Information technology for national integration essay

Essay on “Information Technology is a developing technology ” Complete Essay for Class 10 and Class 12.

INFORMATION TECHNOLOGY

Information Technology is a developing technology that aims at obtaining the maximum information with minimum of resources, labour or time. According to the dictionary, Information Technology is “the study or use of electronic equipment especially computers, for storing, analysing and distribution of information of all kinds, including words, numbers and pictures.”

Ever since the appearance of Man on the earth, information has been the major cause of his progress and development. But information alone is not enough. Information has to be processed, put to use by logic and reason before it becomes useful knowledge.

Information Technology includes and encompasses within itself the whole technological, social and cultural phenomena that promise an excellent future for mankind. The 21st century is a century of Information Technology. Just as steam engine emerged to be the technology of the 19th century and computer technology enhanced the capacity of human brain in the 20th century, Information Technology is the in-thing in the 21 century.

The technological progress during the past sixty years has brought about an explosion in knowledge. Today we have super computers imitating the human brain and even beating it in various fields like fast data processing, huge memory storage and quick retrieval capacity. These super computers can do as much as Terra (10) floating point operations per second (FLOPS) and have a 128 bit word length. The personal computer is today a part of many urban homes in the country. The computer is changing its capacity so fast that while in the 70s the IC chips were operated with 18MHz clock, today the clock rate is 850MHz. In the near future, we would have computers with a clock speed of 4000 MHz. Similarly, the first microprocessor chip (intel 4004) produced in early seventies had 2500 transistors. We hope to have not in very far distant future, 350 million of these transistors sitting on a tiny little chip. The semiconductor fabrication technology has made a possible for the latest memory devices to have a capacity of one Gigabyte (10 bytes) each, which is equivalent to the information stored in 8000 newspaper pages. A single CD can store in itself the entire works of Shakespeare. The most interesting part of the story of staggering progress is that while the number crunching capacity of the computer is going up in geometrical progression, the price or cost involved is falling down in an almost similar proportion.

This wonder machine called computer has revolutionised life in a big way. With its excellent memory, it has become a source of Internet Information Service. A fathomless ocean of information is available today on these computers on any subject, any phenomenon, anytime and anywhere in the world. You have only to switch on your computer, press a few buttons and a whole sea of information is available to you on your screen to select and download without spending a single penny on it. Just press a few buttons, you may be a student, a research worker in any field, an industrialist or an inquisitive information gatherer, the floodgates of information are opened on you in no time.

Think of the days when transfer of information was confined to oral transmission or written message only. Today, any amount of information can be conveyed from any corner of the world to any other farthest corner, in a matter of seconds only. We have satellite communication, optical fibre communication, terrestrial microwave communication, coaxial cable communication and several other advances systems that enable us to transport enormous amounts of data at the huge rate of several gigabytes per second to the farthest points in the world. The data communication capability is increasing every day with the help of various advancing technologies like the video data compression, digital video and audio, HDTV etc.

The global information Infrastructure has established thousands and thousands of servers and multitudes of personal computers in more than 150 countries. All these computers have been networked in the Internet System. The Internet, you will be surprised to learn, has taken five years to reach the first 50 million users. This number is increasing every day. The day is not far when every human individual will have an access to the brain of every other human individual in the world and the two would be able to exchange information on any and every topic under the sun.

The Information Technology today is rightly called the Technology of the Century as it has found its application and use in every walk society of the world. Distances no longer exist and the world appears to have shrunk into a Global Village. The wisdom of the wisest is today available to the stupidest of the person thus ushering in an era of real equality of opportunity to all. It is really a landmark achievement that more than six billion population of the world will soon be living in a virtual village, as compact as any small Indian village of a fun thousand population.

Information Technology, as expected, has brought about a sea change in the functioning of this world. It has proved to be a great boon to industrial productivity. Internet makes all the information available regarding product design, product quality, latest technologies, market survey, financial conditions and the like at any given point of time on a continuous basis at any place in the world. Systems like Supply Chain Management (SCM) and Enterprises Resources Planning (ERP) and coming up fast to provide mutual help and information to producers, buyers, distributors, and consumers all over the world. Documents transfer has now become a very fast and quick affair. The results are eye-opening. The global market for IT enabled services, starting from 200 billion US dollars in 1998 is growing at the rate of 23 per cent per annum. It is expected to touch the 100 trillion US$ mark by the year 2008. In India alone, the software export industry is expected to touch the 100 billion US dollars mark in the next eight years. Commercial activity through internet not only serves businessmen, consumers, financial institutions and their mutual activities, but also provides advertising facilities on the World Wide Web (WWW) servers and Home Pages. Product specifications, company profiles, catalogues, pricing information etc. are all available on these pages 24 hours a day and seven days per week all over the world. Orders can be placed through E-mail and payments can be made through telebanking facilities and E — currency.

