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Evolutionary theories of technological diffusion
and their policy implications
Petr Hanel Professor of Economics
University of Sherbrooke Canada
and
Jorge Niosi Professor of Management
University of Québec at Montreal Canada
To be
Presented to the Annual meeting of EAEPE Porto
Portugal
November 1-3, 2007
Not to be reproduced or cited without the authors approval
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Table of contents
1. Introduction 2. Birth of adoption and diffusion theories 3. Economic research
3.1 Evolutionary theories on adoption 3.2 Evolutionary approaches to development
4. Policy implications 5. Conclusion
Bibliography
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1. Introduction
Technological innovation has an impact on economic growth only when it is widely adopted
and diffused. In this paper, we call “adoption” the actual implementation of a new technology
at firm level, and “diffusion” the spread of the new technology across the economy. As the
proportion of potential users that have adopted an innovation increases, the new technology is
diffused and its economic impact grows. Ruttan (2001) proposed that the economic literature
on adoption and diffusion be split into two different strands: equilibrium and evolutionary
models. However, even though the equilibrium and evolutionary approaches were developed
in parallel for two decades, they began to converge lately in empirical studies. This paper
concentrates on evolutionary models and their policy implications.
Evolutionary models of diffusion are based on the work by Richard Nelson (1968) and Nelson
and Winter (1982). A new strand of evolutionary models is based on complexity and systems
dynamics inspired by the work of Jay Forrester and John Sterman at MIT and W. B. Arthur
and David Lane at the Santa Fe Institute (Sterman, 2000; Lane, 2006). In evolutionary
models, technology adoption takes place in a context of uncertainty and limited information.
In these models, learning is a central feature of the adoption process, and it represents costs
that cannot easily be recovered by the would-be adopter1. Other costs include the disposal of
the previous technology. In these conditions, many potential users prefer to delay the adoption
of new technology in order to reduce uncertainty, and to estimate the population of adopters,
the size of which would most often add to the economic value of the novelty, due to network
externalities, and multiple learning processes. A Rosenberg-type “learning by using” process
occurs in the adopters, as well as a “learning by searching” progression takes places in the
innovating firms together with an Arrow-type learning by doing one. Also, in the evolutionary
approach the original innovation changes during the process of diffusion as learning by
different types of users creates feedback effects that enhance the original innovation.2
1 To be profitable, the adopter has to recover the learning and other related cost sooner or later- otherwise he would not survive. Taking the learning costs into consideration may help to explain the slow speed of diffusion of some technologies. There are two types of learning about the new technology, its suitability, potential problems and advantages: 1) before adoption and (2) after adoption learning to use the new technology. The evolutionary perspective stresses the necessity and implications of “post adoption learning”, including the effect learning may have on further improvement of the technology. 2 The operational concept of innovation used in Oslo innovation survey guidelines takes this evolution into account. The new and improved products and processes introduced by a firm
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A major theme in the evolutionary literature on adoption concerns the role of increasing
returns and the frequency of “lock-in“ situations. While these are supposed to be aberrant and
extreme temporary situations in neoclassical economics (Liebowitz and Margolis, 1998),
evolutionary ideas on development give them a central role, from Gunnar Myrdal (1957) to
W. Brian Arthur (1999). Also, central elements of explanation are information contagion, path
dependent processes, increasing returns and technology choice under uncertainty.
2. Theories
2.1 Birth of adoption and diffusion theories
It is widely accepted that adoption and diffusion theories were born in the traditions of rural
and medical sociology (epidemic models), anthropology and education in the 1920s, 1930s
and 1940s, mainly in the United States (Rogers, 1995). Rural sociology dominated the field,
and up to 1964 it represented over 45% of all publications in the area of diffusion research, all
disciplines combined (Ibid, p. 52). A paper by Ryan and Gross (1943) in rural sociology on
the diffusion of hybrid corn seeds provided the method and model for hundreds of others;
Ryan and Gross developed the S-shaped curve of diffusion, as well as a first classification of
adopters on the basis of how early to adopt an innovation is adopted.
