Leapfrogging

For other uses, see Leapfrogging (disambiguation).

The concept of leapfrogging is used in many different domains of economics and business, and was originally developed in the field of industrial organization and economic growth. The main idea beyond the concept of leapfrogging is that small and incremental innovations lead the dominant firm to stay ahead. However, sometimes, radical innovations will permit to new firms to leapfrog the ancient and dominant firm. The phenomenon can occur to firms but also to leadership of countries, or cities.

Leapfrogging in Industrial Organization

In the field of industrial organization (IO), the main work on leapfrogging was developed by Fudenberg, Gilbert, Stiglitz and TIrole^[1] (1983). In their article, they analyze under which conditions, a new entrant can leapfrog an established firm. Tirole^[2] (1988:391-2) has emphasized that leapfrogging can arise because an established monopolist has a somewhat reduced incentive to innovate because he is earning rents from the old technology. This is somehow based on Joseph Schumpeter's notion of ‘gales of creative destruction’.^[3] The hypothesis proposes that companies holding monopolies based on incumbent technologies have less incentive to innovate than potential rivals, and therefore they eventually lose their technological leadership role when new radical technological innovations are adopted by new firms which are ready to take the risks. When the radical innovations eventually become the new technological paradigm, the newcomer companies leapfrog ahead of former leading firms.

Leapfrogging in Leadership and International Competition

In the field of economic growth, the question raised is: under which conditions, will a country which has the leadership lose its hegemony and be leapfrogged by another country. This has happened in history a few times. In the late eighteenth century, the Netherlands has been leapfrogged by the UK, which was the leader during the whole nineteenth century; this century was even coined Pax Britannica. After the second world war, it is the US which has leapfrogged the UK, and became the hegemonic power of the 20th century, Pax Americana.

Why is this happening? Brezis and Krugman (1993,^[4] 1997^[5]) suggest a mechanism that explains this pattern of "leapfrogging" as a response to occasional major changes in technology. In times of small and incremental technological change, increasing returns to scale tend to accentuate economic leadership. However, at times of a radical innovation and major technological breakthrough, economic leadership, since it also implies high wages, can deter the adoption of new ideas in the most advanced countries. A new technology may well seem initially inferior to older methods to those who have extensive experience with those older methods; yet that initially inferior technology may well have more potential for improvements and adaptation. When technological progress takes this form, economic leadership will tend to be the source of its own downfall.

In consequence, when a radical innovation occurs, it does not initially seem to be an improvement for leading nations, given their extensive experience with older technologies. Lagging nations have less experience; the new technique allows them to use their lower wages to enter the market. If the new technique proves more productive than the old, leapfrogging of leadership occurs.

Brezis and Krugman have applied this theory of leapfrogging to the field of geography, and explain why leading cities are often overtaken by upstart metropolitan areas. Such upheavals may be explained if the advantage of established urban centers rests on localized learning by doing. When a new technology is introduced, for which this accumulated experience is irrelevant, older centers prefer to stay with a technology in which they are more efficient. New centers, however, turn to the new technology and are competitive despite the raw state of that technology because of their lower land rents and wages. Over time, as the new technology matures, the established cities are overtaken.

Leapfrogging in developing countries

More recently the concept of leapfrogging is being used in the context of sustainable development for developing countries as a theory of development which may accelerate development by skipping inferior, less efficient, more expensive or more polluting technologies and industries and move directly to more advanced ones.[The mobile phone is also a wonderful example of a “leapfrog” technology: it has enabled developing countries to skip the fixed-line technology of the 20th century and move straight to the mobile technology of the 21st. ] It is proposed that through leapfrogging developing countries can avoid environmentally harmful stages of development and do not need to follow the polluting development trajectory of industrialized countries.^[6] The adoption of solar energy technologies in developing countries are examples of where countries do not repeat the mistakes of highly industrialized countries in creating an energy infrastructure based on fossil fuels, but "jump" directly into the Solar Age.^[7]

Tunneling through

A closely related concept is that of ‘tunneling through’ the Environmental Kuznets Curve (EKC).^[8] The concept proposes that developing countries could learn from the experiences of industrialized nations, and restructure growth and development to address potentially irreversible environmental damages from an early stage and thereby ‘tunnel’ through any prospective EKC. Environmental quality thereby does not have to get worse before it gets better and crossing safe limits or environmental thresholds can be avoided. Although in principle the concepts of leapfrogging (focused on jumping technological generations) and tunnelling through (focused on pollution) are distinct, in practice they tend to be conflated.

