evolving strategic objectives by coordinating the delivery of skills, services, and capital to meet antic- ipated industrial demand. Singapore’s smoothly functioning economy is a tribute to EDB’s farsightedness and the intangible capital accumulated by this elite body. Institutions for Growth Sifire’s experience with institutions and development agencies illuminates and lends current relevance to the lessons that emerged from the Industrial Revolu- tion in Great Britain and that have been repeatedly reinforced in a variety of contexts. Institutions safeguarding property—physical and intellectual—and enforcing contracts have received due recognition. But technological advances, both radical and incremental, which are so integral to the process of development, have been significantly reinforced by other institutions.8 These institutions go a long way toward explaining the rapidity with which the Sifire countries were able to exploit technological possibilities and are available to other low- and lower- middle-income countries eager to harness the technologies that will unlatch the door to greater prosperity. Historians of science have underscored the importance of institutions that encour- aged and gave prominence to learning and to accretion of usable knowledge—what 8 Rodrik, Subramanian, and Trebbi (2002) maintain that quality institutions trump other determinants of growth. 110 Some Small Countries Do It Better Joel Mokyr (2002) has labeled “propositional knowledge”—about how nature works. The elaboration of this modern scientific knowledge was the province ini- tially of relatively small numbers of thinkers and discoverers, mainly in Europe,9 and, as we come closer to the present, of an international army of scientists, tech- nologists, engineers, and creative workers. The contribution of scientific knowl- edge and modern technologies to standards of living and the quality of life are now well understood, but many countries have failed to create the institutions to accumulate the knowledge capital that is the necessary stepping-stone to techno- logical advances. Such accumulation derives from the significance a society attaches to usable knowledge and to technological innovation of manifold kinds. It derives from the ways capital is built with the help of learned bodies; from incentives for and recognition of technological prowess; from the resources and effort a society devotes to improving the quality of education at all levels; from investment in research universities, think-tanks, and other institutes of learning; and from the garnering of a scientific culture in cities by staging events that engage people from all walks of life and that, in particular, captivate the imagina- tion of the young. The accumulation of knowledge capital can be severely handicapped in the absence of institutions that render a society open to new ideas from within and from other countries. Two centuries ago, when scientific activity tended to be more localized and the pace of change was slower, whether a society was open barely mattered. Now that a large number of countries are contributing to the sci- entific edifice and technological advance is a global pursuit, openness is vital not just to maximize the absorption of findings from elsewhere but also to allow the greatest freedom in how the fund of knowledge is to be manipulated, how new 9 Meisenzahl and Mokyr (2011) maintain that the British industrial revolution was the work of a small number of inventors, who were aided by the practical knowledge and innovativeness of a multitude of skilled craftworkers. Although Arabic science contributed substantially to mathematical, methodological, and scientific knowledge and, until the 14th century, was far ahead of science in Europe, Huff (1993, 62, 63) is correct in observ- ing that it “failed to give birth to modern science,” and “Arabic-Islamic civilization did not succeed in its march toward the development of this universal institution of modernity.” Huff (1993, 67) continues, “The rise of modern science was not just the triumph of tech- nical reasoning but an intellectual struggle over the constitution of the legitimating direc- tive structures of the West.... Intellectually, modern science represents a new canon of proof and evidence; institutionally, it represents a new configuration of role structures.” Shapin (1996, 164) makes a similar point when he remarks that “the more a body of knowledge is understood to be objective and disinterested, the more valuable it is as a tool in moral and political action.... That paradox is also a legacy of the Scientific Revolution, when disengaged scholars and gentlemen forged a body of knowledge that was enor- mously useful for theology and politics precisely because its practitioners advertised the boundaries between science and the affairs of the church and the state.” Governance and Growth 111 combinations will be tried, and how new ideas will be explored with globalization. The tendrilous reaching of the World Wide Web to the farthest corners of the world and the openness supported by protocols and rules governing web-based communication have rendered societies more porous than ever before. Knowl- edge flows more freely than at any time in the past. That this freedom is not seen in some quarters as an unalloyed good is also evident from the steps being taken in some countries to police the Internet. Nevertheless, the universe of knowledge and the dynamics of knowledge flows and accumulation have been transformed. On average, smaller resource-poor countries that are more dependent on close interaction and commerce with other nations have tended toward greater open- ness. For them, the shortest path to the accumulation of knowledge capital is to augment domestic investment in such capital by opening their windows and let- ting it stream in. Openness enlarges access to knowledge, but the efficient gathering of knowl- edge, its use, and the sparking of fresh ideas require the piecing together of networks. As the quantum of knowledge in every field has deepened and individ- uals have inevitably become more specialized, technology development, fresh discoveries, and problem solving of all sorts require greater teamwork (Adams 2004). Fewer technical papers are written by a single author as the complexity of products and services has risen, and the need for cross-disciplinary efforts has become essential in many cases. Not infrequently, novel solutions to knotty prob- lems come from individuals or teams working on widely separated research. Power of Urban Networks Small countries, where most of the population is concentrated in a few cities or, in the case of Singapore, a single city, enjoy the advantages of productivity augment- ing agglomeration (see Glaeser and Resseger 2009), ease of personal interaction, and—potentially—the creation of horizontal ties that germinate social capital. A high degree of ethnic and cultural homogeneity can further assist the process by contributing to the formation of social capital.10 With one-third of Ireland’s pop- ulation located in Dublin and one-third of Finland’s population living in Helsinki11 and in two neighboring cities of Espoo and Turku,12 the demographic 10 See Putnam (2007) on the effects of ethnic diversity on trust and the formation of social capital. 11 The Helsinki metropolitan area includes the cities of Espoo, Vantaa, and Kauniainen. A quarter of all Finns live in the Helsinki region, and eight of Finland’s 20 universities are located there, as are 70 percent of foreign companies with operations in Finland. 12 Turku, the former capital of the Grand Duchy of Finland, has built nutraceutical and pharmaceutical (therapeutic) businesses on the foundations provided by a food industry (Srinivas and Viljamaa 2003). 112 Some Small Countries Do It Better center of gravity in both countries is clearly demarcated. Each of the three coun- tries has a dominant ethnic majority that sets the cultural tone and puts its stamp on social institutions. Finland and Ireland were ethnically more homogeneous in the 1980s than was Singapore, and although both countries have absorbed large numbers of immigrants since, they remain less diverse. Urban demographics, “thick” sociocultural norms, and plentiful social capital are the foundations for networking. Through the 1990s, they have been reinforced by the diffusion of technologies that have enormously increased electronic com- munication and have stimulated greater face-to-face interaction in the urban environment.13 Networking builds on trust, and once networks jell, bonds are tested, and members gain in confidence, trust-based relationships grow stronger. Such connectedness and multistranded relationships are notable features of urban societies in Sifire, and it is important to understand how they have sup- ported development. Recall that in the 1980s, Finland, Ireland, and Singapore were middle-income countries, had already attained a measure of technological capability, and had established manufacturing bases. They were equipped to assimilate codified tech- nologies and needed to move beyond to begin absorbing the less codified or uncodified tacit knowledge on which depended the mastering of frontier tech- nologies. Making this leap required trust-based networking that created the chan- nels for sharing knowledge and encouraged collective effort at refining and extending this knowledge. In the process, new intellectual vistas and commercial opportunities would open.14 Networking served other purposes also. Sifire countries needed to mobilize and focus energies to realize their economic ambitions. Some countries mobilized through top-down pressures exerted by the organs of the state. Being small, open, and democratic societies, Sifire relied more on networks to arrive at objectives that commanded broad support. The exchange of views and ease of interaction was facilitated by the relatively egalitarian nature of the societies and the social proximity of the elites to the public. Social distances were small and permitted 13 Inkpen and Tsang (2005) stress the contribution of social capital to networking but also point out that networking exclusivity can interfere with the flow of knowledge from external sources not part of the network. Leamer and Storper (2001) refer to the impor- tance of face-to-face interaction and how information technology seems to encourage such exchanges. 14 The key message of the network view is that firms are not self-sufficient, and cooperation that leverages external resources can enhance a firm’s competitiveness. Harryson (2006, 93) states that a “network perspective aims at understanding the totality of relationships and how they jointly accomplish the result.... Organizations and large corporations can be regarded and analyzed as integrated networks of complex communication linkages, interdependent actors and activities, and cross-organizational/corporate flows of resources.” Governance and Growth 113 wide networking and engagement on major national issues. Networking proved effective when countries needed to extricate themselves from crises; it was also effective in building and maintaining economic momentum—at least for two decades. Absorbing technology to bring industry closer to international best practice and innovating to heighten competitiveness have become a multidisciplinary enterprise for the majority of industrial products. Whether they are part of the food sector, the machine-building sector, or telecommunications, firms and industries must marshal a variety of skills to solve problems and arrive at prof- itable innovations. Increasingly, firms, or project teams more generally, must seek collaborative arrangements with other parties and tap a number of sources of expertise. Preexisting or newly formed knowledge networks are a means of find- ing solutions. Such networks are more easily mobilized if the social environment favors relationships based on trust.15 Sifire countries proved resourceful in creating intraurban and intracountry networks, and they were also successful in linking with international networks. Globalization enlarged the scope for such networking, and information tech- nology has made it immensely easier to be connected. For smaller economies determined to develop rapidly and catch up with the technological leaders, inter- national networking quickly became essential, whether it was in securing trade opportunities and access to foreign markets, attracting FDI, discovering profitable overseas investment possibilities, or enhancing technology flows and building knowledge capital (OECD 2007). For Ireland and Singapore, the Irish and Chi- nese diasporas provided the basis for business networks that facilitated trade by providing contacts and serving as intermediaries to attract FDI.16 A common lin- gua franca—English, spoken in all three countries—made it easier to participate in global networks and, specifically, to network with U.S. companies and insti- tutions. Knowledge networking, crucial for speeding up technology acquisition 15 Shapin (2010) observes that science in particular relies on trust because only a small frac- tion of society can command the expertise to adequately comprehend the world of sci- ence. So the vast majority depends not on firsthand knowledge but on social categories and institutions that designate certain knowledge producers as trustworthy. The leaking of e-mails from the University of East Anglia’s Climate Research Unit was so damaging because it called into question the trust that was reposed in the scientific establishment studying the still deeply contested evidence on the extent and trends of anthropogenic global warming. The leaks, dubbed “Climategate,” destroyed the waverers’ trust in the integrity of scientists and confirmed the beliefs of those who have always thought that global warming was a myth. 16 An estimated 70 million to 80 million people worldwide can claim Irish ancestry, with the majority living in the United Kingdom followed by the United States. See Rauch and Trindade (2002) on the role of Asian business intermediaries. 114 Some Small Countries Do It Better and nurturing innovation, was aided by investments in education—in particular tertiary-level science, technology, engineering, and mathematics, as discussed in chapters 3 and 5—that were sufficient to absorb new technologies and manufac- turing practices at a rapid pace. The accumulation of high-quality knowledge cap- ital in the Sifire group during the 1990s and incentives to local institutions and firms to embark on research hooked these countries to globe-spanning knowledge networks that drive brain and idea circulation and make possible collaborative problem solving. Sifire countries were able to engage fruitfully with these net- works in an amazingly short time, partly because knowledge and technology were widely accepted as the stepping-stones to prosperity and partly because all three countries started from a higher threshold than the average low-income country. Finland and Ireland lagged the advanced Western European countries in the 1980s, and Singapore was some distance from Europe and Japan. But all three had built a human capital base by investing efficiently in education from the 1960s. Sifire’s competitors were also investing, but these three countries squeezed the extra mileage and showed themselves capable of speeds that eluded others. The critical elements of networking for the purposes of technological catch- up—acquiring the tacit knowledge so vital for technological upgrading and effi- ciency and achieving commercial success in domestic and export markets—are hard to distill into a recipe. It is one thing to render networks mathematically,17 yet quite another to explain in detail how social networks can be assembled. Net- works benefit from social capital and trust; they rarely form involuntarily but call for initiative, interaction, and exchange. They do respond to policy initiatives and incentives, and governments can take the lead in setting up networks, as the gov- ernments of Sifire did at various levels to promote manufacturing and technolog- ical capabilities. Small countries are under greater pressure to exploit the power of networks to arrive at a more complex and advanced economic structure or to risk being left behind in a more integrated world. 17 Graph theory provides a tool to analyze networks. 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Putnam, Robert D. 2007. “E Pluribus Unum: Diversity and Community in the Twenty-First Century—The 2006 Johan Skytte Prize Lecture.” Scandinavian Political Studies 30 (2): 137–74. Rauch, James E., and Vitor Trindade. 2002. “Ethnic Chinese Networks in International Trade.” Review of Economics and Statistics 84 (1): 116–30. Rodrik, Dani, Arvind Subramanian, and Francesco Trebbi. 2002. “Institutions Rule: The Primacy of Institutions over Geography and Integration in Economic Development.” NBER Working Paper 9305, National Bureau of Economic Research, Cambridge, MA. Shapin, Steven. 1996. The Scientific Revolution. Chicago: University of Chicago Press. ———. 2010. Never Pure: Historical Studies of Science as If It Was Produced by People with Bodies, Situated in Time, Space, Culture, and Society, and Struggling for Credibility and Authority. Baltimore, MD: Johns Hopkins University Press. Srinivas, Smita, and Kimmo Viljamaa. 2003. “BioTurku: ‘Newly’ Innovative? The Rise of Bio-pharmaceuticals and the Biotech Concentration in Southwest Finland.” MIT IPC Working Paper 03-006, Industrial Performance Center, Massachusetts Institute of Technology, Cambridge, MA. UNIDO (United Nations Industrial Development Organization). 2005. Industrial Develop- ment Report 2005: Capability Building for Catching-Up—Historical, Empirical, and Policy Dimensions. Vienna, Austria: UNIDO. 