By the late 1950s and mid-1960s, economists became aware of adoption and diffusion
literatures, and started contributing to it, through the works of Zvi Griliches and Edwin
Mansfield. Not by chance, Griliches (1957) wrote his first seminal paper on the diffusion of
hybrid corn, giving its letters patent to the epidemic models he had found in the sociological
literature. Mansfield (1963a, 1963b), instead, devoted himself to the analysis of the diffusion
of industrial innovations. Working often with detailed time series data of a small sample of
firms (panel data) he integrated economic perspective in the epidemic models. The driving
force behind technology diffusion in these models is information diffusion, complemented by
are considered as innovations even though they may not be new to the market or the world. According to a more traditional view these “innovations” would have been considered as “imitations” in the process of diffusion of the original innovation. In the age of politically correct statements everybody may declare to innovate while nobody has to admit to the less glorious act of imitation. Yet, imitation with the associated learning and incremental innovations is at the core of adoption and diffusion of new technology and essential to its economic impact.
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effects of expected profitability and cost, while diffusion is slowed by uncertainty associated
with the use new technology, and influenced by economic characteristics of the adopter.
Models inspired by the epidemic approach provided a useful “macro” synthesis of the
diffusion process for a whole set of potential users. Yet, these macro-economic studies already
address the issues of the “micro” determinants of adoption.
A decade later, management science became also active in the field, and focused more on the
firm-level characteristics of early as opposed to late adopters. In the meantime, the frontiers
between the different disciplines involved in adoption and diffusion research began to fade,
and concepts and methods flowed from one discipline to the next.
The first economic studies of technology diffusion (Griliches, 1957; (Mansfield, 1963a and
1963b) were inspired by epidemic models.
2.2 Current research
Since Nathan Rosenberg made his observation in 1972, the literature on technology adoption
and diffusion has exploded and counts thousands of papers, all disciplines combined. In the
1970s though, economics and management took the lead previously held by sociology in the
area of diffusion.
Some of the major characteristics of the adoption process have been studied in depth. Yet,
putting order in this literature is a complex task because it encompasses economics,
management, policy sciences, geography and sociology. In his major book, Everett Rogers
(Rogers, 1995) has summarized the contribution of the social sciences other than economics
and management, while Richard Nelson and others (Nelson et al, 2004) have tried to organize
the multifarious economic literature. Other authors (Baptista, 1999; Lissoni and Metcalfe,
1994) also tried to paint a broad picture. Some key concepts follow along the disciplinary
paths.
Equilibrium models. In the first generation of these models, technology is basically given
from the start of the diffusion process, and adopters differ in the amount of information they
possess about it. All adopters have similar characteristics. Once the original innovation
introduced the new technology is divisible, explicit, codified and transparent and unchanging.
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Only lack of information about the new technology can preclude or retard its adoption. There
is no uncertainty with regards to its practical application, further evolution and use. In this
simplified framework the rational profit maximizing firms attain a unique, competitive,
welfare maximizing equilibrium. Depending on their access to information and effect of
various market failures, some of them tend to be early adopters; others are laggards resulting
in the time-honoured diffusion curves of the epidemic model. The diffusion process is
characterized by a sequence of shifting static equilibria in which agents are perfectly adjusted
at each point in time (Sankar, 1998, p. 151).
The time path of the proportion of potential users of new technology follows the typical S-
shaped curve (logistic or sigmoid), albeit with shapes and slopes (i.e. speed of diffusion)
varying widely among innovations, industries, regions and countries. (Figure 1 in Annex
shows the widely different patterns of diffusion of selected consumer products and services).
In the 1970s and 1980s, the equilibrium approach changed some of the assumptions inherited
from the rural sociology tradition. Imperfect information of potential adopters ceased to be the
main reason given to explain the evident slowness of the diffusion process. Instead, it was
assumed that the first generation of the new technology was not necessarily superior to the
existing ones. Davies’ book (Davies, 1979) represented a new equilibrium-based approach,
comparable to Griliches seminal article twenty years before. Davies introduced probit models
where potential adopters differed from each other on some important dimension.
Stoneman and Ireland (1983) added learning-by-doing processes taking place at the suppliers,
which translated into price decreases of the new technology over time.
After Mansfield, the equilibrium literature focused not so much on competition and
substitution among technologies, but more on the decision about when to adopt. Companies
are supposed to adopt any new and superior technology, yet they may defer the adoption due
to the high costs of the new technology, due to uncertainty about suitability and performance,
and/or due to sunk costs invested in previous ones. Also, the actual profitability of the
innovation may be low at the beginnings of its diffusion, particularly when early adopters
have to bear the cost of training of existing workers, and assume the cost of complementary
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technologies. In sum, firms continuously update their information on the new technology in
order to optimize the time of their adoption (Jensen, 1982; McCardle, 1985)3.