There is a similar revolution in the field of education. No student, anywhere in the world, will now be deprived of the best information available on any subject in any part of the world. The best course material, the best teachers and the best teaching aids and tools will be available to one and all. Education, in fact, is the biggest beneficiary of the Information Technology. Several projects like Wired Class-rooms of the USA, National Grid of the U. K., Operation Knowledge of India, are already under way, to bring internet to the actual class-rooms of every village in every country.

In the field of the social and cultural development also, the Information Technology is fast showing its wonderful impact. Home shopping, Telebanking, Video conferencing, E-mail, Videophones etc. are bringing the peoples of the world closer together and ushering in an era of mutual goodwill, understanding and harmonious relationships. Similarly, E-governance is bringing in well-informed, quick decisions and transparency in administration. No missing files, no red tape, no delay, better records, quick service and no dishonesty or fooling —- this will soon become the order of the day.

In short, every aspect of the human life under the sun will see a vast change. We used to talk of a utopia, a heaven of our dreams. I am sure it is coming. We are soon going to witness an age where every head will be high, where every heart will be happy, where every hand will be busy.

Technology-Based Pilot Programs: Improving Future U. S. Military Reserve Forces (1999)

Chapter: 6 Conclusions and Recommendations

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6
Conclusions and Recommendations

CONCLUSIONS

National Security Environment

Conclusion 1. Four significant trends important to the U. S. military that are expected to continue are: (1) increasing globalization of business, with relatively rapid transfers of technology; (2) increasing access by unfriendly foreign governments and nongovernmental entities to relatively sophisticated weapons and weapons of mass destruction; (3) tensions among and within nations that could require the rapid deployment of U. S. military capabilities; and (4) increasing pressure to reduce U. S. defense spending.

Conclusion 2. The future missions for reserve components could range from very small missions, such as small peacekeeping operations, to major missions, such as the augmentation of active forces in major-theater wars.

In addition to working with active components in fully integrated operations, reserve components could also be assigned the primary responsibility for providing the bulk of the forces to carry out some military missions, such as homeland defense against missile attacks (similar to their long-standing participation in the air defense of the United States).

Conclusion 3. In all likelihood, reserve components will be asked to respond rapidly for most future combat missions involving major force units. Mobilization times are likely to be measured in weeks or days rather than months for deployments overseas or for reserve components remaining in the United States to support other forces overseas.

Technological Environment

Conclusion 4. Advanced technologies will have a profound effect on the capabilities of both active and reserve components between now and 2010.

Most of the impact of advanced technologies related to combat systems, such as precision-guided weapons that can be used in all types of weather, will be common to both the active and reserve components. In most respects, the effects on both components will be positive. However, if advanced technologies are deployed unevenly among the active and reserve components, integration could be adversely affected.

Conclusion 5. Communications and information technologies have the most potential for improving reserve component capabilities compared to the capabilities of the active components.

Globalization of Technology: International Perspectives (1988)

Chapter: Overview

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H. GUYFORD STEVER AND JANET H. MUROYAMA

THE EFFECTS OF TECHNOLOGICAL CHANGE on the global economic structure are creating immense transformations in the way companies and nations organize production, trade goods, invest capital, and develop new products and processes. Sophisticated information technologies permit instantaneous communication among the far-flung operations of global enterprises. New materials are revolutionizing sectors as diverse as construction and communications. Advanced manufacturing technologies have altered long-standing patterns of productivity and employment. Improved air and sea transportation has greatly accelerated the worldwide flow of people and goods.

All this has both created and mandated greater interdependence among firms and nations. The rapid rate of innovation and the dynamics of technology flows mean that comparative advantage is short-lived. To maximize returns, arrangements such as transnational mergers and shared production agreements are sought to bring together partners with complementary interests and strengths. This permits both developed and developing countries to harness technology more efficiently, with the expectation of creating higher standards of living for all involved.

Rapid technological innovation and the proliferation of transnational organizations are driving the formation of a global economy that sometimes conflicts with nationalistic concerns about maintaining comparative advantage and competitiveness. It is indeed a time of transition for firms and governments alike. This book provides a broad overview of these issues and seeks to shed light on such areas as the changing nature of international competition, influences of new technologies on international trade, and economic and social concerns arising from differences in national cultures and standards of living associated with adoption and use of new technologies.