5 Delivering Quality Education Human capital contributes to growth, but educating more people does not cause growth or an increase in jobs, as many countries with legions of unemployed educated youths are discovering.1 If there is demand and companies perceive opportunities for profiting, then the availability of educated workers makes it easier for firms to expand production and encourages them to invest in addi- tional capacity. Thus, in the presence of demand—actual or latent—augmenting the supply of human capital has the potential to support a virtuous spiral of growth. Globalization set the stage for demand growth, which some countries were quick to exploit, with Singapore, Finland, and Ireland (Sifire) being among the enterprising few. Their efforts at penetrating international markets and servicing domestic demand were buttressed by favorable labor market developments. If all that the Sifire countries did was provide universal primary education and increase the percentage of students completing secondary schools, their suc- cess would be harder to account for.2 The average number of years of schooling 1 Even advanced countries with comparative advantage in knowledge-intensive activities are having a difficult time generating well-paid jobs for people with doctoral qualifications in science and technology fields (Cyranoski and others 2011). 2 As Hanushek and Woessmann (2009, 1) observe, “Schooling and human capital investments have been a central focus of development policy, but doubts have arisen as disappointments with results grow. Nowhere is this more apparent than in the case of growth policy, where schooling investments have not appeared to return the economic outcomes promised by growth models.” 117 118 Some Small Countries Do It Better of a country’s workforce has limited explanatory power in growth regressions. Sifire countries differ from the other low- and middle-income countries that expanded school enrollment in several respects. They were able to raise the average quality of the education imparted to ensure that a high percentage of secondary- and tertiary-level students had good science, technology, engineer- ing, and mathematics (STEM) skills and graduated with science and engineer- ing degrees3 and to see that a significant percentage of students—as high as 40 percent a year—received vocational training of relevance to industrial employers. Sifire further ensured that the average student performed at a higher level than students in most other countries. The Sifire countries were able to pull off this remarkable feat in a relatively short span of time and at costs comparable to or lower than those incurred by other Organisation for Economic Co-operation and Development (OECD) countries. One of the most intriguing findings reported in the growth literature is the contribution of education quality measured by international test scores of sec- ondary school students in math, science, and reading. Hanushek and Woess- mann (2007) find that the excellence of human capital is a potent explanatory variable in growth equations and an intuitively plausible finding.4 This finding is especially relevant for middle-income countries aiming at higher value-adding segments of markets for products or services and competing on quality, technol- ogy, and innovation.5 All countries gain when they improve the quality of educa- tion, but the boost to middle-income countries is arguably greater because they are the ones moving into more skill-intensive activities and are closer to the tech- nology frontier. The broad base and average quality of skills is one major deter- minant of economic performance. But Sifire derived additional mileage from the number and quality of the top-performing students—those with Programme for International Student Assessment (PISA) test scores above 625. The importance of the numbers of students in the upper tail of the student achievement distribu- tion is brought out by the comparative analysis by Pritchett and Viarengo (2010).6 It is supported by the findings of Hanushek and Woessmann (2009, 25), 3 In 2005, 23 percent of OECD students graduated with science and engineering degrees compared with 16 percent in the United States (Oxford Analytica 2006). 4 Using additional time series data and test score results, Appleton, Atherton, and Bleaney (2010) reaffirm the relationship observed by Hanushek and Woessmann (2007), although their estimated coefficients are smaller. 5 Dalia Marin (2008, 5) labels human capital as the “new stakeholder” in a firm that views talent, not plant and machinery, as the critical asset. 6 The quality of education in Finland added 0.5 percentage points to annual productivity growth during 1990–2003. See Honkapohja and others (2009). Delivering Quality Education 119 whose “estimates suggest that developing basic skills and highly talented people reinforce each other.”7 The Power of Quality Education How did the Sifire countries achieve the quality outcomes in education that eluded most of their competitors? Before tackling this question, note that Finland and Singapore have attained results superior to those of Ireland, as is clear from the data in chapter 3. The data reflect the overall focus of the policy and strategic commitment to upgrading the workforce. Also note that the Sifire countries have centralized school systems with curricula and standards established by education ministries. In Ireland, the Roman Catholic Church also has a hand in designing instruction on religion at the primary level. The state pays for education from pri- mary through university levels in Finland and Ireland,8 with the private sector playing a minimal role in Ireland. Singapore provides largely free primary and secondary schooling in state schools.9 Tertiary-level education is subsidized by the state. Private primary and secondary schools coexist with public schools in Ireland and Singapore. The exhaustive research on schooling has helped to narrow the factors respon- sible for student performance, but inevitably opinions remain divided.10 The experience of Sifire points to the importance of six factors. First, raising and sus- taining student performance at high levels are inseparable from nonschool factors such as family circumstances, the value a society attaches to education, and the 7 Hanushek and Woessmann (2009, 25) further observe that “achieving basic literacy for all may well be a precondition for identifying those who can reach ‘rocket scientist’ status.” Because many countries are well on their way to realizing the objective of basic literacy, there is now an urgent need to fatten the upper tail of the quality distribution, which is frequently underpopulated. Mexico, the country singled out by Pritchett and Viarengo (2010), is severely deficient in this regard. Only 0.29 percent of Mexican students who took the PISA test had scores in excess of 625 (the advanced benchmark), compared with 18.5 percent of students from the Republic of Korea and 6.5 percent of students from the United States. In other words, Mexico produces fewer than 6,000 students a year who fall in the advanced category. Even the Slovak Republic, a much smaller country, has a larger number of high-performing students. 8 Only students from the European Union qualify for free education. Students in Ireland must pay a registration fee. 9 There is a small copayment required at the secondary level. 10 Hanushek (2008) discounts factors such as school facilities and class size and singles out teacher quality, although identifying the determinants of teacher performance is difficult. Heckman, Carneiro, and Cunha (2004) also downplay school resources and school quality. 120 Some Small Countries Do It Better conviction that excellence is necessary for progress toward a better, innovative, and more prosperous society.11 It is not only small countries that are likely to seek high standards—there are plenty of examples to the contrary. However, smallness and ethnic homogeneity can lead to the coalescing of cultural norms that induce nations to try harder to progress in a competitive world.12 Second, quality needs to be pervasive, extending from the primary all the way to vocational and tertiary levels. Heckman and his coworkers (Cunha and Heckman 2007) have found that foundational capabilities instilled by the earlier stages of schooling, when children are three to six years of age, exert a strong influence on later cognitive as well as noncognitive development.13 Each level of schooling pro- vides the needed preparation for good performance at the next stage. Obtaining a high average scholastic performance for the student body demands that virtually all primary and middle school students be equipped with a threshold level of knowledge and skills and that every effort be made to shrink the left tail of the performance dis- tribution (Hanushek 2010; OECD 2010). Those lacking in scholastic aptitude need opportunities to acquire other useful skills by taking a vocational route. Third, student performance and the pursuit of excellence must continually be reinforced by family and social environments.14 The importance of parental input scarcely needs emphasizing. Better-educated parents and intact families are more effective in inculcating values that encourage learning and good study habits (Cunha and Heckman 2007).15 The surveys conducted as a part of Trends in International Mathematics and Science Study (TIMSS) show that student attitudes and motivation 11 OECD (2010) refers to the importance Confucian culture attaches to education but also notes that countries such as Canada and Finland are equally committed. Education qual- ity also promotes innovation (Varsakelis 2006). 12 Fernandez (2010) provides a compelling survey of the evidence pointing to the influence of culture on performance. 13 Lynn and Vanhanen (2006) present evidence showing how a country’s IQ scores are correlated with per capita income and also with overall economic performance. Their findings suggest that efforts to raise IQ levels of young children, with the help of a better home environment, nutrition, and early childhood education can have a handsome payoff. Cunha and Heckman (2007, 3–4) point to “critical and sensitive periods in the development of a child.... IQ scores become stable at the age of 10. And the later remediation is given to a disadvantaged child, the less effective it is.” 14 Gould, Lavy, and Paserman (2009) describe how immigrant children from the Republic of Yemen, placed in good socioeconomic environments in Israel, did better in school, married at a later age, and integrated better with the rest of society. The academic drift of students in the United States, as noted by Arum and Roksa (2011), may in part reflect a weakening of the learning environment in universities and in society more generally. 15 The higher the parental education level, the greater are the chances that one or both parents will keep a watchful eye on a child’s performance—and that of the school—and communicate with teachers about lapses or problems. Parental interest is as important a check on schools as is monitoring by public agencies. Delivering Quality Education 121 bear on their test results. This motivation derives from social mores stressing achieve- ment as well as from the expectations instilled by the family (Yusuf and others 2003).16 In societies where income and wealth are more equally distributed, social norms enjoy wider acceptance and there is greater uniformity of family circumstances and family values. More egalitarian societies also find it easier to reorient themselves in response to crises—or fresh opportunities—and to search for and adopt new social bearings in response to changes in the economic or political environment. Not very long ago, Confucian cultures were derided as dysfunctional and con- servative and as lacking the entrepreneurial and progressive attitudes emblematic of modern capitalist societies.17 First Japan, followed by the Republic of Korea and Taiwan, China, and most recently China, falsified these views. No society is too conservative to avoid change at any cost. The East Asian economies demonstrated that the more egalitarian and culturally homogeneous societies are quicker to shift tracks and to mobilize in support of new norms. Economically stagnant East Asian societies were transformed into tigers overnight when new leadership began mak- ing the case for a different strategy and reordering the rules of the game, complete with incentives and penalties. Much of the research and experimentation on how to provide quality education has been done in the United States, but the task of winnowing through the welter of conflicting findings to construct a coherent system on a nationwide scale has been left to other countries (see Hanushek 2010; Hanushek and Rivkin 2006). A fourth factor that influences student performance is teacher qualifications. Sifire set- tled early on good teachers as the vehicles for imparting the education and skills needed by a modern-day workforce.18 By setting high standards and expectations 16 Richard Posner (2011) has stressed the importance of education to instill civic values in a developing country’s youths—values that include honesty, respect for knowledge, toler- ance, and—of perhaps greatest importance—loyalty to national institutions. 17 Max Weber was the foremost exponent of this view, which he expounded in two famous books: The Religion of China (Weber 1951) and The Protestant Ethic and the Spirit of Capitalism (Weber 1958). 18 Recent research has confirmed the wisdom of the policy that singled out teaching capabilities as the key objective. Hanushek (2010, iii) calculates that in the United States the marginal gains of US$400,000 in the present value of earning would accrue to a student from a “teacher one standard deviation above the mean effectiveness.” Were the United States to replace the least effective 8 percent of teachers with average teachers, the country could bring student achievement close to that of Finland. “The estimates of growth impacts of bringing U.S. students up to Finland imply astounding improvements in the well-being of U.S. citizens. The present value of future increments to GDP in the U.S. would amount to $112 trillion” (Hanushek, 2010, 23). But Hanushek’s review of the literature also draws attention to how difficult it is to identify the measures that will make teachers deliver results (Hanushek 2010; Hanushek and Rivkin 2006; see also Goldhaber 2002). Another article (Economist 2011, 25) emphasizes the role of teachers and states, “Better teachers take much longer to form. They should be made the priority.” 122 Some Small Countries Do It Better for teachers and by steadfastly adhering to these standards, Sifire stiffened and rein- forced the social ethic underpinning the quest for excellence. There is no uniformity in the approaches to selecting and training teachers. However, all countries have var- iously used similar criteria. Teacher qualifications are pitched high—generally grad- uate-level degrees19—and the selection criteria are demanding, especially in Finland and Singapore.20 Teacher education and frequent in-service training to upgrade skills are seen as helpful for maintaining standards.21 A fifth factor is pay and prestige. To attract and retain some of the most talented in the teaching profession, Sifire offered competitive salaries and job security and used effective personnel management practices.22 Teaching in the Sifire countries has also been treated as a high-status occupation, with teachers enjoying considerable prestige in society (OECD 2010). That standing partially compensates for incomes that might be somewhat less than the highest offered by the market. Research reported by McKinsey Global Institute (2010) indicates that the best-performing education systems have drawn a proportionately larger number of teachers from the most able university graduates—those in the upper right-hand tail of the distribution. Finland, Ireland, and Singapore are among the countries that have filled the ranks of the teaching profession with some of the ablest graduates. Teacher performance appears to have been buttressed by rewards and social recognition (see Sahlberg 2011). The sixth factor calls for a measure of teacher autonomy in fine-tuning the cur- riculum and pedagogical techniques and in evaluating students. In this respect, Finland has given teachers the greatest latitude, and Finnish teachers devote less time to classroom instruction than teachers in the two other countries. Teachers in Singapore also enjoy substantial autonomy.23 Thus, nationally uniform curricula 19 All Finnish teachers must have at least a master’s degree. Hanushek (2010) notes, how- ever, that teachers with higher qualifications are not, on average, more effective than those with fewer degrees. 20 Singapore’s college administrators identify individuals they would like to draw into the teaching profession and offer them a variety of incentives to take up teaching. Singapore also offers teachers highly competitive salaries. 21 However, Hanushek (2010, 5) cites research showing that “even very intensive professional development to help teachers become more effective after they are already in the classroom has shown little impact on student achievement.” 22 Hanushek (2010) observes that the attraction of the teaching profession in Finland could not be because of high salaries. Research reported by Loeb, Kalogrides, and Béteille (2011) shows that successful schools selectively seek better teachers from the available pool and exert more effort at retaining them. Moreover, there is a virtuous cycle at work: a school’s performance in the past motivates improvement in the performance of teachers in subsequent periods. 