The equilibrium models were criticized on several topics. They assumed that learning by both
users and producers of the innovation was marginal; they often treated all potential users as
similar in resources and competencies; firms are supposed to behave optimally: they are just
waiting for the new technology to become profitable for them; the number of potential
adopters is also given. Probit and Logit models treat adoption as detached both from diffusion
and from time. In spite of such limitative assumptions, the economic mainstream has
produced important insights into the process of adoption. For instance, firm size was
confirmed as a key determinant of the speed of adoption. However, as McWilliams and
Zilberman (1996) show, probit and logit can incorporate diffusion and time. There is no
reason other than the lack of information on the extent of diffusion –hence time- that prevents
inclusion of these elements in the Probit or logit models. The authors used a sample of
adopters compared to one of non-adopters, and estimated the chances that a given firm adopts
the technology at a certain time on the basis of its size. This allowed the authors to predict the
diffusion pattern. Several diffusion curves were found in different markets, and in the
diffusion of several products and processes. Their study also introduced explicitly the Arrow-
type learning-by-doing within suppliers) was introduced.
The work by Nelson (1968) and Nelson and Winter (1982) launched evolutionary models. In
these models, contrary to the equilibrium ones, adoption and diffusion take place in an
environment of uncertainty and limited information. Rational maximizing behaviour, the
fundamental assumption underlying the neoclassical equilibrium approach is impossible in the
world of uncertain future states of technology. Learning is a central feature of the adoption
process, and it represents costs that cannot easily be recovered by the would-be adopter. Other
costs include the disposal of the previous technology. In these conditions, many potential
users prefer to delay the adoption of new technology in order to reduce uncertainty and to
estimate the population of adopters. Larger number of adopters adds to the economic value of
the novelty, due to network externalities and multiple learning processes. Also, in the
evolutionary approach, the original innovation is changed during the process of diffusion, as
learning by different types of users creates feedback effects that enhance the original novelty
3 McCardle (1985) recognizes the limitations of his model: linearity of the profit function, constancy of profits over time, the one-shot exogenous nature of the innovation, and lack of competition (Ibid, p. 1386).
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(Hall, 2005). A Rosenberg-type “learning-by-using” process occurs in the adopters, and a
“learning-by-searching” progression (Dutton and Thomas, 1985) takes places in the
innovating firms together with the Arrow-type learning-by-doing already indicated. Finally,
evolutionary economics has emphasized the industry-specific and even firm-specific character
of knowledge. In evolutionary economics and management, information is most often
“sticky” (partially tacit and difficult to transfer) rather than “leaky” (explicit, codified,
universally available) (von Hippel, 1994).
Yet, evolutionary theories are difficult to test: micro-economic learning, uncertainty,
technological trajectories, and path dependency are often difficult and costly to measure in
empirical surveys. The “sticky” or “leaky” debate on the character of information will not be
solved with a few easy empirical studies.
A major debate in the adoption literature between the two economic strands concerned the
role of increasing returns and the frequency of “lock-in“ situations. At one extreme, we find
positions such as those taken by P. David (1985), involving the QWERTY keyboard case,
where adopters have chosen a suboptimal novelty due to the early entrance of a particular
solution. At the other extreme are authors such as Liebowitz and Margolis (1998), arguing
that such lock-in situations in inferior technologies are aberrant and uncommon cases, and
that, in the course of adoption, markets are more rational than argued by David. Network
externalities, predominant in later evolutionary models, suggest that these lock-in situations
are likely to be abundant today, and will probably multiply in future. Inefficient standards
may be adopted and persist through time due to sunk costs, information limitation and similar
obstacles to perfect rational adoption decisions (Katz and Shapiro, 1986; Clements, 2005).
The evolutionary approach is based on a “micro” perspective of technology adoption. Viewed
from the point of view of an individual, firm or other organization, models of this type
estimate the factors (characteristics of firms, industries and technologies) that increase or
decrease the probability of adoption of the new technology by the observed unit. These
probabilistic models allow different potential adopters to give different values to the same
technological novelty, and thus allow for heterogeneous behaviors of would be adopters
(Geroski, 2000). Heterogeneous agents, exploiting different learning capabilities may give
different values to technology irrespective of the number of users.
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The speed of the diffusion of innovations thus depends on a variety of micro-level factors,
including the amount of sunk costs incurred in previous adoptions, network externalities, the
response of the providers of the older, competing technologies, the quality and reliability of
information sources about the costs and benefits of adoption, the importance of
complementary inputs, and the market structures of both the adopters and the suppliers of
technological innovation. As one might expect, the greater the sunk costs, and particularly the
sunk cost of learning, the slower will be the rate of adoption of an innovation (Astebro, 2004).
