With some 200 indicators, the 2017 edition of the OECD Science, Technology and Industry (STI) Scoreboard shows how the digital transformation affects science, innovation, the economy, and the way people work and live. It aims to help governments design more effective science, innovation and industry policies in the fast-changing digital era. The charts and underlying data in this publication are available for download and over half the indicators contain additional data expanding the time and/or country coverage of the print edition.
Economies and societies are undergoing digital transformations that bring both opportunities and challenges and countries’ preparedness to seize the benefits of a digital world is largely dependent on the skills of their population.
With some 200 indicators, the 2017 edition of the OECD Science, Technology and Industry (STI) Scoreboard shows how the digital transformation affects science, innovation, the economy, and the way people work and live.
With some 200 indicators, the 2017 edition of the OECD Science, Technology and Industry (STI) Scoreboard shows how the digital transformation affects science, innovation, the economy, and the way people work and live. It aims to help governments design more effective science, innovation and industry policies in the fast-changing digital era. The charts and underlying data in this publication are available for download and over half the indicators contain additional data expanding the time and/or country coverage of the print edition.
Are OECD countries becoming more knowledge-based? Are they embracing the information economy? To what extent are innovation, science, technology and economies becoming global? What are the new growth industries and occupations? With over 160 indicators, 60% of them new to this edition, the volume provides a comprehensive picture of countries’ performance in the areas of science, technology and industry. It uses an improved classification of technology and knowledge-intensive industries. New indicators address emerging policy issues: international mobility of human capital, relative innovative performance as measured by patent families, skills in the information economy, diffusion of the Internet and electronic commerce. Resources devoted to innovation in emerging areas such as biotechnology, environment, health and information and communication technologies are measured for the first time. A new section on the information economy relies on the latest data from official sources. With the essential findings presented in bullet points and methodological notes on indicators and data sources, this publication combines statistical rigour with easy access and readability. An electronic version makes individual sections, an elaborate data appendix and links to the databases readily available. The electronic version also gives users “clickable” access to the data used in charts and figures. AREAS COVERED: New resources for the knowledge-based economy - Human capital and international mobility - R&D performance - Role of government and business in R&D and innovation - Science and innovation performance - Resources and infrastructure for the information economy - Diffusion of Internet technologies and electronic commerce - Contribution of the information and communication technologies to economic performance - International trade - Foreign direct investment - Strategic alliances and cross-border, mergers and acquisitions - Internationalisation of science and technology - Industrial structure and productivity growth - Technology and knowledge-intensive industries and their performance. FURTHER READING: OECD Science, Technology and Industry Outlook 2000; OECD Information Technology Outlook 2000; OECD Communications Outlook 2001; A New Economy: Beyond the Hype, 2001 (OECD ); OECD Main Science and Technology Indicators 2001/1 and STI Working Papers series available at http://www.oecd.org/dsti/sti/stat-ana/index.htm.
This book provides a set of principles for fostering innovation in people (workers and consumers), in firms and in government, taking an in-depth look at the scope of innovation and how it is changing, as well as where and how it is occurring.
What is innovation and how should it be measured? Understanding the scale of innovation activities, the characteristics of innovative firms and the internal and systemic factors that can influence innovation is a prerequisite for the pursuit and analysis of policies aimed at fostering innovation.
The artificial intelligence (AI) landscape has evolved significantly from 1950 when Alan Turing first posed the question of whether machines can think. Today, AI is transforming societies and economies. It promises to generate productivity gains, improve well-being and help address global challenges, such as climate change, resource scarcity and health crises.