23 An OECD (2010) report draws attention to the limited amount of time devoted to classroom lectures in the best-performing systems. Rather, teachers engage in group discussions and make every effort to draw out students and get to know their strengths and limitations so as to better assist them. Delivering Quality Education 123 and standards are combined with a freer hand at the school level, a practice that permits microlevel adjustments based on differences in teacher capabilities and the characteristics of students (on Finland, see Sahlberg 2011). In addition, this approach leaves room for experimentation. Careful selection of school principals in Singapore, recognition of merit, and rotation of principals among schools are part and parcel of the effort to raise the average quality of schools.24 In one important area of pedagogical technique, Finland and Singapore have diverged. Singapore, in keeping with practice across East Asia, has favored the rigor- ous drilling of students, a lengthy school year, and homework. Finland adopted a different tack: a short school year, little homework, fewer hours of instruction by the teacher,25 and greater independence for the student to pursue studies. Both approaches have produced outstanding scholastic outcomes in their respective social environments. Ireland is in between. Singapore worries that a highly structured approach that includes drilling risks draining students of creativity and analytic skills. However, Finland’s concern is that in the current milieu, with its numerous dis- tractions, students may slacken and turn away from the hard sciences, a trend visible throughout the world and notably in Ireland. The debate on how to combine perfor- mance and knowledge accumulation with creativity continues. Vocational Training In addition to raising the quality of general education, many industrializing coun- tries have struggled to make a success of vocational training. Such training is the appropriate path for students whose aptitude is for the practical and for working with their hands. Industry values not just good basic education but also practical skills suited for the majority of jobs. Unfortunately, cultural predispositions that shape parental preferences assign a lower ranking to vocational qualifications, and vocational school graduates often see themselves as a cut below those who have received general schooling. Moreover, few countries have been able to develop an effective system of vocational schools because such training is costly and needs to mesh with emerging market demands. The Sifire group is conspicuous in having crafted a system of vocational schools and polytechnics catering to between 24 Evidence showing that salaries motivate teachers and are reflected in the performance of students can be found in Figlio and Kenny (2006). On the issue of autonomy, it should be noted that Finland is moving away from tight central regulation and financing of the ter- tiary education system and is modifying university governance as well as financing struc- tures (Aarrevaara, Dobson, and Elander 2009). 25 A detailed analysis of the PISA 2006 data from 50 countries by Lavy (2010) revealed that the time devoted to instruction by teachers has a positive and significant effect on the test scores of 15-year-olds. Hence, the Finnish results might not carry over to other countries and cultures. 124 Some Small Countries Do It Better one-third and one-half of the post–primary school student body with the objec- tive of equipping graduates with marketable skills.26 As with general schooling, the vocational training outcomes have varied among the three countries, but they share four attributes. First, the quality of the instructors sets the tone. The ability to recruit better and experienced teachers is a hallmark of quality. Second, vocational schools need to be well furnished with adequate, up-to-date equipment so that students are trained on machines and software reasonably sim- ilar to the equipment they would encounter on the job. The cost of equipment and facilities makes vocational education more expensive than general education. Thus, sufficient financing from public and private sources is key to a viable system. Third, financing vocational training and structuring the system to deliver the mix of skills that could be readily absorbed require close collaboration with potential employers. Ministries of education, in consultation with businesses, must project future demand for skills and, on the basis of employer feedback, cor- rect deficiencies and consolidate strengths of vocational trainees. Such an effort entails information exchange, analysis, and coordination, not to mention contin- ual adjustments to training programs, to deliver market-conforming results. It is the nature of vocational training that employer involvement with and support for the system are crucial. In Sifire, this effort was facilitated by the proactive role assigned to key economic agencies, the smallness of the countries, and the cluster- ing of most businesses in just three or four cities—all of which made for ease of forecasting and responding to emerging market demands. Fourth, the efforts of governments would have come to naught if they had failed to convince parents and students of the value of vocational qualifications and how these burnished their job prospects. The Sifire governments realized early the necessity of backstopping industrial and growth ambitions with suitable training institutions to minimize the risk of skill shortages and mismatches. In European countries, the value of technical training has long been recognized; hence, government agencies in Finland and Ireland had a much easier time in augmenting and improving the vocational training system. Singapore had to overcome a deep-seated bias against vocational streaming that required the gov- ernment to launch an intensive and ongoing campaign of persuasion, to build expensive facilities, and to present evidence that the vocational path led to a rewarding career even under conditions of uncertainty and rapid economic change. 26 The longer-term benefits of vocational education for economies and individuals have been questioned by Hanushek, Woessmann, and Zhang (2011), who find that those with primarily vocational training found it harder to adapt later in life to technological changes and new work routines. Delivering Quality Education 125 Sustaining Consistent Performance As in every other country, education in the Sifire countries has its history of short- comings and problems—some corrected and others still demanding attention. Quality education that meets the market test with some consistency is difficult to deliver. The risk of sliding backward is omnipresent, as Germany, Japan, the United Kingdom, and the United States are finding. Increasing spending on edu- cation is rarely an answer, an inconvenient fact that advanced countries such as the United States have difficulty coming to terms with.27 Efficient investment is what counts (OECD 2010). Vested interests—especially teachers unions, where they exist—strenuously oppose change, and better test results do not immediately translate into improved economic outcomes. With technological change coming to be viewed as essential for sustaining growth, Sifire and other countries have increasingly attached a special significance to tertiary education and research. It was becoming apparent in the 1980s that the intensity of skill levels required by manufacturing and many service industries was on an upward trend, but few could predict how steep a trend it might be. Fewer still could anticipate how rapidly information technology would evolve, filter into every crevice of society, and demand new kinds of literacy and skills. Many countries were slow to acknowledge the cues and to prepare their universities for the leap in quality and content of education. The Sifire countries were among those that read the signs accurately, possibly because by the early 1990s, their leading sectors were among the most research and skill intensive. The first order of business for these countries was to increase the supply of uni- versity graduates with the technical skills likely to be in greatest demand and to ensure that their training conformed to the highest international standards.28 By enhancing supply and raising standards, the Sifire countries reasoned that they would be able to help their firms catapult into the front ranks of international business and persuade leading multinational corporations to relocate their pro- duction, their other functions, and eventually their regional headquarters and some of their research and development activities. To a surprising extent, Ireland and Singapore did achieve this objective. A world-class tertiary education sector was singled out as the long-term driver in a world where business people, econo- mists, and scientists identified innovative technologies as the principal means of growth. 27 Among the OECD countries, the United States spends more on secondary education than only two other countries—Austria and Switzerland—and obtains mediocre results. South Africa, also a high spender, has seen its performance deteriorate over the past decade (see Economist 2011). 28 Aghion and Howitt (1998) and Vandenbussche, Aghion, and Meghir (2004) have shown that the payoff to tertiary-level skills and research and development increases the closer a country moves to the technological frontier. 126 Some Small Countries Do It Better Sifire showed how university systems, modest in size and middling in capabili- ties and performance, could be scaled up and staffed with talented people in a short time and at a price these countries could afford. If done efficiently, expand- ing tertiary education need not be a formidable undertaking for a small country that proceeds strategically in manageable steps with the support of key stakehold- ers, that is willing to supplement a domestic teaching staff with overseas talent, and that is willing to pay market rates. A coordinated effort by government agen- cies with the backing of municipal bodies, universities, business interests, and property developers yielded prompt results that were soon reflected in the perfor- mance of the three countries. The universities in Sifire first set their sights on meeting actual and projected demand for well-trained graduates. Only after the initial objectives were being realized, did some universities begin pursuing research agendas in specialized fields. The quest for university and industry research links and the commercializa- tion of research findings is an even more recent departure.29 Whether universities in Sifire will become research powerhouses remains to be seen. Their global rank- ings do not yet point to burgeoning capabilities, although the Singapore authori- ties in particular have been signaling their ambitions to make Singapore a research hub in biotechnology. Undeniable are the staggering achievements telescoped into two decades that have created highly effective university sectors with a strong focus on STEM skills, which are among the most difficult and costly to inculcate. Starting Almost from Scratch: What It Takes In this context, three additional points deserve attention. First, none of the coun- tries started with a long-standing academic tradition. Finland and Ireland had small university sectors in the 1960s, and none of the universities were highly ranked. Hence, the subsequent growth of tertiary education was on the narrowest of foundations. Second, the three countries lie on the periphery of regional eco- nomic systems and away from the industrial cores of East Asia and Europe. Yet their location did not prevent a coalescence of talent once the tempo of economic activity began accelerating. The Sifire countries were able to groom local talent, retain most of the highly trained workers, and—in Ireland and Singapore— engineer a brain gain from abroad. Both of these factors are heartening, but they do suggest that growing the tertiary sector is predicated on accelerating industrial activity led by export-oriented high-tech activities with sound long-term prospects. Absent a deepening and dynamic industrial base and the buzz associated with high-tech activities that are demonstrating international competitiveness, it is 29 Earlier stages of development involved combining capital with less well-educated work- ers. Once the focus shifted to technological innovation, it became necessary to increase the supply of higher-level skills. Delivering Quality Education 127 difficult to envision the emergence of world-class tertiary-level institutions, sources of financing and the demand for skills, and a steady concentration of talent. Pri- mary and secondary schooling, combined with other ingredients, must initiate faster growth before a country can substantially augment tertiary-level skills and their quality and create the employment opportunities. The final observation is about the urban dimension of tertiary-level educa- tion and research institutions. World-class universities flourish in the principal cities. It can hardly be otherwise, especially in small countries. Establishing a major university would be difficult in cities with a population below a threshold of about 500,000 to 700,000.30 The better-known Finnish universities are in Helsinki, Turku, and Oulu.31 Irish universities of note are in Dublin, Galway, and Cork. Most of the jobs for university graduates are in cities that host clusters of industrial activity.32 The earlier point about industrial quickening preceding ter- tiary sector expansion and upgrading can be given an urban twist. The better institutions are in one of the main cities because the jobs, resources, new starts, and excitement are in those places, and the social and professional networks are more numerous, more dense, and more rewarding. If there is an urban agglom- eration strand to the Sifire story, it is a very minor one. Aside from Singapore, the cities of Finland and Ireland are midsized or small. The spectacular growth was localized, inevitably, and induced a concentration of talent that further perpetu- ated the narrow geographic focus of development. Progress on the institutional front enabled Sifire to push ahead with accumu- lating human capital, the driver of endogenous growth. The three countries dif- fered in the degree to which they could invest in the education system, but by focusing on the workforce, they all greatly improved the economic odds in their favor. Research on the contribution of human capital to growth has yielded equiv- ocal results; however, the progressive refinement of hypotheses and of their testing is providing clarification (see Aghion and others 2009). It is also helping to align 30 This is by no means an iron rule. Cambridge University, a research university ranked sec- ond in the world, has flourished in a city with a population of less than 120,000 (250,000 if the periurban area is included). Oxford University thrives in a city of 130,000. Many of the famous university towns in Europe are as small, if not smaller. However, most are adjacent to larger cities and benefit from their agglomeration economies. University scale remains a consideration, and Finland is taking steps to merge its 20 universities into fewer and more viable units (Aarrevaara, Dobson, and Elander 2009). 31 The University of Turku is Finland’s second-largest university, and the Turku University of Applied Sciences is the nation’s largest polytechnic. Oulu’s capabilities in electronics and information technology were built by the University of Oulu (Chakrabarti and Rice 2003). 32 Larger cities also stand a better chance of retaining students who come from elsewhere to study in their universities. 128 Some Small Countries Do It Better the role of human capital with the workings of endogenous growth models (see Lucas 1990; Romer 1989; Warsh 2006). References Aarrevaara, Timo, Ian R. 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Chakrabarti, Alok K., and Mark Rice. 2003. “Changing Roles of Universities in Developing Entrepreneurial Regions: The Case of Finland and the U.S.” MIT-IPC Working Paper 03-003, Industrial Performance Center, Massachusetts Institute of Technology, Cam- bridge, MA. Cunha, Flavio, and James J. Heckman. 2007. “The Technology of Skill Formation.” NBER Working Paper 12840, National Bureau of Economic Research, Cambridge, MA. http://www.nber.org/papers/w12840.pdf. Cyranoski, David, Natasha Gilbert, Heidi Ledford, Anjali Nayer, and Mohammed Yahia. 2011. “Education: The PhD Factory.” Nature 472: 276–79. http://www.nature.com/ news/2011/110420/full/472276a.html. Economist. 2011. “Reforming Education: The Great Schools Revolution.” Economist, September 17. Fernandez, Raquel. 2010. “Does Culture Matter?” CEPR Discussion Paper DP7965, Centre for Economic Policy Research, London. 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Loeb, Susanna, Demetra Kalogrides, and Tara Béteille. 2011. “Effective Schools: Demonstrating Recruitment, Assignment, Development, and Retention of Effective Teachers.” NBER Working Paper 17177, National Bureau of Economic Research, Cambridge, MA. Lucas, Robert. 1990. “On the Mechanics of Economic Development.” Journal of Monetary Economics 22(1): 3–42. Lynn, Richard, and Tatu Vanhanen. 2006. IQ and Global Inequality. Whitefish, MT: Washington Summit. Marin, Dalia. 2008. “The New Corporation in Europe.” Policy Brief 2008/07, Bruegel, Brussels. McKinsey & Company. 2010. “Closing the Talent Gap: Attracting and Retaining Top Third Graduates to a Career in Teaching.” McKinsey & Company, Washington, DC. OECD (Organisation for Economic Co-operation and Development). 2010. Strong Performers and Successful Reformers of Education: Lessons from PISA for the United States. Paris: OECD. Oxford Analytica. 2006. “R&D Moves to Developing Countries.” Oxford Analytica, September 25. Posner, Richard. 2011. “What Is a College Degree Really Worth?” Becker-Posner Blog, March 14. http://www.becker-posner-blog.com/2011/03/what-is-a-college-degree-really- worthposner.html. 130 Some Small Countries Do It Better Pritchett, Lant, and Martina Viarengo. 