Network externalities are also crucial; they are defined as benefits (or cost) related to the
number of adopters of an innovation. The larger the number of adopters, the larger the
benefits for each particular adopter; the cases of the computer and the dynamo are well known
examples of such network goods in which adopters only benefit when the number of adopters
is substantial (David, 1990). Suppliers also shape the curve of adoption. Suppliers may either
favor fast adoption of innovation, as in the case of agricultural innovations provided by
governmental agricultural stations (Griliches, 1957); or they can delay adoption and try to
extract monopoly rents from their novelty through patenting and/or special arrangements with
particular users (Nelson et al. , 2004).
Also, in the evolutionary approach, technology is not given from the start, but its trajectory
may be affected by the type and number of users. Technology changes as it is adopted,
because the innovators adapt the technology to different markets (industries, countries, size
and capabilities of users). More awkward, some adopters abandon the new technology and
revert to previous ones (McGuckin, Streitweiser and Doms 1998).
The evolutionary models were more inspired by the substitution approach pioneered by
Mansfield. This kind of perspective became more general and substitution replaced simple
adoption, as in the case of the substitution of horses by cars in the United States between 1905
and 1955 (see Figure 2 in Annex) and successive waves in the replacement of raw steel
processes, from crucible to the Bessemer process, to open hearth furnaces to basic oxygen to
the electric processes (Grübler, 1991). The substitution theory brought new forms to the S-
shaped curve: logistic growth is followed by saturation and logistic decline (Nakicenovic,
1997).
In spite of its novel concepts, and its promising synergy between economics and management,
evolutionary approaches of technological diffusion are not easily testable. Bounded
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rationality, learning and uncertainty as micro-foundations in economic agents, whatever their
realism, are difficult to measure; technological trajectories and path dependencies are more
easily mapped ex-post than ex-ante; lock-in situations in inferior technologies are evident
after the adoption process has taken place, but difficult to predict, particularly because the
adopted technological paths tend to evolve, whereas the abandoned ones tend to stagnate.
Since evolutionary approach stresses the importance of the economic and technological
context in which a particular technology is adopted, it is less amenable to statistical analysis
than models based on unifying, albeit simplistic assumptions proper to the equilibrium
approach. The evolutionary theorizing about adoption and diffusion of technology does not
yet – and probably will not in the future – provide a simple model that could be tested. It has,
however, enriched the empirical studies of adoption of new technologies. Increasingly, the
probabilistic models of technology adoption include features suggested by the evolutionary
approach to technological change. As a result, the econometric studies of technology adoption
are becoming more eclectic and realistic.
System dynamics has provided evolutionary economics with a set of tools for modelling
(Arthur, 1994; Sterman, 2000). Case studies (Consoli, 2005; Shi and Gill, 2005) and
conceptual models (Weil and Utterback, 2005) are now appearing using dynamic simulation
methods. Yet, in spite of the advancement that these models provides, particularly through a
more rigorous treatment of the interaction through time of multiple variables, the basic
obstacle remains, namely, how to obtain high quality data through time. These data are
difficult and expensive to obtain, even if the models and methods are far more sophisticated
than previous simple statistical analysis.
4. Policy implication of theories and empirical findings
Both the neoclassical equilibrium approach and the evolutionary theory are in agreement that
government role today4 is to ensure (1) well functioning markets with well defined property
rights, basic economic freedoms including foreign trade and investment and adequate
infrastructure. (2) Government policies are also responsible for health, education and training
of human resources – the development of human capital indispensable for continuous
4 The market consensus defined in the present era of globalization.
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technological change. (3) Last, but not least, Government is to arbitrate in the cases of
conflict of interest, seek to reduce or eliminate major market failures and redistribute income.
All currents have stressed the importance of healthy and open economic environment for
investment in general and adoption of new technologies in particular. For instance, the rate of
adoption of AMTs by Canadian manufacturing firms increased notably with renewed
economic growth after the beginning of the 1990s (Baldwin, Rama and Sabourin, 1999).
International trade and international investment barriers act as an impediment to technology
adoption (Daly and Globerman, 1976)
Taxation is also very important. International differences in effective tax rates on the returns
to technology are, according to Parente and Prescott (1991), fundamental to understand
differences in adoption of new technologies and the resulting diversity in per capita incomes.
