R&D intensity

Research and development intensity (R&D intensity) is generally defined as expenditures by a firm on its research and development (R&D) divided by the firm's sales. There are two types of R&D intensity: direct and indirect. R&D intensity varies, in general, according to a firm's industry sector, product knowledge, manufacturing, and technology, and is a metric that can be used to gauge the level of a company's investment to spur innovation in and through basic and applied research. A further aim of R&D spending, ultimately, is to increase productivity (e.g., factor productivity) as well as an organization's salable output.

Definition and aim of metric

Generally speaking, R&D is seen as a main driver of societal and business innovation. The OECD's Frascati Manual describes R&D as "creative work undertaken on a systematic basis in order to increase the stock of knowledge, including knowledge of man, culture and society, and the use of this stock of knowledge to devise new applications."[1]

R&D expenditure and R&D intensity are two of the key indicators used to monitor resources devoted to science and technology worldwide. R&D intensity has been defined as "the ratio of expenditures by a firm on research and development to the firm's sales."[2] William Leonard has described research intensity as "measured usually by ratios of scientific personnel to total employment or by R&D expenditures/sales" to gains in such variables as productivity, profits, sales, and asset status.[3] R&D intensity is therefore a measure of a company's R&D spending toward activities aimed at expanding sector and product knowledge, manufacturing, and technology, and so aimed at spurring innovation in and through basic and applied research.[4][5] Furthermore, it is aimed at increasing "factor productivity and salable output".[3]

There are two types of R&D intensity, calculated as follows:[6]

  • Direct R&D intensity, calculated by dividing R&D expenditure by output
  • Indirect R&D intensity, which quantifies the R&D expenditure embodied in the intermediate goods used in the production of another sector and can be calculated using Input-Output Tables

In enterprises and companies

As the National Science Foundation explains: absolute levels of "R&D expenditures indicate the level of effort dedicated to producing future products and process improvements while maintaining current market share and increasing operating efficiency. By extension, such expenditures may reflect firms' perceptions of the market's demand for new and improved technology." However, R&D intensity is the most frequently used measure "to gauge the relative importance of R&D across industries and among firms in the same industry."[7] Economic research on sixteen industries by William Leonard, "the relation [between investment and gains] appears two years after R&D spending and increases thereafter", although research intensity relates "less effectively" to "manpower ratios [ratios of scientific personnel to total employment]."[3]

Among sectors

R&D intensity differs between different sectors: high-tech sectors (such as aircraft & spacecraft, electrical equipment, and pharmaceuticals) are characterized by the highest R&D intensity, while low-tech sectors (such as food products, iron and steel, and textiles) usually have low R&D intensity.[6] In fact, R&D intensity could be used as the sole indicator to identify high-tech sectors.[6]

By countries and regions

R&D intensity for a country or larger political or geographical entity is defined as its R&D expenditure as a percentage of gross domestic product (GDP) of the entity. Generally speaking, developed countries have higher R&D intensities than developing countries. As Eurostat noted in 2013, for a preceding period,

The European Union (EU) is currently lagging behind both the USA and Japan in terms of expenditure on R&D as a proportion of GDP, primarily due to slow relative growth in business R&D expenditure. The European Council set an overall target of 3% of GDP by the year 2010, with industry asked to contribute two thirds of this objective.[8]

GERD can be broken down among four sectors of performance: business enterprise, higher education, government, and private not-for-profit institutions serving households (PNP).[9]

See also

References

  1. OECD (2002) Frascati Manual 2002: Proposed Standard Practice for Surveys on Research and Experimental Development, The Measurement of Scientific and Technological Activities, p. 30, Paris, FR: OECD Publishing, DOI 10.1787/9789264199040-en, see , accessed 13 October 2015.
  2. Meyer, Peter B. (Editor) (2005). "R&D intensity". Glossary of Research Economics. Retrieved October 13, 2015.CS1 maint: extra text: authors list (link)
  3. William N. Leonard (1971). "Research and Development in Industrial Growth". Journal of Political Economy. 79 (2, March–April): 232–256. doi:10.1086/259741. JSTOR 1832108.
  4. Cohen, Wesley M. & Levinthal, Daniel A. (1990). "Absorptive Capacity: A New Perspective on Learning and Innovation". Administrative Science Quarterly. 35: 128–152. doi:10.2307/2393553.CS1 maint: uses authors parameter (link)
  5. Burgelman, Robert A. & Christensen, Clayton & Wheelwright, Steven (2008). "Strategic Management of Technology and Innovation" (5th ed.). New York, NY: McGraw-Hill. pp. 748–772. ISBN 9780073381541.CS1 maint: uses authors parameter (link)
  6. "Reviewing the nomenclature for high-technology trade – the sectoral approach". European Commission. Retrieved 13 December 2013.
  7. NSF (2010). "Research and Development: National Trends and International Linkages (Ch. 4)". Science and Engineering Indicators 2010. Arlington, VA, USA: National Science Foundation, National Center for Science and Engineering Statistics, National Science Board. Retrieved 13 October 2015.
  8. Anon. (2013). "Glossary: R&D intensity". Eurostat. Retrieved 13 December 2013.
  9. OECD (2013). "2. Building Knowledge, 5. R&D expenditure," In OECD Science, Technology and Industry Scorecard 2013, OECD Publishing, Paris, FR: OECD Publishing, DOI 10.1787/20725345 or DOI 10.1787/sti_scoreboard-2013-en, ISSN 2072-5345 or ISSN 1562-983X, ISBN 9789264203181 or ISBN 9789264205000 or ISBN 9789264200739, see or , accessed 13 October 2015.
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