2010. “Producing Superstars for the Economic Mundial: The Team in the Tail.” VoxEU.org, August 20. http://voxeu.org/index.php?q= node/5422. Romer, Paul M. 1989. “Human Capital and Growth: Theory and Evidence.” NBER Working Paper 3173, National Bureau of Economic Research, Cambridge, MA. Sahlberg, Pasi. 2011. Finnish Lessons. New York: Teachers College Press. Vandenbussche, Jérôme, Philippe Aghion, and Costas Meghir. 2004. “Growth, Distance to the Frontier, and the Composition of Human Capital.” Department of Economics, Harvard University, Cambridge, MA. Varsakelis, Nikos C. 2006. “Education, Political Institutions, and Innovative Activity: A Cross-Country Empirical Investigation.” Research Policy 35 (7): 1083–90. Warsh, David. 2006. Knowledge and the Wealth of Nations: A Story of Economic Discovery. New York: W.W. Norton. Weber, Max. 1951. The Religion of China: Confucianism and Taoism. New York: Free Press. ———. 1958. The Protestant Ethic and the Spirit of Capitalism. New York: Charles Scribner’s Sons. Yusuf, Shahid, M. Anjum Altaf, Barry Eichengreen, Sudarshan Gooptu, Kaoru Nabeshima, Charles Kenny, Dwight H. Perkins, and Marc Shotten. 2003. Innovative East Asia: The Future of Growth. Washington, DC: World Bank. 6 The Message from Sifire An observer in the mid 1980s could not have imagined how much economic ground Singapore, Finland, and Ireland (Sifire) could cover by 2005. The three economies looked frail and their longer-term prospects seemed uncertain. Ten years later they were flying high, and over the course of another decade, they had gained admission to the club of high-income economies. A mere three years after that, in 2008, Ireland was in the grip of a severe crisis that threatened its hard-won prosperity and suspended a question over its economic future. This crisis resulted not from a failure of Ireland’s knowledge-based growth model but from a bank credit–fueled, highly speculative real estate bubble1 and the subsequent socializa- tion of the extraordinary liabilities of private banks by the Irish government (Portes 2011). Although Finland is recovering from the financial crisis of 2008 and 2009, its medium-term growth prospects appear less promising.2 Its flagship telecommunications company, Nokia, is losing global market share in the face of competition from nimbler rivals, which have been quicker to introduce cost, design, and product innovations—firms such as Apple, HTC, Huawei, RIM, 1 In 2006, at the height of the boom, construction accounted for almost a quarter of Ireland’s gross domestic product and employed close to 20 percent of the workforce. Between 1994 and 2006, the cost of an average home in Dublin rose by 500 percent (Lewis 2011). Lewis (2011, 184) claims, “The Irish real estate bubble was different from the American version in many ways: it wasn’t disguised, for a start; it did not require a lot of financial engineering beyond the understanding of mere mortals; it also wasn’t as cynical . . . in Ireland the big shots went down with the banks.” 2 In 2009, Finland’s gross domestic product fell by 7.8 percent because of a 24 percent drop in exports and a 13 percent decline in investment. This downturn was the worst ever experienced by Finland, and the economy has struggled to recover with investment remaining sluggish in 2011 (Oxford Analytica 2010a). See also HelsinginSanomat (2004). 131 132 Some Small Countries Do It Better Samsung, and ZTE. Meanwhile, biotech clusters and other traditional industries are unable to provide alternative engines of growth.3 Only Singapore is in good health, having recovered smartly from the financial crisis of 2008 and 2009 and having averaged a growth rate of 12 percent during 2009 and 2010. But with nonoil exports amounting to 75 percent of gross domestic product (GDP), Singapore is highly vulnerable to trade and currency wars and the retreat of globalization.4 The painful events that clouded the last three years of the “noughties” cannot diminish the remarkable economic progress by the three countries against consid- erable odds. Nor does the postcrisis slowdown detract from the relevance of their experience for ambitious low- and middle-income countries. This final chapter parses a few of the enduring lessons for late starters and the smaller middle- income economies and indicates how these lessons need to be tempered in light of recent shocks and the forces now pressing on the global economy. The experience of Sifire offers heartening evidence that quite simple recipes that are vigorously implemented can produce dramatic results when a country can take advantage of the winds of globalization to generate demand, acquire technology, and supplement domestic resources of human and physical capital. Sifire’s development over approximately two decades (extending from 1985 to 2005) underscores the potency of two sets of ingredients. One set comprises the development institutions that plan and implement economic policies and the public agencies and key private entities that, through their coordination and net- working capabilities, agree on and jointly pursue economic objectives. The second set comprises the elements of the learning and innovation system and the means of achieving desired quality standards. The Sifire countries also illuminate the role of investment by multinational cor- porations (MNCs). The foreign direct investment (FDI) story is part of the con- ventional wisdom on development. For late starters or, for that matter, any country, FDI in the productive sectors and in infrastructure can contribute pos- itively to growth through spillovers and links.5 Sifire demonstrated how a devel- opment strategy backed by efficient institutions and attention to the supply of quality talent underpinned the conventional menu of tax incentives and the provision of infrastructure and urban amenities. 3 Nokia’s share of the mobile handset market fell to 27 percent in 2011, and its ranking, according to Interbrand, fell to 14 from 8 in the previous year (http://worldwidegadget.blog spot.com/2012/01/2011-global-handset-market-share-nokia.html; http://www.interbrand .com/en/best-global-brands/best-global-brands-2008/best-global-brands-2011.aspx). On the potential of the biotech cluster in Helsinki, see Breznitz and Tahvanainen (2010). 4 This vulnerability became apparent in 2008, when exports began dipping sharply and the financial crisis tightened its grip, pulling GDP into negative territory in 2009 by 1.3 percent (Oxford Analytica 2008, 2010d). 5 Irish experience suggests that smaller foreign firms are more likely to partner with local firms (Görg, Hanley, and Strobl 2010). The Message from Sifire 133 Pragmatic Governance Sifire demonstrated that neither size nor geographic peripherality need pose insu- perable obstacles as long as the country is politically mobilized in support of a development strategy credibly tailored to its potential capabilities and buttressed by relevant international experience.6 Sifire also demonstrated tellingly that a sound strategy, good policies, and the capacity to leverage human resources could, with a bit of luck, serve as sufficient conditions for rapid growth. A close reading of the recent history of Finland and Ireland revealed that they are “normal” coun- tries displaying an average degree of social cohesion and discipline. Both are sub- ject to political give-and-take, are susceptible to slippages or outright failures of governance,7 and are led by parties and leaders who could not be accused of unusual enlightenment or farsightedness. Singapore, tightly managed by the People’s Action Party (PAP) since the 1960s,8 is closer to the model of the effi- cient, authoritarian development state, but from necessity, Singapore func- tioned as a highly open economy, albeit with an illiberal democracy.9 Openness checked the powers of the state and compelled it to win commitment to demanding policies by continuously demonstrating that it delivered the promised economic rewards. In Albert Hirschman’s (1970) terms, the citizens of the three countries could easily avail themselves of the exit option and, to vary- ing degrees, could also exercise voice. When the countries began stepping up the pace, they were much like other industrializing nations and far less well endowed with natural resources than many. Leveraging Global Markets and General-Purpose Technologies The winds of trade were beginning to blow strongly when the Sifire group began its dash to the top, and flows of FDI and of portfolio capital were also increasing in volume. The first was a source of demand, the second a source of productive investment, and both embodied technology and spillovers. Ireland and Singapore 6 Smallness and peripherality can constrain innovation because of “small world” problems arising from intense connectivity that homogenizes the material available to members and from excessive cohesiveness that leads to sharing common rather than novel information (see Uzzi and Spiro 2005). 7 These failures are glaring in Ireland’s case. See Foster (2008) and Lewis (2011). 8 Elections in 2011 led to a sharp decline in the popular vote for the PAP and point to dissatisfaction with rising inequality, in-migration, and the mode of government. 9 Illiberal democracy is a term coined by Fareed Zakaria (1997) to describe countries where regular elections are held but power is centralized and political opposition tightly controlled. See Mutalib (2000, 2003) and Rodan (2006) on the practice of democracy in Singapore. 134 Some Small Countries Do It Better exploited this situation to the full by using foreign capital to promote industrial development and the widening foreign markets to sell products. Finland also ben- efited from export demand and a smaller volume of FDI. In the 1980s, trade and capital were joined by a third growth driver—technology— as the electronics, Internet, and biotech industries began spreading their wings. The Sifire countries combined the power of all three sets of policies described in earlier chapters: • They created lead development and planning agencies and mechanisms for interagency coordination of objectives and of policies as well as mechanisms for consulting stakeholders in the business, financial, real estate, and education sectors. Lead agencies defined ambitious, albeit feasible, objectives. Most important, they helped strengthen the capability to implement policies and produce results. The critical early stage of development in the late 1980s and early 1990s involved accelerating growth using demand generated by exports and investment. This demand and the growth that followed fed savings and enabled Sifire to push human capital development to a higher plane. • Starting from a solid base of primary and middle school education, Sifire focused on boosting secondary and tertiary education by emphasizing quality and by promoting science, technology, engineering, and mathematics (STEM) and vocational skills. Chapter 5 discussed how quality objectives were realized within a matter of years. The increased supply of trained workers allowed busi- nesses, both local and foreign, to expand capacity. Businesses supported an upgrading of production technology, that enabled Sifire to take the lead in har- nessing information and communication technology (ICT), and they helped the countries advance toward technology frontiers in a number of major and rapidly evolving fields. In addition, businesses supported incremental innova- tion by combining advanced technical skills with vocational ones.10 The deep- ening of tertiary education set the stage for spillovers to industry through research, consulting, internships, incubators, and science parks. • Globalization, a thick shelf of technological possibilities, better governance and stronger implementation capabilities, effective networking, and an increased supply of human talent can contribute to growth. However, rapid growth is inseparable from the high levels of investment that supplement demand from other sources. Such investment is the primary vehicle for transferring technology and closing technology gaps until countries are ready to move to the innovation stage. Singapore, which has had the highest growth rates, also invested the most, combining domestic savings with FDI. Ireland had lower rates of domestic sav- ings and depended more on FDI and transfers from the European Union (EU). Finland, with more modest FDI flows, relied on domestic resources. 10 See the survey relating skills and work organization to innovation by Toner (2011). The Message from Sifire 135 Updating the Sifire Experience The relevance of all these factors for growth in the smaller lower- and middle- income countries remains pertinent. But looking forward, one sees a need to qual- ify some of the lessons from Sifire and to add a few more that are based on the experiences from elsewhere. The industrial drivers of growth in Sifire were ICT, biopharmaceutical, and resource-based products. The importance of the traditional industries should not be forgotten and is of particular relevance for lower-income countries. There is plenty of life and demonstrated scalability in these industries. However, capital- intensive productivity, by enhancing technological change, is measurably dimin- ishing the employment generated and is intensifying the skill requirements in both manufacturing and ICT based services (Brynjolfsson and McAfee 2011; Ford 2009). Furthermore, middle-income producers of ICT-based products are finding that once technological gaps in manufacturing have been erased, pushing the technology frontier through innovation is no easy matter. Small countries with narrow skill bases and specializations find it much harder to gain and sustain a technological lead on the strength of home-grown skills and companies. As Nokia has discovered, anticipating and responding to shifts in the global telecommuni- cation market can be challenging for a company that is not firmly tethered to the technology hubs in East Asia and North America. Nokia’s slide since 2008 high- lights the pitfalls for a company specializing in a narrow product range and the risks for a country that relies heavily on a single firm—or a few firms11—that has weak input-output (I-O) links with the rest of the economy for production, exports, and innovation.12 MNCs largely account for Ireland’s recent industrialization and for Singapore’s as well, but to attract the MNCs, both countries have had to offer a generous pack- age of tax and other incentives.13 Ireland’s efforts to repair its finances following the global crisis of 2008 to 2009 are affected by the low 12.5 percent corporate income tax rate, which MNCs view as indispensable to the viability of their 11 The Republic of Korea’s fortunes are tied to a handful of large conglomerates that domi- nate the export and technology sectors and exercise enormous political leverage. 12 Daveri and Silva (2004, 148) observe that “Nokia is relatively unconnected in the I-O sense with the rest of the economy. Finland’s greater reliance on the slower-growing EU and Russian markets might also be affecting its performance since 2008.” Similar worries regarding reliance on the technological prowess of one or a few firms have also surfaced in Korea in connection with the innovativeness of the smart phones produced by Samsung (Ihlwan 2010). 13 Honohan and Walsh (2002) stress Ireland’s low corporate income tax rates, grant assistance to MNCs, and freedom to repatriate profits, all of which have brought FDI into mature capital-intensive industries producing enormously profitable patented products (especially pharmaceuticals, microprocessors, software, and food products). 136 Some Small Countries Do It Better operations. FDI transfers technology, with vertical transfers being more com- mon than horizontal diffusion. This situation is a plus, but MNCs have con- tributed little to the creation and growth of indigenous firms in either Ireland or Singapore, and the banyan tree effect has been viewed by policy makers in these countries as a disadvantage.14 In fact, the Sifire countries lack a sufficiently dynamic small and medium-size enterprise (SME) sector, which can provide a seedbed for larger world-class firms and churn the business sector to continuously refresh the top tier of national firms (see Haltiwanger 2008). Other countries also lack dynamic SME sectors, including Malaysia and South Africa, both of which host numerous MNCs. Thus, the message on this score is equivocal: with the exception of the Republic of Korea; Taiwan, China; and possibly Finland, all the other late-blooming small economies have ridden the coattails of MNCs. For several countries, this route has been advantageous, but MNCs are unre- liable growth engines over the long term. They are continually scanning the horizon for less costly production platforms to enhance their returns. They are likely to absorb the cream of the local technical and managerial talent and often funnel out the best to their international operations. They are less likely to engage in fundamental research, preferring to limit themselves to adaptation of products for local markets and some applied research and testing. MNCs prefer to rely on technology transfers from their core research centers and on the trusted suppliers with a global reach. They do not actively assist the coun- try in building indigenous entrepreneurship or augment the flora of local firms. The problem for many late-starting countries is that in a world straddled by buyer- or supplier-controlled value chains (Gereffi 1996, 2001), countries need large MNCs, whether home grown or foreign, to link with these chains and estab- lish a foothold in the global market. But MNCs can be unreliable partners over the long haul, especially for countries with small domestic markets.15 Large economies such as China and India are the ones most attractive to MNCs, even in relation to the advanced Western ones, because their size and growth prospects hold the most promise. Moreover, these countries are creating their own MNCs and building up research capabilities that rival those of the advanced economies, with the benefit of wages of technical workers that are a fraction of those in Sifire or, for that matter, in the United States. 