Since most new technology originates abroad, policies ensuring openness to international
trade, investment and skilled labour migration are another set of measures contributing to a
favourable environment for diffusion and adoption of new technologies (Comin and Hobijn,
2004; Herrendorf and Teixeira, 2002; Caselli and Coleman 2001, and Coleman, 2004).
However, the market consensus and the usual macroeconomic solutions do not seem enough
in order to catch up with world technological leaders.
Major differences in policy approach appear with regard to promotion of technological
change. The neoclassical equilibrium model of technological change is not concerned with
diffusion of new technologies. The diffusion is believed to happen through profit maximizing
behaviour in a well functioning market. The only need for policy intervention is to eliminate
or reduce market failures affecting the appropriability of innovation related economic
benefits, access to financing and uninsurable risk (Arrow, 1962).
In contrast to the neoclassical doctrine, the evolutionary theory shows that the government
policy can not be limited to ensuring well functioning markets. According to Lipsey, 2002;
(based on Lipsey and Carlaw, 1998- OECD –STI review no.22), not only in industrialised but
also in developing countries the main reasons for additional government intervention are :
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(1) R&D and innovation creates positive externalities and therefore should be supported5 (2)
since technology changes endogenously, it is possible to change a country’s comparative
advantage through policy intervention. (3) Far from being unique, universally available and
free, technological change depends on the local context. (4) Given the uncertainty about
technological development and its acceptance by the market there is no unique, optimal
allocation of resources (R&D and related activities) for innovation and diffusion. Lipsey
argues that policy with respect to these matters has to be based on a mixture of theory,
measurement and subjective judgement.
As pointed out by Canepa and Stoneman (2002), given the diversity of diffusion experiences
of different countries across various technologies, international comparisons may not be a
valid means by which to judge the need for policy intervention in the diffusion process. There
is just not yet sufficient reliable information on the adoption and diffusion process.6 Instead,
the attention should be given to reduce reasons for the divergence from the optimal, i.e. to
address the likely market failures.
The literature has emphasized a major market failure based on information deficits in the
potential adopters; other market imperfections were related to the minimum optimal size of
the firm and the uninsurable uncertainty that contribute to suboptimal investment in
innovation. As our overview of adoption and diffusion studies above shows, these market
failures directly affect the decision to adopt new technology. Policies to subsidize adoption of
new technologies by small and medium size firms aim primarily at reducing these barriers to
the adoption of new technology. It should be noted that small firms and firms in mid and low
tech industries use significantly less R&D tax credit policies (the presumably neutral preferred
neoclassical policy instrument) than larger and high-tech firms. Besides, tax credits aim
creation of new technologies rather than diffusion of the existing ones. Providing information
to firms at low or no cost and help to develop their R&D capabilities is one policy response.
In this direction, Canada created the IRAP program and has spanned agricultural and
industrial national laboratories across the country in order to support technology diffusion.
The evaluation of the IRAP program provides a textbook example of the contrast (difference) 5 Other authors, (Cohen and Levinthal, 1989), have underlined the fact that early adopters are most often R&D executants, as they need to scan the world for novelties in order to solve specific process and product obstacles, and thus learn about existing alternative technologies: “innovation and learning are the two phases of R&D”. 6 As illustrated by the study of technology adoption in Canadian food industries (Baldwin, Sabourin and Smith, 1999) discussed in Section 3.5 above. .
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between the neoclassical and evolutionary approach to diffusion policies. According to the
neoclassical assessment the program was wasteful and the money would have been better
spent on a framework policy such as R&D tax credits. In contrast, according to the
evolutionary perspective (Lipsey and Carlaw, 1998), the program was very successful because
it has placed particular emphasis on changing research and technological capabilities within
firms and on creating new channels of information flows between private industry, university
and government researchers and succeeded to do so.
Agricultural R&D and extension has for decades been the showcase of the usefulness of
government laboratories in the production and diffusion of plant and animal technologies in
Canada, the United States as well as in Western Europe (Ruttan, 1982, 2001).
In Canada and the United States, both the federal level and all the constituent provinces and
states have applied manufacturing extension policies that are the centre of their diffusion
policies (Georghiu and Roessner, 2000). Public laboratories and technology institutes may act
as “windows” of new technology for local firms. They may also be conducive to industrial
technology diffusion if their standard-promotion practices are carefully orchestrated (Link,
1996; Tassey, 2000).