Millennium Development Goals

The concept of environmental leapfrogging also includes a social dimension. The diffusion and application of environmental technologies would not only reduce environmental impacts, but can at the same time contribute to sustainable economic development and the realization of the Millennium Development Goals (MDGs) by promoting greater access to resources and technologies to people who currently have no access. Regarding electricity currently nearly one third of the world population has no access to electricity and another third has only poor access. Reliance on traditional biomass fuels for cooking and heating can have a serious impact on health and the environment. There is not only a direct positive link between sustainable renewable energy technologies and climate change mitigation, but also between clean energy and issues of health, education and gender equity.^[9]

Examples

A frequently cited example is countries which move directly from having no telephones to having cellular phones, skipping the stage of copperwire landline telephones altogether.^[10]

The use of ethanol fuel in Brazil, where ethanol produced from sugarcane for transportation replaces gasoline, provides evidence that leapfrogging is a possible alternative to business-as-usual development.

The city of Rizhao in China is an example of energy leapfrogging on city level. As of 2007, 99 percent of households in the central districts use solar water heaters, and most of the lighting and traffic signals are powered with photovoltaic solar power.^[11]

Necessary conditions

Leapfrogging can occur accidentally, when the only systems around for adoption are better than legacy systems elsewhere, or situationally, such as the adoption of decentralized communication for a sprawling, rural countryside. It may also be initiated intentionally, e.g. by policies promoting the installation of WiFi and free computers in poor urban areas.^[12]

The Reut Institute has carried out extensive research regarding the common denominators of all the different countries that have successfully 'leapt' in recent years. It concludes that to leapfrog a country needs to create a shared vision, leadership by a committed elite, 'Inclusive growth', relevant institutions, a labor market suited to cope with rapid growth and changes, growth diagnostics of the country's bottlenecks and focused reforms as well as local and regional development and national mobilization.

Promotion by international initiatives

Japan's Low-Carbon Society 2050 Initiative has the objective to cooperate with and offer support to Asian developing countries to leapfrog towards a low-carbon energy future.^[13]

References

↑ Fudenberg, Drew, Gilbert, Richard J., Stiglitz, Joseph and Tirole, Jean (1983). Preemption, Leapfrogging, and Competition in Patent Races. " European Economic Review. p. 22: 3–31.
↑ Tirole, Jean (1988). The Theory of Industrial Organization. Cambridge: MA: MIT Press.
↑ Schumpeter, J. (1942). Capitalism, Socialism and Democracy. New York: Harper.
↑ Brezis, E., P. Krugman, and D. Tsiddon. (1993). Leapfrogging: A Theory of Cycles in National Technological Leadership ,. American Economic Review. pp. 1211–1219.
↑ Brezis, E. S. and P. Krugman (1997). "Technology and Life Cycle of Cities",. Journal of Economic Growth. p. 2: 369–383.
↑ Goldemberg, J. (1998). "Leapfrogging Energy Technologies". Energy Policy. 2 (10): 729–741.
↑ http://www.wupperinst.org/globalisation/html/leap.html Wuppertal Institute on Leapfrogging
↑ Munasinghe, M. (1999). "Is environmental degradation an inevitable consequence of economic growth: tunneling through the environmental Kuznets curve". Ecological Economics. 29 (1): 89–109. doi:10.1016/S0921-8009(98)00062-7.
↑ Vijay Modi, V., 2004. Energy services for the poor. Commissioned paper for the Millennium Project Task Force 1. December 14, 2004
↑ Look at the difference in ICT diffusion: India ICT Diffusion, History and Forecast compared with Belgium ICT Diffusion, History and Forecast from International Futures
↑ Rizhao: An extensive solar program in China
↑ Cascio, J. "Leapfrog 101" WorldChanging, December 15, 2004.
↑ Ministry of the Environment (Japan), 2007. 'Building a Low Carbon Society'

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