14 The banyan tree effect occurs when MNCs favor their own traditional suppliers, tend to absorb a lot of the best local talent, and are quick to take over promising local start-ups, with the result that the local SME sector does not become dense. But see footnote 6. 15 A consolidation of value chains is tightening the links among current participants but threatens to further marginalize potential suppliers on the periphery (Canuto and Salazar 2010). The Message from Sifire 137 Under these circumstances, an effective central planning and coordinating body can build a favorable investment climate and orient economic activities to maximize the growth potential deriving from productivity and technological change. Parallel attention to policy implementation capabilities enhances the speed of response. Sifire’s recovery from crises in the 1980s and performance through the 1990s highlight the quality of government. Sifire seized opportunities and grew because the three countries had begun crafting the institutions and net- works essential to the conduct of effective policy. By empowering these institu- tions and using networks, governments were able to pursue objectives with the coordinated support of key stakeholders. Rapid and efficient implementation of policies creates a virtuous spiral. People can see that public agencies are delivering on their promises; they can see positive results. Such a climate legitimizes govern- ment, adds to political capital, and energizes as well as expands networks within the country. Public sector efficiency and national economic performance also build an international reputation—they embellish the country’s brand—thereby providing an inducement for foreign businesses. In just a decade, the Sifire countries were being touted as economic icons— small resource-poor countries that had elbowed their way forward by dint of clever policy making and systematic application of human talent. The global crisis of 2008 to 2009 and subsequent decline in economic performance have revealed flaws and gaps in the Sifire model. For example, in Finland, coordination across ministries and the involvement of the Finance Ministry in innovation policy mak- ing are deemed inadequate, the procedures for evaluating programs lack sufficient independence and objectivity, and high-tech start-up activity and scaling up of SMEs falls well short of expectations. Such gaps do not diminish the attractiveness of the model; they only show that, as with everything, there is always room for improvement. Crises shine a spotlight on weaknesses and create an opening for reforms. Almost all late starters have their own planning agencies, but all too frequently these agencies do not muster much political clout, technical expertise, or adminis- trative leverage. In some cases, for legacy reasons, a moribund agency can be diffi- cult to revive and endow with substantial authority and technical capabilities. But given the political will, bringing such agencies to life is by no means impossible. Much depends on who is appointed to head the agency and the connections that person has with other key players in the economic hierarchy and the country’s leadership. The success of planning bodies in Taiwan, China, rested on the stand- ing and influence of the people who directed economic management in the 1970s and 1980s. There are risks associated with vesting too much power in a single agency, because it can aggressively pursue misguided objectives and silence criti- cism. There are plenty of instances from around the world of this problem occur- ring, including in Indonesia and Korea. However, given the options, which are few, attempting to create a lead agency and building that agency’s technical, coor- dinating, and implementation capabilities are good bets. 138 Some Small Countries Do It Better Quality of Human Capital Human capital of high quality emerged as one of the principal drivers in Sifire, but only after the policy-making institutions and networks had begun gaining traction. These policy makers defined the goals for the education system and served to mesh the workings of schools and universities with the rest of the econ- omy. Undoubtedly, the smallness of these three countries and the concentration of most of the training facilities in a few cities magnified the power of networks, thereby making it easier to devise as well as implement policies. Finland and Singapore have shown that there are different roads to a quality education, but teachers and their incentives are central to both countries, as is the culture of excellence in motivating parents, students, and schools. It is unclear whether a centralized school system, free schooling, school autonomy, time devoted to instruction, and a large volume of homework were important in them- selves, though in some combination these conditions may have reinforced the effectiveness of teachers and of the learning systems.16 Aiming for a high average level of quality for the student body and instilling basic scientific literacy enhanced the productivity of the workforce, as did the successful inducing of a high percentage of students to study science and engineering. Having put the schooling system on a sound footing, Sifire showed tremen- dous initiative in expanding tertiary institutions without compromising quality.17 The big test was to find staff members of sufficient caliber for the newly created universities and polytechnics. Some of the best graduates had to be persuaded to become teachers and researchers, which meant paying high salaries, providing an attractive well-equipped work environment, and according faculty social recogni- tion. This same challenge faces late starters in South Asia and in Sub-Saharan Africa. Before the 1980s, Sifire had made some progress toward modern learning systems. However, the conditions prevailing in the 1980s—the crises, globaliza- tion, technological revolutions, the implosion of the Soviet Union, and so forth—prompted strategic rethinking in Sifire, stoked economic activity, and underscored the imperative of a world-class learning economy. Looking ahead, one finds that the role of learning and research to drive innova- tion is undiminished; if anything, future growth is more tightly linked to produc- tivity gains deriving from education. But the Sifire countries will have a hard time 16 See the discussion of decentralized school management and teacher incentives in Bruns, Filmer, and Patrinos (2010). 17 International experience—mainly U.S.-based—suggests that universities are more productive when they have greater autonomy and are exposed to competition (Aghion and others 2010). See also the survey of findings in Yusuf, Saint, and Nabeshima (2009). Universities in Sifire were exposed to some competition from local and overseas institutions, but probably to a lesser degree than occurred in the United States. The Message from Sifire 139 sustaining all but very high-end manufacturing activities in the face of competi- tion from Asian countries. Tradable services are becoming exposed to equally intense pressure from overseas suppliers. In response, Singapore is actively diver- sifying its productive base, attempting to hold on to as many manufacturing industries as it can while promoting other activities—mainly high-value services and tourism.18 Finland and Ireland need to follow suit. To successfully diversify into other high-value adding activities, Sifire countries will need to reshape their learning systems to sustain math and science skills while helping students improve their noncognitive skills and become more creative. The advent of the Internet and social networking has created an immensity of electronic noise and innumer- able diversions that are dividing the attention of students and eroding disciplined study habits and interest in sustained reading. This electronic noise also makes it difficult to deepen writing skills. Teachers have to strive harder to convey the “process of science”; the “deep connections between the core disciplines of physics, chemistry, and biology”; and the “excitement and beauty of the scientific view of how the world works” (Lederman 2008, 399). The Internet, video games, and television are helping to develop the visual intelligence of young people, but at the cost of other cognitive skills. The “cost seems to be deep processing: mind- ful knowledge acquisition, inductive analysis, critical thinking, imagination, and reflection”—attributes that society needs more than ever (Greenfield 2009, 71). To accommodate the shifting demands of employers, training institutions are having to use greater foresight to ascertain the future composition of desired skills and adjust their course offerings accordingly to minimize skill mismatches. The significance of feedback from employers and of networking is becoming greater than ever, although the willingness of footloose MNCs to invest in local human capital and innovation systems is questionable. With accumulating knowledge, the STEM disciplines are steadily becoming more demanding in terms of the quantum of knowledge that must be assimilated and the analytical skill required to solve complex problems. Consequently, fewer tertiary-level students are willing to invest the time and effort. The percentage of students majoring in science and engineering is declining in Sifire countries as it is almost worldwide. This trend risks weakening hard-won technological and inno- vation capabilities. To reverse the trend, government and businesses will have to redouble their joint efforts to shore up incentives (including incentives to finance training) and to provide rewarding career prospects to people who graduate with science and engineering degrees. The steady buildup of knowledge in every disciplinary field and the interdisci- plinary content of many products and services mean that all but the very largest 18 The Marina Bay Sands Casino, which was built at a cost of US$5.5 billion (the second most costly complex of its type in the world), represents Singapore’s efforts to diversify. Built by Las Vegas Sands Corp., the complex reaffirms the role of FDI in the services industry. 140 Some Small Countries Do It Better countries must necessarily specialize. Firms and researchers need to network and collaborate with their counterparts in other countries, thus exploiting the open global innovation system. Ireland’s attempt to reignite the growth of Silicon Dock in Dublin, Finland’s struggle to remain a world-class supplier of telecommunication equipment, and Singapore’s ongoing efforts to become a biotech hotspot19 high- light the challenge for small countries far removed from the established centers of excellence to carve out a place for themselves. At the same time, Singapore has demonstrated its ability to attract world-class researchers20 to its recently estab- lished biotech research center and enlarge its tertiary education system in partner- ship with leading European and U.S. universities. This example shows how late starters can tap the pool of international knowledge workers to augment and groom local talent.21 Late-starting countries confront even sterner challenges, which could be compounded by a weakening of globalization or if globalization takes a different turn in a multipolar world. Stevens, Miller, and Michalski (2000, 16) caution that globalization could widen social differences: Globalisation’s dependence on and reinforcement of differences is at the origin of much concern about its social consequences.... First,... the world has no mechanisms that enable those who win because of change to compensate those who lose. Secondly, and this difficulty is related to the first, without the infrastructure needed to overcome exclusion there is a great risk that globalisation’s social heterogeneity will turn into destabilisingly high levels of fragmentation and polarization.22 Implications for African Countries Small, resource-poor economies may need to try harder, but firmly adhering to a high-growth strategy and creating the governance institutions, human 19 See Normile (2002) for a listing of the measures Singapore had taken to create an infra- structure of institutes supporting training and hospital facilities and to attract foreign researchers and companies. 20 Most of the principal researchers at the Institute of Molecular and Cell Biology, created in 1987, were recruited from overseas. 21 Singapore began building Biopolis—a bioscience city—and the Tuas Biomedical Park in 2003. Although several MNCs have set research facilities in the space provided, there is as yet little evidence that Singapore is on the way to creating a cluster rivaling Medicon Valley in Denmark, much less the clusters in Boston and San Diego. See Normile (2002) and Yusuf and Nabeshima (2006). However, Singapore has aggressively pursued the development of additional science parks with the building of Fusionopolis to spur multimedia-related businesses. The latest initiative is One North, a 200-hectare park for biomed, IT, and multimedia companies that is visualized as the axis of Singapore’s science hub (Engardio 2009). 22 Kemeny (2011) notes that the technology gap between the most and the least developed economies grew between 1972 and 2001. The most sophisticated economies may continue to pull further away from the least, thereby setting the stage for greater polarization along several axes. The Message from Sifire 141 capital, and urban-industrial-research networking such a strategy entails is a proven way forward. The scope for technological catch-up offers the opportu- nity, and an efficiently governed learning economy provides a means of closing the gap. The Sifire countries provide a model of compressed development. Proven alternatives are difficult to identify from cross-country experience spanning the past half-century. However, as with any strategy, the Sifire model will need to be adapted by late starters to account for changed global condi- tions and unique country circumstances. African and other low-income economies in search of ways to accelerate growth must, at the minimum, fac- tor in the following: • Sifire transitioned toward the phase of rapid industrialization and growth from a more advanced level of development than many of the current low-income countries. The Sifire group’s industrial capabilities in the 1980s were of a higher order, as was the group’s human capital. The Sifire countries were better prepared to absorb technology and to exploit advances in scientific knowledge. And they already had a stratum of well-educated people from which to recruit the teachers needed to nurture technical skills. • Globalization, the electronics and the information technology (IT) revolu- tion, and the offshoring of industry from the United States and other advanced countries favored all three countries to varying degrees. Now entry barriers to the electronics and IT sectors are higher for newcomers. Late- starting countries need to quickly muster substantial manufacturing and technological capabilities if they are to compete on the basis of price and quality with seasoned suppliers who already enjoy cost and learning advan- tages.23 These advantages accrue from links with established value chains. The speed at which products are imitated and rents competed away is also a handicap for newcomers hoping to carve out profitable niches. For a wide range of manufactured products, the barriers to entry for existing producers are now quite low, and this ease of diversification raises the odds against newcomers. • The Sifire countries did not confront the challenges posed by competition from China and, to a lesser extent, India through much of the 1990s. They faced competition from other countries, but it was nowhere near as fierce as the threat Chinese manufacturers and Indian IT service providers now pre- sent. Some research suggests that the development of skills in African coun- tries may be inhibited by the import of skill-intensive products, which slow the indigenous upgrading of production and maintain, if not widen, the income divergence between Sub-Saharan Africa and the rest of the world (Auer 2010). 23 For a number of industries, wage costs are dwarfed by other costs eroding the advantages bestowed by low-wage labor. 