The “lack of information” explanation for the usually slow diffusion of new technology,
consistent with both the equilibrium and the evolutionary approach models, has generated
other policy responses. Human capital building in firms is among them. In Germany,
vocational education has aimed at developing industry specific skills. Industries and their
cooperative associations direct technical change. There is a tradition of long-term
commitment of employees to firms and close links between firms7 and the financial system.
Canada may consider some kind of similar industry-education linkage in order to promote the
permanent upgrading of the labour force. Given Canada’s industrial structure dominated by
small and medium size firms and their position of technological follower rather than leader in
most industries, more emphasis on human capital policies may be called for smaller firms.
7 A great proportion of German firms is made of small and medium size and at the same time export-oriented enterprises.
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Policy emphasis on vocational training could be beneficial in alleviating the chronic lack of
skills- one of the most frequently cited obstacles to adoption of AMTs by SMEs8.
In the equilibrium as in the product life cycle perspectives, there is an overseas corollary. The
solution to slow international adoption of new technology is fairly straightforward: policies
should promote the accumulation of human capital, in order to allow backward nations to
understand, adopt and use superior process technologies and openness to international trade
and direct investment (Comin and Hobijn, 2004; Herrendorf and Teixeira, 2002; Caselli and
Coleman 2001 and Coleman (2004). This type of policy may be called increasing the human
capital pool. This policy implication applies to Canadian backward provinces, such as the
Maritimes. They receive little human capital from abroad, and are less involved in research
and university-industry collaboration, than other provinces (Doutriaux and Barker, 1995).
Both federal and some provincial governments should make additional efforts to attract more
skilled immigrants, develop incentives to insert them in the labour force, and help to convert
their universities into important cradles of human capital by developing scientific and
engineering research. Adoption, or the lack of it, may be the result not so much of attributes of
the firm, but of the structural failures of the “system” of innovation in which they operate.
In the evolutionary perspective, policy implications go further than just correcting imperfect
information and low levels of human capital. Knowledge is seen as partially explicit, and
partially tacit (“know-how”). Even the explicit part of it is not readily available, as firms make
efforts to keep it within the walls of the company, and protect them as industrial secrets. As
such, technical knowledge is often firm and industry specific. As a result, technology transfer
and diffusion are not always costless undertakings. Besides, superior technologies are not
8 German-speaking countries have been applying vocational training schemes with some success. Originally aimed at the chemical and electrical engineering industries, these have extended to ICTs. As the competencies of firms are extremely diverse, the adoption of ICT (and related AMTs) depends on human capital deficiencies at the level of the firm. Several authors (Arvanitis and Hollenstein, 2001a and 2001b) suggest that activist vocational education and retraining institutions may help to increase the absorptive capacity of the firms and should be at the heart of diffusion policies. After realizing that there were deficiencies of AMT-specific knowledge among small and medium size firms, Switzerland introduced AMT-specific training programs that, according to evaluation, had significant diffusion effects (Arvanitis, Hollenstein and Lenz, 1998). On the other hand, the vocational training system may be less appropriate than a more general education system for a continuous adaptation to rapidly changing demand for labour skills.
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always successful.9 Sunk costs in previous technical solutions may also preclude or delay the
adoption of superior technologies, as it happened with electricity and the computer (David,
1990).
In this approach, technology adoption is associated with different degrees of uncertainty.
When there is uncertainty about the future value of different new technologies (the C-series
plane, different high-definition DVD standards today) evolutionary policy may be aimed at
maintaining diversity in technology competition as to permit the unfolding of different
technical trajectories over time (Bryant, 2001). Yet, public policy may be more effective if it
is implemented at the beginnings of the technological competition between different solutions.
Thus, policies aimed at keeping open diversity may be preferable to any early public decision
that would preclude some solution in favor of others. To avoid irreversible sub-optimal
choices, appropriate policies should favor experimenting with alternative technologies. For
instance, in the present debate about future energy technology in Canada, surrounded by much
uncertainty, the evolutionary approach would suggest to keep all alternatives (hydro, thermal,
nuclear and wind) open. National champion technology policies would thus be at odds with
the evolutionary approach, and technical pluralism much indicated. If uncertainty is pervasive
due to accelerated technical change, information and diversification policies may become
permanent elements of government intervention (Metcalfe, 1995; Lipsey and Carlaw, 1998).
Governments may influence diffusion of new technologies by supporting or creating
demonstration projects and by government procurement programs (Rosenberg, 1972;
Mowery, 1993). These government initiatives may, however, carry the risks of “government
failure” implicit in the National champion technology policies.