The volume is a compilation of papers presented at the Sixth Convocation of the Council of Academies of Engineering and Technological Sciences held in Washington, D. C. in the spring of 1987. The convocation brought together about one hundred leaders in technology from more than twenty countries to discuss issues of “Technology and the Global Economy.” The program of the convocation was structured around four objectives:

identification and discussion of the driving technologies of the current era, for example, in materials, information, and manufacturing;

evaluation of how technological advances are transforming industrial sectors such as telecommunications and construction;

exploration of how in turn the global economy is affecting technology and production through such factors as marketing strategies, intellectual property rights, and financial markets; and

clarification of regional and national consequences of globalizing industries for several geographical areas including the Pacific Rim, Western Europe, and Latin America.

An overall assessment of the issues raised was provided in conclusion by a panel consisting of Morris Tanenbaum, Wolf Häfele, Sir Robin Nicholson, and Robert Malpas. On the one hand, their assessment made clear that though most technological advance occurs in industry, there are too few mechanisms for exchange of views on international technology and cooperation that involve both private and public sector representatives in a forum not constrained by the formal policies and stands of national governments. There is great need for improved and more open lines of international communication on topics where engineering and technology intertwine with trade and economic growth.

At the same time, the panelists’ evaluations made clear a hierarchy of four sets of relationships among technology, technologists, and the societies they attempt to serve. The first of these includes relationships at the human level, ranging from professional education to relations between management and labor to the public’s understanding of the impact of technology on our lives. The second includes relationships at the institutional level, that is, the impact of technology on the management of businesses and industries. The third relationship is at the national level, where public and private interactions determine the use of technology and possibly a country’s ability to grow economically. The fourth relationship occurs at the international level. Here information flows, trade frictions, and alliances characterize technological development, its diffusion, global competition, and economic advance.

At the human level a key area of change is the invisible contract between a manufacturing company and its customers and employees. In the factory, we are seeing a movement away from the expectation that workers should be organized to fit the technologies and a movement toward networking and

small teams. Wolf Häfele referred to this as the evolution of a higher level of integration between technology and human relations. This is evident, he said, in the emphasis on words such as “interface,” “reliability,” and “adaptation” in describing or explaining some of the new technologies. As a result of this phenomenon, organizations that pursue single objectives may be less suited for survival than those that consider a broader range of issues that optimize the human, organizational, and technological elements.

At the institutional level, private enterprises are the principal instruments in many countries for developing and using technology, although governments play an important enabling role. The task of private enterprises is to be knowledgeable about the current state of science and technology, to understand the needs of the marketplace, and then to create technologies, products, and services that best meet those market needs. Morris Tanenbaum pointed out that this endeavor embraces many disciplines (basic science, engineering, production, distribution, marketing, and finance) and individual motivations. Many participants and observers of the contemporary technological scene propose that we are going through a period of discontinuous change as the breadth of technological applications expands and the time scale of change becomes shorter. For example, markets are becoming more global as transportation and communication speed the flow of knowledge of new products, and greater investment is being made in research and development (R&D) as technological capability has expanded. This process has placed new demands on organizations as they strive to obtain quick and effective market information and access, recoup their R&D investment more quickly, and recognize the importance of sharing technological capabilities. This is particularly true with regard to the information technologies—the one technology most rapidly changing other technologies. It achieves its greatest power when it is most global; where it provides the means to obtain access to the information systems of other countries and establish arrangements that promote the transfer of technology.

Government plays a central role in technology issues at the national level. Technology has now become a part of almost every political discussion as politicians have realized the impact of technology on world events. Governments vary in the way they influence and exploit technological changes, for example, through regulation, procurement, protectionist policies, and support of R&D. Public attitudes among various countries also differ, and these differences can affect governmental technology policy. “Given the fact that there is no ‘correct’ way of dealing with technologies which is applicable to all countries,” Sir Robin Nicholson commented, “each country must find its optimum way depending on its history, institutions, and public attitudes.” This implies that countries will move forward at different speeds, creating imbalances among nations. In this respect, multinational corporations, responsibly managed and sensibly treated by the countries in which they invest,

and transnational joint ventures serve an important function by promoting global equilibrium.

From an international perspective, the main issue is to sustain and improve world growth and improve growth per capita. This breaks down into the problems of Western Europe, Japan, the United States, Eastern Europe and the Soviet Union, and the problems of the more and less advanced developing countries. Robert Malpas noted that it becomes essential for all these players to harness technology for growth; however, this effort is frequently constrained by protectionism, concerns about intellectual property, the demands of international marketing and finance, and, of course, national security. The net result appears to be that emerging nations, with a few exceptions, have even more difficulty achieving the growth necessary to close the gap with leading nations. Among the trends at the international level that can help sustain and improve world growth: the rebirth of interest in manufacturing, the spread of expert systems which multiply skills and help in the industrialization process, the acceptance of multinational corporations, the privatization of various industries, and the increased interest of governments in technology.