142 Some Small Countries Do It Better • Energy and resource scarcities24 and environmental concerns were not as pressing or inhibiting to growth. • Global growth prospects were robust even though the economic performance of Sub-Saharan Africa and Latin America was lagging. Demand from the advanced countries was strong and became stronger in the 1990s.25 Following the global crisis of 2008 to 2009 and the longer-term adjustment imperatives of major economies in the Organisation for Economic Co-operation and Devel- opment, global demand for the exports of industrializing countries could be significantly weaker.26 At the same time, the performance of Sub-Saharan Africa is much superior to what it was in the 1990s. GDP rose by an average of 4.9 percent a year between 2000 and 2009, the future prognosis is more positive than in the 1990s, and portfolio and FDI are flowing to the continent (see McKinsey Global Institute 2010). But the performance remains a function of strong and rising prices of raw materials and investment in infrastructure to develop these resources. The domestic beneficiation of mineral resources remains low even in relatively industrial nations such as South Africa. Although South-South trade is picking up, with Sub-Saharan Africa exporting more to China, the technology level of these exports is lower than that of the exports by African countries to the West. These changed circumstances, if anything, enhance the attractiveness of the Sifire model for late starters and middle-income countries: the importance of technology as a driver of growth has risen, and so also has the skill intensity of technologies. Absorbing and fully harnessing technologies makes it essential to aim high in building a learning economy. Late starters can also usefully reconsider the approach to innovation by focusing on cost innovation and aim- ing for lower-income buyers closer to the bottom of the pyramid. With the 24 Opinions vary on this issue, with one side pointing to the disparities between the growth trend in the supplies of fuels (and net exports of oil and condensates) and other minerals and the growth in demand, especially from industrializing Asian countries. The other side points to long-term stable or declining price trends and technological advances that con- tribute to the elasticity of supply and provide substitutes for resources as they grow scarce. 25 The East Asian crisis of 1997 to 1998 and the deflating of the dot-com bubble slowed, but did not derail the growth of the three economies. 26 The overhang of fiscal and trade imbalances bedeviling several of the major economies threatens a slowing or partial reversal of globalization (Oxford Analytica 2010b). As long as essentially short-term political calculations prevent governments from taking ultimately unavoidable action, the future of globalization will remain clouded. Hufbauer and Suominen (2010) point out that climate change and national security are compounding the threat. The Message from Sifire 143 fastest-growing markets now located in industrializing countries such as China and India and in regions such as Southeast Asia and Sub-Saharan Africa, low- tech innovation27 could offer better market prospects in an era of increasing South-South trade and be more attuned to the capabilities of late starters.28 Thus a more creative approach to innovation is called for—not necessarily the one adopted by Sifire. Also, unlike Sifire countries, which invested very little in research and development (R&D) during the 1960s and 1970s, the late starters may need to complement investment in tertiary education with incentives for R&D to improve the quality of higher-level skills, speed up the assimilation of technology, and lay the groundwork for indigenous innovation. Ireland, which has devoted far fewer resources to R&D than have Finland and Singapore, is now paying the price for neglect.29 By absorbing technologies faster and build- ing capacity for innovation, late starters can begin to broaden their capabilities. These capabilities will be vital for diversifying their economies and climbing out of low-level industrial and primary production traps (Hausmann and Hidalgo 2010). Countries in Sub-Saharan Africa may need to explore the scope for inno- vating in services, where the opportunities might be richer, easier, and cheaper to commercialize and also easier to scale up.30 The smallness of these countries will necessarily will mean that they must start by combining teaching and research and by focusing resources and talent on a few promising areas until more trained personnel are available. International institutions and major for- eign universities might provide some support, but experience suggests that this assistance will be minimal. Countries will have to be more self-reliant. A big change from the 1990s may be that South-South trade, capital, and tech- nology flows become far more important and faster growing, with countries such as China emerging as major importers and suppliers of capital and technology.31 27 Such innovation is off to a slow start in Africa. In the area of health, for example, identi- fying new drugs, medical devices, and equipment is proceeding slowly with little com- mercialization, partly because of the shortage of venture finance (Simiyu, Daar, and Singer 2010). 28 Although frequently touted, the so-called inclusive low-tech innovations targeting the poor are few in number and are insufficiently scalable. Moreover, these innovations have attracted little venture financing and have yet to demonstrate their macroeconomic potential. See Oxford Analytica (2010c). 29 Ireland is seeking to protect its research budget from the draconian cuts of expenditures forced by the financial crisis (Gilbert 2010). 30 Innovation in services might benefit from the “open” approach proposed by Henry Chesbrough. See Chesbrough (2011) for many illuminating examples of pathways to innovation in services. 31 As discussed previously, Sub-Saharan Africa’s exports to China consist of commodities and semiprocessed products, and imports of low-cost Chinese manufactures confront local producers with severe challenges. 144 Some Small Countries Do It Better This factor will undoubtedly affect development strategy,32 industrialization, the export mix, and technological development. Only time will tell whether, on bal- ance, this shift in the global economic center of gravity will be good for late starters. Despite how globalization evolves, small economies in Sub-Saharan Africa, would benefit from access to a Pan-African market with few barriers. Finland and Ireland gained from the formation of a common market. The gains to all mem- bers of the EU would be even greater today if the plethora of laws, standards, tax codes, and intellectual property rules were replaced by uniform institutions.33 For Africa, market integration is a long-running project, but it is a project that is tak- ing on more urgency as the world economy steers into uncharted waters. As Michael Porter (1998) noted in The Competitive Advantage of Nations, the size and sophistication of markets profoundly stimulate both competitiveness and innova- tion, thereby forcing firms to upgrade and offer new and higher-quality products. The greater the willingness of consumers to demand and to use new products is, the greater the incentives for firms to satisfy these demands will be.34 Whether countries hew to a Sifire-type strategy or choose a different approach, the outcome will be crucially linked to design, planning, institutional architecture, and implementation. The efficacy of these elements will be affected by governance mechanisms.35 In part, such mechanisms are a function of domestic politics, about which this book says little. But the Sifire countries have much to teach developing countries about how to enhance the efficiency of governance institu- tions, how to contribute to productivity and innovation by harnessing IT, and how to avoid some of the pitfalls. A small example must suffice: Finland has taken the lead in introducing electronic invoicing to eliminate a vast number of costly 32 References to the still-nebulous Beijing Consensus and the revival of interest in industrial strategy suggest that the developmental state might be back in favor, although it could be a softer and more flexible state than the rigid type that is so much a part of East Asian leg- end. If so, the Sifire experience could provide useful pointers. 33 This situation is spelled out in the call for a single market contained in a report prepared for the European Commission by Mario Monti (2010). The prospect seems even more distant in 2012. 34 Bhidé (2006) ascribes the innovativeness of U.S. firms to the venturesome behavior of consumers and the vast U.S. domestic market. 35 One indicator of governance that emerges from the World Bank’s Doing Business survey is not encouraging. The latest report (2011), which is available at http://www .doingbusiness.org, shows that of the 50 lowest-ranked countries, 32 were from Sub- Saharan Africa. Of these 32, 15 had experienced a decline in their ranking over the preceding year. According to a second indicator, the Afrobarometer, which is available at http://www.afrobarometer.org, satisfaction with democratic performance diminished in the 11 countries tracked by the surveys from 1999 through 2008. See Gilley (2010). The Message from Sifire 145 paper transactions and to facilitate a variety of transactions, from shopping to the payment of pensions. Finnish mobile phone operators are issuing individuals with electronic IDs that can be used for a wide range of purposes. These innova- tions will feed into Finland’s bottom line through productivity, and they will do so more speedily if the population is better educated. References Aghion, Philippe, Mathias Dewatripont, Caroline M. 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Zakaria, Fareed. 1997. “The Rise of Illiberal Democracy.” Foreign Affairs, November– December. Appendix A Table A.1 Ghana’s Top Five Exports 1996 2007 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Beans, whole or 748 PP Gold, nonmonetary 1,459 LT2 broken, raw Gold, nonmonetary 740 LT2 Beans, whole or 896 PP broken, raw Wood of nonconiferous 212 RB1 Wood of nonconiferous 154 RB1 species, sawn species, sawn Wood, sawn lengthwise, 169 RB1 Cocoa butter and cocoa 148 PP sliced or peeled paste Cocoa butter and cocoa 115 PP Wood, sawn lengthwise, 73 RB1 paste sliced or peeled Source: United Nations Commodity Trade Statistics Database. Note: LT2 = other low-technology products; PP = primary products; RB1 = agriculture-based products. Table A.2 Kenya’s Top Five Exports 1995 2007 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Tea 362 PP Tea 698 PP Coffee, whether or not 292 PP Cut flowers and foliage 390 PP roasted Cut flowers and foliage 68 PP Other fresh or chilled 232 PP vegetables (continued on next page) 149 150 Some Small Countries Do It Better Table A.2 (continued) 1995 2007 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Other sheets and plates 66 LT2 Coffee, whether or not 165 PP of iron roasted Fruit, otherwise 54 RB1 Cigarettes 94 RB1 prepared or preserved Source: United Nations Commodity Trade Statistics Database. Note: LT2 = other low-technology products; PP = primary products; RB1 = agriculture-based products. Table A.3 South Africa’s Top Five Exports 1996 2007 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Beans, whole or 748 PP Gold, nonmonetary 1,459 LT2 broken, raw Gold, nonmonetary 740 LT2 Beans, whole or 896 PP broken, raw Wood of nonconiferous 212 RB1 Wood of nonconiferous 154 RB1 species, sawn species, sawn Wood, sawn lengthwise, 169 RB1 Cocoa butter and 148 PP sliced or peeled cocoa paste Cocoa butter and cocoa 115 PP Wood, sawn lengthwise, 73 RB1 paste sliced or peeled Source: United Nations Commodity Trade Statistics Database. Note: LT2 = other low-technology products; PP = primary products; RB1 = agriculture-based products. Table A.4 Rwanda’s Top Five Exports 1996 2007 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Coffee, whether or not 4 PP Ores and concentrates 43 RB2 roasted of other nonferrous base metals Tea 1 PP Tin ores and 39 RB2 concentrates Motor vehicles for 1 MT1 Coffee, whether or not 32 PP transport of goods roasted Tin ores and 1 RB2 Tea 30 PP concentrates Calfskins, raw (fresh, 1 PP Passenger motorcars, 4 MT1 salted, dried) for transport Source: United Nations Commodity Trade Statistics Database. Note: MT1 = automotive products; PP = primary products; RB2 = resource-based products. Appendix A 151 Table A.5 Zambia’s Top Five Exports 1995 2007 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Copper and copper 856 PP Copper and copper 2,257 PP alloys, refined or not alloys, refined or not Cotton yarn 30 LT1 Copper and copper 1,023 PP alloys, worked Copper and copper 28 PP Copper ores and 256 RB2 alloys, worked concentrates; copper matte Electric current 26 RB2 Semimanufactures of 249 LT2 tungsten, molybdenum Sugars, beet and cane, 17 RB1 Sugars, beet and cane, 82 RB1 raw, solid raw, solid Source: United Nations Commodity Trade Statistics Database. Note: LT1 = textiles and fashion products; LT2 = other low-technology products; PP = primary products; RB1 = agriculture-based products; RB2 = resource-based products. Table A.6 Costa Rica’s Top Five Exports 1996 2009 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Bananas, including 687 PP Parts and accessories 857 HT1 plantains, fresh of data-processing equipment not elsewhere specified Coffee, not roasted or 417 PP Monolithic integrated 663 HT1 decaffeinated circuits, digital Pineapples, fresh or 59 PP Bananas, including 448 PP dried plantains, fresh Raw cane sugar, in 46 RB1 Pineapples, fresh or 445 PP solid form dried Melons and 46 PP Needles, catheters, 378 MT3 watermelons, fresh cannulae, and so forth (medical) Source: United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; MT3 = engineering products; PP = primary products; RB1 = agriculture-based products. 152 Some Small Countries Do It Better Table A.7 Jordan’s Top Five Exports 1995 2009 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Vegetable fats, oils, or 200 RB1 Potassic fertilizers, 447 MT2 fractions mixes, not elsewhere hydrogenated, specified (pack > 10 esterified kilograms) Carnallite, sylvite, and 173 PP Unground natural 372 PP other crude natural calcium phosphates potassium salts Nitrogenous fertilizers, 157 MT2 Medicaments not 352 HT2 mixes, not elsewhere elsewhere specified, specified (pack > 10 in dosage kilograms) Unground natural 150 PP Garments not 323 LT1 calcium phosphates elsewhere specified, of cotton, knit Medicaments not 113 HT2 Nitrogenous fertilizers, 206 MT2 elsewhere specified, mixes, not elsewhere in dosage specified (pack > 10 kilograms) Source: United Nations Commodity Trade Statistics Database. Note: HT2 = other high-technology products; LT1 = textiles and fashion products; MT2 = process industries (chemi- cals and basic metals); PP = primary products; RB1 = agriculture-based products. Table A.8 Mauritius’s Top Five Exports 1995 2009 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Raw cane sugar, in 364 RB1 T-shirts, singlets, and 252 LT1 solid form other vests T-shirts, singlets, and 202 LT1 Raw cane sugar, in solid 215 RB1 other vests form Men’s or boys’ shirts of 123 LT1 Tuna, skipjack, and 211 RB1 cotton bonito, prepared or preserved, not minced Men’s or boys’ trousers, 78 LT1 Men’s or boys’ shirts of 106 LT1 breeches cotton Jerseys, pullovers, and 73 LT1 Men’s or boys’ trousers, 78 LT1 so forth, of wool breeches Source: United Nations Commodity Trade Statistics Database. Note: LT1 = textiles and fashion products; RB1 = agriculture-based products. Appendix A 153 Table A.9 Morocco’s Top Five Exports 1995 2009 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Phosphoric and 551 RB2 Phosphoric and 1,000 RB2 polyphosphoric acids polyphosphoric acids Octopus, frozen, dried, 297 PP Unground natural 643 PP salted, or in brine calcium phosphates Unground natural 285 PP Ignition wiring sets and 554 MT3 calcium phosphates other wiring sets Phosphatic fertilizers, 279 MT2 Transistors, except 482 HT1 mixes, not elsewhere photosensitive specified (pack > 10 (> 1 watt) kilograms) Men’s or boys’ trousers, 193 LT1 Diammonium 429 MT2 breeches phosphate (pack > 10 kilograms) Source: United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; LT1 = textiles and fashion products; MT2 = process industries (chemicals and basic metals); MT3 = engineering products; PP = primary products; RB2 = resource-based products. Table A.10 Tunisia’s Top Five Exports 1995 2009 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Men’s or boys’ trousers, 582 LT1 Petroleum oils, oils 1,550 PP breeches from bituminous minerals, crude Petroleum oils, oils 378 PP Electric conductors, 555 MT3 from bituminous not elsewere minerals, crude specified (< 80 volts, with connectors) Virgin olive oil and 228 RB1 Men’s or boys’ trousers, 504 LT1 fractions breeches Phosphoric and 202 RB2 Electrical switches, 486 MT3 polyphosphoric acids protectors, connecters for < 1 kilovolt, not elsewhere specified Diammonium phosphate 164 MT2 Petroleum oils and so 412 RB2 (pack > 10 kilograms) forth, excluding crude Source: United Nations Commodity Trade Statistics Database. Note: LT1 = textiles and fashion products; MT2 = process industries (chemicals and basic metals); MT3 = engineer- ing products; PP = primary products; RB1 = agriculture-based products; RB2 = resource-based products. 154 Some Small Countries Do It Better Table A.11 Sri Lanka’s Top Five Exports 1994 2009 Trade value Technology Trade value Technology Product name (US$ million) class Product name (US$ million) class Tea, black, fermented 256 PP Tea, black, fermented 662 PP or partly (pack > 3 or partly (pack > 3 kilograms) kilograms) Tea, black, fermented 159 PP Tea, black, fermented 485 PP or partly (pack < 3 or partly (pack < 3 kilograms) kilograms) Diamonds (jewelry), 105 RB2 Brassieres 307 LT1 worked but not mounted or set Precious and 76 RB2 T-shirts, singlets, and 225 LT1 semiprecious stones other vests not elsewhere specified, worked, not set Women’s or girls’ 73 LT1 Men’s or boys’ trousers, 246 LT1 blouses, shirts breeches Source: United Nations Commodity Trade Statistics Database. Note: LT1 = textiles and fashion products; PP = primary products; RB2 = resource-based products. Appendix B Table B.1 Finland’s Top 10 Exports in 1980, by Value Value Technology Rank Description (US$ million) class 1 Lumber, sawn, planed, and so forth: conifer 1,321.3 RB1 2 Other printing and writing paper, machine made 1,036.7 RB1 3 Sulfate wood pulp 665.6 RB1 4 Newsprint paper 648.6 RB1 5 Paper and paperboard in rolls or sheets not elsewhere specified 518.9 RB1 6 Ships and boats, other than warships 485.5 MT3 7 Clothing of textile fabric, not knitted or crocheted 452.6 LT1 8 Kraft paper and kraft paperboard 337.1 RB1 9 Plywood, including veneered panels 332.1 RB1 10 Motor spirits, gasoline, and other light oils 300.0 RB2 Source: United Nations Commodity Trade Statistics Database. Note: LT1 = textiles and fashion products; MT3 = engineering products; RB1 = agriculture-based products; RB2 = resource-based products. 