The patent system may speed up but also retard diffusion of new technologies. This is
especially important consideration as regards diffusion of new technologies to developing
countries. Since the effect of patents on diffusion depends on the breadth of protected claims,
the assessment of the patent system on technology diffusion must be context specific.
Excessively broad patent rights impede adaptation of new technologies to local conditions and
constitute an obstacle to adoption and diffusion of new technologies.
9 The diffusion, prevalence and lock-in in inferior technologies may occur due to historical events, such as the QWERTY keyboard becoming widespread with no specific ergonomic advantage over other types of keyboards, or VHS dislodging from the market the technically superior Betamax video technology (Arthur, 1989).
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Policies supporting adoption and diffusion of new technologies must take into consideration
whether the object of the policy- country, industry or even firms are close to the leading edge
or trying to catch up more advanced competitors. Another important consideration is that
different technologies are at different stages in their life cycle and the policy response has to
take this aspect in consideration. Even though the intra-firm transfer of technology in
multinational firms is very efficient, some of the most successful adopter countries such as
Japan, Taiwan, and South Korea succeeded to catch up the leading edge technologies without
relying on TT via the multinational channel (Lipsey, 2002). In this respect the Japan’s MITI is
a good example of very successful diffusion policies helping the country to catch up and
further develop its technological capabilities.
Evolutionary economics, as pointed up before, has fallen short of empirical research other
than case studies. Its public policy implications are scanty. Besides, when network
externalities exist, and there are several different possible trajectories, public policy
implications are less evident. For instance, when there is uncertainty about the final outcome
where several technologies are competing, second-mover advantages may occur. It is not
evident that faster is better, or that policy should create incentives to rapid adoption as it was
the case in hybrid corn (Hoppe, 2000). Yet, in the evolutionary approach, policy should be
aimed at preventing the generalized adoption of inferior technologies and the subsequent lock-
in of the economic system in these types of technologies.
An important point is that as new technologies are adopted and diffused, they evolve both in
terms of technical characteristics and market applications. Therefore, diffusion policies can
have the greatest impact at the beginning of their life cycle. However, it is at that stage that
the uncertainty is greatest. One way of characterizing evolutionary policy is to provide
government assistance in helping private sector to pick up and push potential winners (Lipsey,
2002).
In sum, in order to benefit from the evolutionary perspective, and draw more precise policy
implications, multiple panel studies would be needed to better understand learning processes
of economic agents, the waning of uncertainty in different technological paths, as well as the
profitability and the specific trajectories (improvements) followed by both the adopted and the
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rejected technologies. Such empirical studies are still to be made10. Also, systems dynamics
has become an increasingly used method in evolutionary economics and management.
Dynamic simulation of adoption processes could shed a different light on diffusion, inasmuch
as data are available to calibrate the models.
10 But we are not entirely devoid of some tentative econometric studies in some industries (see Bonaccorsi and Giuri, 2001)
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5. Conclusions
Several disciplines (chronologically sociology, economics, geography, and management) have
contributed towards an increasingly convergent set of hypothesis and empirical generalizations.
Technology adoption and diffusion have been theorized and hundreds of empirical studies have
been conducted using these theories and different methods. Some general conclusions are already
evident. Technology diffusion is slow and uneven. First adopters are most often large R&D-
intensive firms, and those located in main urban agglomerations in advanced countries.
Conversely, slow and partial diffusion is particularly evident in disadvantaged regions in
industrial nations, as well as in developing countries. Industrial patterns of adoption are also
apparent; industries such as aircraft, automobile and information technology are eager adopters of
AMTs, while more traditional ones, such as pulp and paper, textiles and clothing are less
advanced. Several credible hypotheses have been advanced to explain these delays and
incomplete adoption, including inadequate and reduced information, a meager stock of human
capital, and poor managerial practices.
Yet, many issues remain fairly opaque, due to methodological problems: several types of
externalities (among which knowledge spillovers are the most important) are difficult to measure,
even using the most expensive and sophisticated panel-generated data. If diffusion is affected by
externalities, which is possible, these remain to be proven. Also, learning processes in economic
agents are difficult but not impossible to grasp, requiring panel studies where the stock of
knowledge is measured through time, as well as the processes through which new knowledge is
acquired and integrated into adoption practices. Also, the adoption process is a complex one, with
different agents putting forward diverse strategies; system dynamics, again a costly and time
consuming method, may in the future shed some light on these complex patterns.