155 156 Some Small Countries Do It Better Table B.2 Finland’s Top 10 Exports in 1990, by Value Value Technology Rank Description (US$ million) class 1 Machine made paper and paperboard, simply finished 2,214.6 RB1 2 Other printing and writing paper, machine made 1,592.6 RB1 3 Paper and paperboard in rolls or sheets not elsewhere specified 1,386.3 RB1 4 Lumber, sawn, planed, and so forth: conifer 1,164.1 RB1 5 Telecommunication equipment not elsewhere specified 865.2 HT1 6 Sulfate wood pulp 831.2 RB1 7 Paper mill and pulp mill machinery and so forth 831.1 MT3 8 Newsprint paper 767.2 RB1 9 Kraft paper and kraft paperboard 630.7 RB1 10 Mechanical handling equipment 575.8 MT3 Source: United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; MT3 = engineering products; RB1 = agriculture-based products. Table B.3 Ireland’s Top 10 Exports in 1980, by Value Value Technology Rank Description (US$ million) class 1 Meat of bovine animals, fresh, chilled, or frozen 957.7 PP 2 Organo-inorganic and heterocyclic compounds 405.8 RB2 3 Statistical machine cards or tapes 350.1 HT1 4 Bovine cattle including buffalo 340.1 PP 5 Butter 259.5 RB1 6 Food preparations not elsewhere specified 253.6 RB1 7 Milk and cream in solid form, blocks, or powder 199.1 PP 8 Office machines, not elsewhere specified 162.6 HT1 9 Medical instruments, not elsewhere specified 137.0 MT3 10 Passenger motorcars, other than buses 121.6 MT1 Source: United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; MT1 = automotive products; MT3 = engineering products; PP = primary products; RB1 = agriculture-based products; RB2 = resource-based products. Appendix B 157 Table B.4 Ireland’s Top 10 Exports in 1990, by Value Value Technology Rank Description (US$ million) class 1 Statistical machine cards or tapes 2,505.8 HT1 2 Office machines not elsewhere specified 2,067.0 HT1 3 Phonograph records, recorded tapes, and other sound recordings 1,115.6 LT2 4 Food preparations not elsewhere specified 938.1 RB1 5 Organo-inorganic and heterocyclic compounds 924.6 RB2 6 Meat of bovine animals, fresh, chilled, or frozen 862.6 PP 7 Medicaments 760.4 HT2 8 Nitrogen function compounds 493.7 RB2 9 Medical instruments not elsewhere specified 407.4 MT3 10 Distilled alcoholic beverages 386.8 RB1 Source: United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; HT2 = other high-technology products; LT2 = other low-technology products; MT3 = engineering products; PP = primary products; RB1 = agriculture-based products; RB2 = resource-based products. Table B.5 Singapore’s Top 10 Exports in 1980, by Value Value Technology Rank Description (US$ million) class 1 Residual fuel oils 1,643.4 RB2 2 Natural rubber and similar natural gums 1,538.8 PP 3 Distillate fuels 1,246.6 RB2 4 Thermionic valves and tubes, transistors, and so forth 1,186.8 HT1 5 Lamp oil and white spirits 980.0 RB2 6 Oils and other products of the distillation of coal tar 710.7 RB2 7 Radio broadcast receivers 643.6 MT3 8 Motor spirits, gasoline, and other light oils 589.2 RB2 9 Telecommunication equipment not elsewhere specified 350.7 HT1 10 Palm oil 304.2 RB1 Source: United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; MT3 = engineering products; PP = primary products; RB1 = agriculture-based products; RB2 = resource-based products. 158 Some Small Countries Do It Better Table B.6 Singapore’s Top 10 Exports in 1990, by Value Value Technology Rank Description (US$ million) class 1 Statistical machine cards or tapes 6,828.2 HT1 2 Distillate fuels 3,788.6 RB2 3 Thermionic valves and tubes, transistors, and so forth 3,674.6 HT1 4 Telecommunication equipment not elsewhere specified 2,027.5 HT1 5 Office machines not elsewhere specified 2,024.5 HT1 6 Lamp oil and white spirits 1,907.9 RB2 7 Motor spirits, gasoline, and other light oils 1,854.6 RB2 8 Radio broadcast receivers 1,575.9 MT3 9 Phonographs, tape and other sound recorders, and so forth 1,419.4 MT3 10 Residual fuel oils 1,335.0 RB2 Source: United Nations Commodity Trade Statistics Database. Note: HT1 = electronics and electrical products; MT3 = engineering products; RB2 = resource-based products. Index Figures, notes, and tables are indicated by f, n, and t following page numbers. A Beijing Consensus, 4n13, 144n32 Aalto University (Finland), 74 biotech industry, 140, 140nn20–21 Academy of Finland, 46, 46n38 Botswana Africa. See also specific countries and regions economic development, 31n1 agriculture as share of GDP in, 11 mineral wealth of, 2n6, 31 foreign direct investment (FDI) in, 142 brain drain, 46 implications of Sifire economic development brain gain, 126 for, 140–45 Brazil, contribution of urban areas to economy innovation in, 143n27 of, 20n57 in need of policies for economic broadband connection of Internet users, development in, 4 95–96, 96t nontradable government services and service business community and representation in industries in, 5, 6t coordination and long-term strategy Pan-African market, benefits of, 144 formulation, 16 skill-intensive products and, 141 top five exports, 6, 149–50t C Afrobarometer, 144n35 Cambridge University, 127n30 Agency for Science, Technology, and Research capital’s contribution to growth, 7, 7t, 21, 42 (A*STAR), 86, 87n36 Celtic Resources Holdings Plc (construction agglomeration, contribution to economic materials), 58 development, 20, 127 Centers of Expertise Program (Finland), 47 agriculture as share of GDP, 11 chemical sector, 57 Alko Oy (national alcohol company), 79n27 China Amer Sports (apparel), 56 ability to mobilize to adopt new norms Anglo-Irish Free Trade Area Agreement in, 121 (1965), 89 economic development, 2 Arabic-Islamic civilization, 110n9 investment capital sources in, 14n39 Arrow–Lucas–Romer model of endogenous learning economy in, 17 growth, 3n7 MNCs and, 136 Asia. See also specific countries and regions poverty reduction in, 9 agriculture as share of GDP in, 11 Chinese diaspora, 113 Confucian cultures, 120n11, 121 civic values, teaching of, 121n16 exports’ contribution to GDP growth in, 11, 12f climate change, questioning of, 113n15 investment climate in, 14–15 Commission for Growth and Development, 2n4 B Committee for the Future (Finland), 104 banking sector, 7n18, 14 The Competitive Advantage of Nations banyan tree effect, 136, 136n14 (Porter), 144 159 160 Index competitiveness Economic Community (EEC) membership of Asian countries, 139, 141 of Ireland, 38, 42n31, 89 contribution to economic development, economic development 10, 19 inhibiting factors for late starters, 141–42 of Sifire cities, 47, 113 by region, 8f of Sifire countries, 22, 23–24t scope of, 1 of small countries, 103 stylized facts on, 7–13, 7n17, 8f of universities, 138n17 world growth trends, 9 compressed development, 21, 31–53, 141 Economic Development Board (EDB; consensus building among key stakeholders in Singapore), 102, 107, 109, 109f Sifire countries, 37–38, 103–4 EDB Network, 107–9, 109f containerized shipping, 32, 32n7 education sector, 64–78, 138–40 Control of Manufactured Products Act average years of schooling, 65, 66f, 67 (Ireland), 89n39 centralized school systems, 119, 138 Cork (Ireland), 127 challenges for, 139 Costa Rica feedback loops between university sector educated workforce in, 92n42 and business community, 45 top five exports, 6, 151t free education, 119, 119n8, 138 crises and consequences, 39–41, 137, 142n25. in learning economy, 17. See also learning See also financial crisis, resolution of economy cross-disciplinary efforts primary education, 65n9, 67–68, 68n11, in education, 74 68t, 119 in products and services, 139 priority given to, in Sifire countries, 38–39, in technology development, 111 44, 48 public expenditure on, 64–65, 65–66t, D 67f, 114 developing economies. See also late-starting quality education, 17, 70–71, 110, economies 117–30, 134 accumulation of knowledge, strategies civic values, teaching of, 121n16 in, 111 contribution to economic development, capital’s contribution to growth, 7, 7t 118 economic development, 2, 2n4 early start on schooling, 120 between 1913 and 1950, 9 factors contributing to, 119–21 development economics, 4 family and social reinforcement of, Diageo (drink distributor), 58 120–21, 120nn11–12 Dublin (Ireland), 127 power of, 119–23 Dutch disease, 11 reaching from low starting points, 126–28 E sustaining consistent performance, East Asia 125–26 ability to mobilize to adopt new norms, 121 teacher qualifications, compensation, “flying geese,” 1 status, and autonomy, 121–23, 121n18, growth rates of, 2 122nn19–23, 123nn24–25 investment capital sources in, 14n39 vocational training, 123–24 investment climate in, 14–15 secondary education, 68–70, 69t, 119 learning economy in, 17 tertiary education. See tertiary education other countries emulating, 2 vocational and technical enrollment. regional and bilateral trade arrangements See vocational training in, 34 electronic games industry, 64n7 technological advances in, effect on electronic invoicing, 144–45 manufacturing capabilities in, 35 electronics and electrical industry, 57 Index 161 Encouragement of External Investment Act of between 1970 and 2000, 55 1959 (Ireland), 57n4 approach taken, 3 Enterprise Ireland, 92 changes in economic structure, 55–57, 56f entrepreneurship downturn in 2009, 131n2 contribution to economic development, 10, future goals, 140 16, 16n44 shortcomings in, 137 role of, 18 education sector in Sifire countries, 43, 74n22 approach to quality education, 123, 138 entry barriers, 14, 14n38, 141 average years of schooling, 65, 66f, 67 ethnic factors, 112, 120 centralized school system, 119, 138 European Union (EU) contribution to productivity, 118n6 economic problems of, effect on developing PISA ranks and scores, 71 countries, 4, 4n10 primary education, 67, 68t integration advantage of, 34 as priority, 38, 67n10 structural funds provided to Ireland, 42–43, public expenditure on, 64–65, 65–66t, 67, 67f 42n31 research output from, 76–78, 77t vocational training in, 124 secondary education, 68, 69t exports status and compensation of teaching change to high-tech, 59–64, 60–62t, 63–64f profession, 122, 122n22 contribution to GDP growth, 11, 12f teacher qualifications, 122, 122n19 economic modernization driven by, 38 tertiary education, 45n36, 72, 73–76t, globalized expansion of, 2 74, 74n23, 75f, 126, 127nn30–31 importance to small economies, 31 vocational and technical enrollment, 69t, of resource-intensive products, 2n6, 11 70, 124 top exports of Finland, 10, 155–56t electronic invoicing, 144–45 top exports of Ireland, 156–57t exports top exports of Singapore, 157–58t high-tech exports, change to, 59–60, top exports of small countries, 6, 149–54t 59t, 63f ICT exports, 94, 94t F top 10, 155–56t fast followers, 22n65 financial crisis, recovery in, 40, 43, 131 FDI. See foreign direct investment foreign direct investment (FDI) in, 55, 90, 91f, Fianna Fáil government (Ireland), 103–4 92, 134 financial crisis, resolution of, 12n32, 38n22, 40, industrialization, 39, 49 43, 131–32 innovation capabilities financial institutions and markets, 16. See also leadership and coordination for, 104–5, banking sector 106f development of, as contribution to overall patents, 80–81, 81–82t economic development, 33n9 R&D spending in, 79, 79n28, 79t integration of, 33–34 researchers, number of, 80, 80t, 140 Fine Gael Party (Ireland), 103–4 institutions coordinating for economic Finland. See also Sifire growth, 105–6, 106f. See also Tekes acquisition of foreign technologies in, 92 Internet users, 95–96, 95–96t consensus building among key stakeholders learning economy in, 17 in, 37, 104 patenting in, 17n48 consultative arrangements to facilitate coordi- success of, 23 nation in, 16 trade policies, 89–90, 90f demographics of, 21, 22t urban centers, 111–12, 111nn11–12 diversification policies, 139 Finnish Funding Agency for Technology and domestic investment in, 134 Innovation. See Tekes economic development, 22, 23, 23t Flextronics, 33 162 Index food-processing industries, 57, 59 GPTs. See general-purpose technologies foreign direct investment (FDI) gross domestic product (GDP) contribution to GDP, 12 of East Asian countries, 2 growth of, 34 of Sub-Saharan Africa, 5t as innovation facilitator, 89–92, 91f growth. See economic development as key driver for Sifire countries, 55, 87–88, growth acceleration rates, 2n2 132, 134 growth theorists, 10n20 in Singapore, 113 forest industry, R&D initiatives of, 79n27 H free education, 119, 119n8, 138 Helsinki, 47, 111, 111n11, 127 high-tech industries, 57, 59–64, 60–62t, G 63–64f, 96 Galway (Ireland), 127 Hon Hai (Asian manufacturer), 33 GDP. See gross domestic product Huhtamaki (paper and packaging), 56 General Agreement on Tariffs and Trade human capital. See also education sector (GATT), 12n31, 32n5 contribution to economic development, general-purpose technologies (GPTs), 13, 10, 117, 118, 138–40 13nn34–35, 34–36, 34n11. See also as critical business asset, 118n5 information and communication measurement of, 10n22 technologies (ICTs) Germany I economic development, 2 ICTs. See information and communication quality education issues in, 125 technologies Ghana, top five exports, 149t IDA. See Industrial Development Agency globalization, 12–13, 32–37 (Ireland) defined, 12n31 illiberal democracy, 133, 133n9 demand growth and, 117 immigration policies, 74–75, 112 enabling condition for growth, 48, 134, 141 imports financial crisis and, 12n32 contribution to technological catch-up, future challenges of, 140, 142n26 11–12 general-purpose technologies (GPTs) and, as share of GDP, 89–90, 90f 34–36 transfer of technologies through, 88, 92 innovation capabilities and, 36–37 India networking and, 113 investment climate in, 14 scientific knowledge and technological MNCs and, 136 advance as part of, 110 poverty reduction in, 9 small countries and, 103 services sector trade and, 32–34, 96 technology development’s positive effect Global System for Mobile Communications, on, 35 47n43 trade growth in, 11, 11n27 global warming, questioning of, 113n15 Indonesia governance, 101–16 economic development, 1 contribution to economic development, 10, resource-intensive products as exports 16–17, 133, 137, 144–45 from, 2n6, 11 coordinators to streamline economic growth, Industrial Development Agency (IDA; Ireland), 16–17, 104–9, 106f 92, 92n42, 102, 107, 108f institutions for growth, 109–11, 132 industrial revolution, 110n9 planning agencies, role of, 137 industrial sector, 10–11 power of urban networks, 111–14 competitiveness of, 139 pragmatic governance, 133 in developing countries, 34 weak institutions, effect of, 102 in late-starting economies, 10n25, 141 Index 163 in Sifire countries, 39, 43n33, 135, 141 total factor productivity (TFP) and, 14–15 Sifire investment in, 42 investment climate, 3n8, 14–15 informal sector, 5n15 IQ scores correlated with per capita income, information and communication technologies 120n13 (ICTs), 35, 47–48, 57, 92–96 Ireland. See also Sifire changes in economic structure due to, 56, acquisition of foreign technologies, 92 134, 135 consensus building among key stakeholders exports of, 94, 94t in, 38, 103–4 openness of, 111 construction industry, 131n1 information technology (IT). See also consultative arrangements to facilitate technology development coordination in, 16 contribution to economic development, 10, demographics of, 21, 22t 10n23, 141 diversification policies, 139 investment in, as basis for growth, 11, 17 drain of workers in, 46n40 omnipresence of, 125 economic development, 22, 23t innovation capabilities, 78–87 between 1970 and 2000, 55 computing power and, 13n36 approach taken, 3 crossover innovations, 17n49 changes in economic structure, 57–58, 58f economic growth attributable to, 9, 10n20, education sector 11n26, 132 average years of schooling, 65, 67f globalization and, 36–37 Catholic Church’s role in, 119 leadership and coordination for, 104–9, 106f, centralized school system, 119 108–9f, 134 as FDI factor, 92n42 learning and innovation system (LIS), 44, 45, PISA ranks and scores, 71 46, 49 primary education, 67, 68t low-tech innovation, 143, 143n28 production of university graduates as openness to trade, 89–92, 143n30 skilled workers, 125 patents, 80–87, 81–88t. See also patents public expenditure on, 64–65, 65–66t, 67f R&D spending, 79–80, 79t registration fee, 119n8 researchers, number of, 80, 80t research output from, 76, 77–78t in Sifire countries, 43–47 secondary education, 68, 69t smallness problems and, 133n6 status and compensation of teaching innovation facilitators, 87–96 profession, 122 ICT, 92–96, 94–95t tertiary education, 71–72, 73–76t, openness to trade and FDI, 89–92, 91f 73n21, 74 Institute of Molecular and Cell Biology vocational and technical enrollment, (Singapore), 140n20 69t, 70, 124 Institute of Technical Education (Singapore), exports 69–70 high-tech, change to, 63, 63f institutions. See also governance ICT exports, 94, 94t defined, 101–2 top 10, 156–57t role of, 101, 109–11, 132 fiscal crisis, resolution of, 38n22, 40, 43, 131 weak institutions, effect of, 102 as “flexible development state,” 104 Internet users, 95–96, 95–96t, 139. See also foreign direct investment (FDI) in, 43, 55, information and communication 57nn4–5, 90–91, 91f, 92nn42–43, technologies (ICTs) 113, 134 investment. See also foreign direct immigration and visa policies, 75, 75n24 investment (FDI) industrialization, 39, 43n33, 49 capital investments, 7, 7t innovation capabilities in economic development, 41–43 leadership and coordination for, 107, 108f. in information technology (IT), 11, 17 See also Industrial Development Agency 164 Index Ireland. See also Sifire (continued) teacher unions, 125 patents, 82, 83t, 85–86, 87t late-starting economies R&D spending in, 79–80, 79t, 87n34, entrepreneurship and, 18 143, 143n29 exports to accelerate growth, 4 researchers, number of, 80, 80t factors tempering growth in, 3–4, 141 Internet users, 95–96, 95–96t globalization and, 143–44 investment in growth, 41, 42–43 inhibiting factors for, 141–42 learning economy in, 17 MNCs and, 136 real estate bubble, 131, 131n1 R&D investment of, 143 rebranding of, 38 Sifire countries as models for, 3, 41, 131–47 services sector, trade growth in, 11 with small industrial sectors, 10n25 social capital in, 38, 38n21 learning and innovation system (LIS), 44, 45, success of, 24 46, 49 trade policies, 89–90, 90f learning economy, 17, 55–99. See also youth dividend in workforce, 64n8 education sector Irish diaspora, 113, 113n16 changes in economic structure, 55–58 coordination requirements of, 16, 45 J elements of, 17, 132 Japan high-tech exports, rise of, 59–64 economic development, 1, 2 innovation capabilities, 78–87 investment capital sources in, 14n39 Li & Fung (Asian integrator), 33 investment climate in, 14 Linden Food Group, 58 quality education issues in, 125 LIS. See learning and innovation system stability of firms in business hierarchy in, literacy rates, 119n7. See also education sector 42n30 long-term strategy and coordination, Jordan, top five exports, 6, 152t 16–17, 137 Low2No project (Finland), 106–7 K low-tech innovation, 143, 143n28 Kenya, top five exports, 149–50t Keppel Corporation (Singapore), 47n42 M Keppel Offshore & Marine, 61 Malaysia Kerry Group, 57–58 economic development, 1 knowledge capital, accumulation of, 110, investment capital sources in, 14n39 114, 139 resource-intensive products as exports from, knowledge networking, power of, 113–14 2n6, 11 KONE (company), 56 small and medium-size enterprise (SME) Korea, Republic of sector lacking in, 136 ability to mobilize to adopt new norms managerial skills, 10, 18 in, 121 manufacturing sector. See industrial sector banking sector in, 7n18 Mauritius domestic investment in ICT in, 94n45 economic development, 31n1 economic development, 1 top five exports, 6, 152t economic reliance on large conglomerates McKinsey Global Institute, 122 in, 135nn11–12 Metsäliitto (forest-based products), 82 investment capital sources in, 14n39 Mexico’s literacy deficiency, 119n7 learning economy in, 17 middle-income economies capital’s contribution to growth, 7, 7t L export diversification of, 6 labor unions Sifire countries as models for, 3, 21–22, 112 contribution to economic development, 7t, 9 mineral resources. See natural resources coordination requirements of, 16, 104 MIT, 46n37 Index 165 MNCs. See multinational corporations patents, 17n48, 80–87 Morocco, top five exports, 6, 153t royalty payments indicating acquisition of multinational corporations (MNCs) foreign technologies, 92, 93f banyan tree effect of, 136n14 top 10 assignees of Finland residents’ development strategy linked to, 41–42, patents, 85–86t 42n28, 46, 132 top 10 assignees of Ireland residents’ as growth engines, 136 patents, 85–86, 87t Ireland’s attractiveness to, 38, 43n33 top 10 technology classes of Finland as benefit to Ireland, 40, 49, 57 residents’ patents, 81–82, 81–82t taxation incentives, 64n8, 90–91, top 10 technology classes of Ireland 90–91n40, 91n41, 135, 135n13 residents’ patents, 82, 83t offshoring and, 33 top 10 technology classes of Singapore as patent assignees, 86 residents’ patents, 82, 84t urban areas and, 20n58 N U.S. patents granted by country of origin, Nanyang Technological University, 77, 78, 79t 80, 80n29, 81t National University of Singapore, 77, 78, 79t Patria (defense firm), 56 natural resources, countries with abundance Pax Americana, 32 of, 2n6, 11, 142 People’s Action Party (PAP; Singapore), neoclassical growth models, 3n8 103, 103n3, 133, 133n8 Neptune (transportation company), 47n42 petrochemicals industry, 60–61 Neste Oil, 56 pharmaceutical sector, 57, 60, 135 networked economy. See also urbanization planning agencies, 137 contribution to economic development, policy satisficing, 1 10, 19–21, 21n60, 113–14 political parties and leadership, 103–4, 133. foundations of, 112–13, 112n14 See also specific parties Nokia, 46, 47, 47n43, 57n1, 81, 85, 85nn32–33, poverty reduction, 9 86t, 131, 132n3, 135, 135n12 primary education, 65n9, 67–68, 68n11, 68t, 119 O Programme for International Student OECD Assessment (PISA), 17n49, 44, 71, comparison of student achievement with 71nn17–18, 72t, 118, 119n7, 123n25 Sifire countries, 118, 118n3 “propositional knowledge,” 110 on cultural commitment to education, 120n11 Q on entry barriers, 14n38 quality education. See education sector PISA surveys. See Programme for quark theory, 10n21 International Student Assessment on teaching approaches, 122n23 R “one-stop agency,” 41 regulatory capture, 16, 16n45 O-ring approach, 44, 44n34 research and development (R&D), 42, 44, 45, 49 Oulu (Finland), 127, 127n31 expenditure, 79–80, 79t, 87n34 Outokumpu (mining company), 85, 85t late-starting economies’ need to invest in, 143 outsourcing and offshoring, 33, 35, 141 research output from universities, 76–78, Oxford University, 127n30 77–78t Research and Innovation Council (Finland), P 105n6 PAP. See People’s Action Party (Singapore) research universities, 45, 76–78 paper and pulp industry, 57, 82 resource curse, 11, 11n29 parental influence on children’s education, Rocket Pack, 64n7 120–21, 120n15, 123 Rovio Mobile, 64n7 166 Index royalty payments indicating acquisition of returns of, 117n2 foreign technologies, 92, 93f secondary education, 68–70, 69t Rwanda, top five exports, 150t spending on, 64–65, 65t tertiary education, 17, 39, 71–76, 73–76t, S 75f, 119, 125–26 Samsung, 135n12 entrepreneurship in, 43 science, technology, engineering, and formative period of, 37–39 mathematic (STEM) skills, 45, 118, GDP of, 23t 126, 134, 139 governance institutions, role of, 101, 102–3, Science and Technology Policy Council 109–11 (Finland), 79 high-tech exports, change to, 59–64, Science Foundation Ireland, 77 60–62t, 63–64f, 96 science parks (Singapore), 140, 140nn20–21 home-grown companies in, 47n42 Science Watch (Thomson Reuters), 77 ICT-based industries in, 47–48 scientific knowledge, contributions of, 110, immigration and visa policies, 74–75 110n9 implications for African countries, 140–45 Scientific Revolution, 110n9 industrialization in, 39 secondary education, 119 innovation capabilities, 78–87 second-best approaches, 1 patents, 80–87, 81–88t services sector R&D spending in, 79–80, 79t contribution to economic development, 11 researchers, number of, 80, 80t, 140 trade growth in, 11, 11n27 innovation facilitators, 87–96 shipping methods and costs, 32–33, 32n7 broadband connectivity, 95–96, 96t Sifire (Singapore, Finland, and Ireland). domestic investment in ICT, 94, 95t See also individual countries ICT exports, 93–94, 94t competitiveness of countries, 22, Internet users, 95, 95t 23–24t, 103 openness to trade and FDI, 89–92, 133 compressed development, 21, 31–53, 141 investment in growth, 41–43 consensus building among key stakeholders leadership and coordination for economic in, 37–38, 103–4 growth and innovation, 104–9, 106f, consultative arrangements to facilitate 108–9f, 132, 134 coordination in, 16 learning and innovation in, 43–47 crises and consequences in, 39–41, 137 lessons learned from, 3, 41, 131–47 demographics of, 21, 21n62, 22t leveraging global markets and general- distinctive characteristics of, 21–24 purpose technologies, 133–34 diversification policies of, 139 as market economies, 104 economic development, 22, 23t as middle-income countries, 3, 21–22, 112 between 1970 and 2000, 55 political parties and leadership, 103–4 changes in economic structure, 55–58 pragmatic governance, 133 post-crisis slowdown, 131–32 skilled workforce, 118 education sector, 64–78, 117, 138–40 small and medium-size enterprise (SME) average years of schooling, 65, 66f, 67, sector lacking in, 136 117–18 success of, 22, 31, 48–49, 96–97, 117, 137 free education, 119, 119n8 updating experience of, 135–37 primary education, 67–68, 68t urbanization in, 47–48, 111–14 as priority in, 38–39, 44, 48 Singapore. See also Sifire public expenditure on, 64–65, 65–66t, acquisition of foreign technologies, 92 67, 67f, 114 consensus building among key stakeholders quality education, 17, 70–71, 110, in, 37, 103 117–30, 138 consultative arrangements to facilitate research output from, 76–78, 77–78t coordination in, 16 Index 167 demographics of, 22t trade policies, 89–90, 90f diversification policies of, 139 Sitra (Finnish venture capital fund), 106–7 economic development, 1, 22, 23t skill bias, 44n35, 45, 135 between 1970 and 2000, 55 skills transfer, 13 approach taken, 3 small and medium-size enterprise (SME) changes in economic structure, 58, 59f sector, 136 future goals and challenges, 140, 140n19 social networks, advantages of, 114. See also education sector networked economy approach to instruction, 123, 138 South Africa approach to quality education, 123, 138 education spending of, 125n27 average years of schooling, 65, 66f, 67 natural resources abundance in, 142 centralized school system, 119, 138 small and medium-size enterprise (SME) PISA participation, 71 sector lacking in, 136 primary education, 65n9, 67, 68n11, 68t top five exports, 150t as priority in, 38 South-South trade, 142, 143 production of university graduates as spillovers of urban areas, 20n58 skilled workers, 125 Sri Lanka, top five exports, 6, 154t public expenditure on, 64–65, 65–66t, Stanford University, 46n37 67, 67f state capability traps, 17 research output from, 76–78, 77t “stickiness” to retain best minds, 46–47 secondary education, 68–69, 69t Stora Enso (paper and cardboard), 56, 82 status and compensation of teaching The Strategy of Economic Development profession, 122, 122n20 (Hirschman), 38 teacher qualifications, 122 Sub-Saharan Africa, economic development tertiary education, 71–75, 72n20, 73–76t of, 4–5, 5t, 142–43 TIMSS ranks and scores, 70, 71t supply-chain management, 94n45 vocational and technical enrollment, Switzerland 69–70, 69n13, 69t immigration and visa policies, 75, 75n25 vocational schools, overcoming bias vocational and technical training, 68n12 against, 124 exports T high-tech, change to, 60–62, 62t, 64f Taiwan, China ICT, 94, 94t ability to mobilize to adopt new norms, 121 top 10, 157–58t banking sector, 7n18 financial crisis, resolution of, 40, 43, 132 economic development, 1 foreign direct investment (FDI) in, 55, 90, investment capital sources, 14n39 91f, 113 planning bodies, success of, 137 as illiberal democracy, 133, 133n9 Tallaght Strategy (Ireland), 40 immigration and visa policies of, 74–75 Tampella (heavy industry manufacturer), 85, 85t industrialization, 39, 40n23, 49 tariffs, reduction of, 12n31, 32. See also trade innovation capabilities liberalization leadership and coordination for, 107, 109, taxation incentives for MNCs in Ireland, 64n8, 109f. See also Economic Development 90–91, 91n41, 135, 135n13 Board (EDB) teacher qualifications, 121–22, 121n18 patents, 80, 81t, 82, 84t, 86 teacher unions, 125 R&D spending in, 79–80, 79t Technical Education Department (Singapore), researchers, number of, 80, 80t 69n13 Internet users, 95–96, 95–96t technical schools. See vocational training investment in growth, 14n39, 41, 42, 134 technology development. See also information learning economy, 17 and communication technologies success of, 22–23 (ICTs); information technology (IT) 168 Index technology development. (continued) Trends in International Mathematics and contribution to economic development, Science Study (TIMSS), 44, 70, 10, 44, 142 70n16, 71t, 120–21 fast followers in, 22n65 Trinity College Dublin, 78, 79t gap between most and least developed Tunisia, top five exports, 6, 153t economies, 140n22 Turku (Finland), 47, 111, 111n12, 127 general-purpose technologies (GPTs), 13, 13nn34–35, 34–36, 34n11 U impediments to, 15n41 unemployment, 104 institutions reinforcing, 109–11 unions. See labor unions leadership harnessing, 102 United Nations Industrial Development low-tech innovation, 143, 143n28 Organization , 43n33 royalty payments indicating acquisition of United States foreign technologies, 92, 93f academic drift of students in, 120n14 scientific knowledge, contributions of, 110, churning of firms in business hierarchy, 110n9 42n30 in Sifire countries, 43–47 economic problems, 6n16 skill bias in, 44n35, 45 effect on developing countries, 4, 4n10 technology transfers in imported equipment, education spending, 125n27 88, 92, 134 education’s positive effect on economic Tekes (Finnish Funding Agency for development, 36n15 Technology and Innovation), 46n38, exports from urban areas, 20n58 79, 102, 105–6, 106f innovation’s contribution to economic telecom industry (Finland), 57n1, 81, 135, 140. development, 9 See also Nokia military spending on research, 36n16 tertiary education, 17, 39, 71–76, 73–76t, 75f patents, clustering in urban areas, entrepreneurial universities, 46, 46n37 20nn58–59 importance in production of skilled workers, quality education issues, 125 125–26, 141 retailers as importers, 33n8 investments in, 114 TFP’s contribution to economic ranking of universities, 78, 79t development, 9n19 research universities, 45, 76–78 universities, competitiveness of, 138n17 state subsidization of, 119 universities, generally. See research and develop- urban locations of world-class universities, ment (R&D); tertiary education 127, 127nn30–32 University College Dublin, 78, 79t TFP. See total factor productivity University of East Anglia’s Climate Research Thomson Reuters’s Science Watch, 77 Unit, 113n15 “tiger economies,” 14. See also East Asia University of Helsinki, 78 TIMSS. See Trends in International Mathematics University of Oulu (Finland), 127n31 and Science Study University of Turku (Finland), 127n31 total factor productivity (TFP), 7, 7t, 9, 9n19, UPM (forest-based products), 82 10n20 urbanization capital investment and, 14–15 contribution to economic development, domestic investment in ICT contributing to, 10, 19–21, 20nn58–59 94n45 power of, 111–14 objectives in pursuit of growth, 15–16 in Sifire countries, 47–48 trade arrangements, regional and bilateral, 34, university location and, 127 34n10, 144 Uruguay Round, 32 trade blocs, coalescence of, 34, 96 U.S. Patent and Trademark Office (USPTO), trade liberalization, 32–33, 32n6, 88–89, 89f 80, 80n29, 87n35 Index 169 V improving, as focus of education, 127–28 Valio (dairy products), 56 vocational training of. See vocational Valmet (state-owned machinery maker), 85, training 85n31, 85t youth dividend in Ireland’s workforce, 64n8 Vietnam World Bank’s Doing Business survey, 144n35 economic development, 2 world-class systems, 44 foreign direct investment in, 12n30 world economic development, 9. See also investment climate in, 14 globalization virtuous growth spirals, 15, 102, 117, 137 vocational training, 44, 69t, 118, 123–24, 124n26 Y vulnerability of small countries, 103 Yemeni immigrant children in Israeli schools, 120n14 W youth dividend in Ireland’s workforce, 64n8 Wärtsilä (diesel engine maker), 56, 85, 85t workforce. See also labor unions Z immigration and visa policies for, 74 Zambia, top five exports, 151t ECO-AUDIT Environmental Benefits Statement The World Bank is committed to preserving Saved: endangered forests and natural resources. • 3 trees The Office of the Publisher has chosen to • 1 million Btu of print Some Small Countries Do It Better total energy on recycled paper with 50 percent post- • 290 lb. of net consumer fiber in accordance with the rec- greenhouse gases ommended standards for paper usage set by • 1,309 gal. of waste the Green Press Initiative, a nonprofit pro- water gram supporting publishers in using fiber • 83 lb. of solid that is not sourced from endangered forests. waste For more information, visit www.greenpress initiative.org. C ountries worldwide are “This book should be read by endeavoring to imitate the all the peoples of small and industrial prowess of the East resource-poor countries. The experiences of Singapore, Asian pacesetters. However, building a Finland, and Ireland (Sifire) portfolio of tradable goods and services, show that it is possible for such and raising the levels of investment in countries to overcome their these activities have generally defied the limitations and achieve rapid best policy efforts. Bringing investment and sustainable growth. I agree ratios on par with East Asian averages has with the authors’ insights into how to replicate their success.” proven to be particularly challenging. Tommy Koh The developmental experience of Ambassador-At-Large, Singapore Singapore, Finland, and Ireland (Sifire) offers a different approach to rapid and “Drawing on the intriguing sustained growth. The focus of these similarities and differences among three high-growth countries, rather than being tightly economies at the turn of bound to investment, concentrates on the millennium—Singapore, building human capital in order to Finland, and Ireland—Yusuf attract technology-intensive foreign direct and Nabeshima characterize investment and to enable domestic firms productivity growth as being to compete in global markets for high- driven by not only high investment rates but also value products and services. This recipe the interactions between a for rapid and sustained growth is well range of fundamental building suited for the large number of small, blocks, in particular human resource-poor countries and is of especial capital and institutions. For relevance in the competitive global the policy maker keen to avoid environment of the 21st century. pitfalls in developing policy for promoting economic growth, The book provides a succinct and there is much to be learned accessible analysis of growth that will from the comprehensive be of particular interest to development picture the authors paint of practitioners and policy makers, as well as these interactions.” to academics and students. Patrick Honohan Governor, Central Bank of Ireland ISBN 978-0-8213-8846-4 THE WORLD BANK SKU 18846