Some policy implications are fairly straightforward. They are twofold. First, from a public policy
point of view, governments may diffuse information about new technologies through government
laboratories or other channels; training may increase the private-firm personnel able to
understand, assess and operate new technologies; promoting a variety of technological solutions
may be preferable to one-fits-all strategies and national champions. Helping disadvantaged
19
provinces to increase the influx of skilled immigrants, reducing barriers to integration of
immigrants in the labour market and creating incentives to train their manpower (either in private
firms, colleges and universities) may also provide a fertile soil for technology adoption. Also, as
Geroski (2000) has suggested, diffusion policies assisting small and medium-sized firms to move
closer to the technology frontier may be more advisable than big-science projects pushing the
frontier farther away from them. This latter suggestion seems particularly advisable for smaller
countries such as Canada, Sweden or Switzerland, which may represent between one and two
percent of the world R&D effort.
Second, and from the perspective of collecting useful information, industry studies at a more
disaggregated level, increasingly using panel data, and based on samples valid at the regional
level seem appropriate. More in-depth analysis of specific technologies in which the public purse
has heavily invested (and may invest in the future) also seem suitable; they include nuclear
energy, agricultural biotechnology and nanotechnology.
20
Table 2.1 Theories about diffusion. Representative authors Author Year Theory/model Method/Data Parameters Predictions B. Ryan and N. Gross
1943 Epidemic model
Survey interviews
Innovation, time, social structure, communication channels
Hybrid corn diffused in Iowa through an S-shaped curve. Neighbor imitation is key channel
T. Hagerstrand 1953 Simulation models
Regional data Proximity, personal communication, subsidy
Probability of diffusion a negative function of distance
Z. Griliches 1957 Epidemic Model, logistic curves
Econometric analysis of time series
Profitability Hybrid corn will diffuse if brings higher returns than natural ones. Social returns high on public R&D
E. Mansfield 1963 Epidemic model
Time series of adoption
Information diffusion, cost profitability
Information drives adoption, uncertainty a barrier
R. Vernon 1966 Product life cycle model
Industry studies
Time, standardization, exports, FDI
Innovation diffuses across borders as it standardizes
F. M. Bass 1969 S-shaped marketing model
Case and industry studies
Communication channels, innovator efforts
Media key at beginning, personal communication later
P. David 1985 Evolution, path dependency
Product and industry cases
Information lags, sunk costs
Innovation spreads slowly and best technology is not always adopted
W. Bijker et.al. 1987 Social models Case studies Social structure, culture Social structure affects adoption W. Cohen and D. Levinthal
1989 1990
Evolutionary learning model
Case studies R&D activities, ability to assess technology
R&D executants are early adopters
M. Feldman 1994 Economic geography
Economic data Proximity, spillovers, metropolitan size
Spillovers and competition in cities affect probability of innovation
E. Rogers 1995 Sociological Case studies Superiority, complexity, observability
Parameters affect speed of diffusion
B. Mc Williams & D. Zilberman
1996 Probit & logit models
Samples, industry cases
Size and industry Large firms adopt early, different patterns according to industry
21
Table 2: Public policy about diffusion. Representative authors Author Year
publication Years studied
Country Technologies Impediment Results
T. Hagerstrand 1953 1930s Sweden Agricultural conversion
Distance, lack of information
Personal communication by government carrier was key
W. Ruttan 1982 2001
1850-1980
USA Agricultural technologies
Lack of information, small size of
farms
Government laboratory system an effective way of technology diffusion; but little R&D on soil
degradation
H. Ergas 1987 1945-1985
Germany Switzerland
Sweden
All types System geared to existing
industry and trajectories
Reinforces patterns of specialization; reduced emphasis on new industry
A. Link and G. Tassey; A. Link G. Tassey
1988
1996 2000
1980s USA Advanced industrial
technologies
Lack of product standards
Public standards developed at NIST often had a positive effect on network externalities and
diffusion. Too much or too early standardization may have the opposite effect
R. Lipsey and K. Carlaw
1998 1962-1990s
Canada All types Lack of information
Technology counsellors an effective way of information
G. Klaassen et al. 2003 19780s/ 1990s
Denmark, Germany,
UK
Wind turbines R&D and adoption
Cost, uncertainty
Danish public R&D and demonstration for small turbines was most successful
D. Krueger and K. Kumar
2003 1960s /1990
Germany Vocational training
Absorptive capability
Technical training worked well only under slow technical change in the 1960s
22
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