As evidenced by the papers in this volume, these four relationships at the human, institutional, national, and international levels permeate discussions on the globalization of technology. In his keynote paper, Simon Ramo maintains that technological issues lie at the heart of most of the social, economic, and political issues of today, sometimes causing problems but more often offering possibilities for their solution. From this perspective, Ramo goes on to make several intriguing predictions about the role of technology in the future. Particularly powerful influences on the diffusion of new technological processes and products will be governments, corporations, national security concerns, and the rate of advances in scientific research. Technological discovery will become a global rather than an individual or national endeavor. As a result, new mechanisms will be developed to facilitate the flow of technology, despite protectionist-nationalist tendencies to stem the free exchange of information. One of these influences impeding the flow of technology is national security concerns. Ramo, however, is optimistic about the direction of the two superpowers, predicting that offensive forces will be reduced, thereby lessening interference with the flow of advanced technology and allowing the application of military technologies to peacetime applications in manufacturing, transportation, and services.

In scientific research, Ramo reiterates his belief that the expense of conducting such research, particularly in “big science” areas such as super colliders or in outer space, and the recognition that such knowledge must be shared to achieve maximum progress are driving scientists toward international cooperation. Since the role of government in setting a national direction for technology is so pervasive, its relationship to the private sector in the

productive use of technology will continue to be problematic. Yet, Ramo argues, it is only the government that can perform the regulatory functions necessary for the smooth operation of free enterprise activity that makes use of new technologies. It is also the government, he says, that will be the primary obstacle to diffusion of the benefits of technology to world society.

As experts on the costs and benefits of developing technology, engineers are in a key position to contribute to policy formation of these issues. For engineers to better prepare themselves for the future, Ramo suggests that engineering education place more emphasis on the links between engineering and its societal applications. The result, he says, will be engineers equipped to play a broader role in influencing government policies and practices regarding technological advance.

Umberto Colombo’s analysis of technological and global economic issues emphasizes the impact of the technological revolution on production methods, types of products, labor markets, and on the importance of manufacturing to the economy. He compares manufacturing to agriculture—although it will no longer dominate the economy or provide the majority of jobs, it will continue to perform an important function even in a service-oriented society. Certain key technologies are bringing about this transition, both creating new industries and rejuvenating mature ones, and in the process are changing patterns of development throughout the world. The rapid spread of innovation makes it imperative that firms quickly exploit any competitive advantage. Moreover, their increased ability to operate in the global marketplace rein-forces the importance of cooperative agreements to advance innovation. Another force driving the trend toward cooperation is the increasingly scientific nature of technology, which requires that firms take a cross-disciplinary approach to solving problems. Colombo also argues that the technological revolution brings about a “dematerialization” of society, one element of which is that fewer raw materials are now needed to achieve a particular level of economic output and income generation.

The globalization of technology is being spearheaded by North America, Western Europe, and Japan. Despite their influence in shaping a new pattern of global competition, each has unique problems. The United States, though a leader in developing emergent technologies, is facing the double threat of enormous budget and trade deficits as well as deindustrialization of traditional economic sectors. Japan, which has demonstrated enormous success in commercializing new technologies, has an economy excessively dependent on exports. Western Europe has the cultural tradition and core of excellent research groups to facilitate its leadership in the technology arena, yet it lacks the cohesion necessary to develop strategic initiatives in important sectors.

Colombo optimistically concludes that globalization will bring the emergence of many small and medium-size multinational firms that will rely on

a network of technology alliances. Governments will provide oversight and strategic direction. The impact on developing countries will be enormous. With the help of new technologies, Third World countries can transform their raw materials and energy into value-added commodities and thereby accelerate economic development without dysfunctional effects. It is the responsibility of developed countries, Colombo concludes, to see that this happens.

Though desirable, the alliances proposed by Colombo are not easily established. As Gerald Dinneen points out in his paper on trends in international technological cooperation, international arrangements, whether they be international marketing organizations, joint ventures, or creation of subsidiaries, are necessary if industries are to get a proper return on investment and remain competitive. However, the “not-invented-here” syndrome, differences in standards, lack of protocols for transmission of data, and especially protectionist sentiment prevent companies and countries from collaborating. Despite these barriers, Dinneen says, international labs and exchanges of scholars and students in schools of engineering have been effective mechanisms for fostering international cooperation.

Presenting the European perspective on technological cooperation, Harry Beckers comments on the impacts of the dissimilarities in the ways academicians and business people conduct research as well as differences in R&D support in the United States, Western Europe, and Japan. Western Europe, he says, faces the unique difficulties posed by its diversity and nationalistic tendencies. Nevertheless, there are a number of EEC programs that facilitate international cooperation among various countries, thereby helping to bring about “Europeanization” in the technology sector.

Papers on three of today’s most crucial technologies—software, materials science, and information technologies—illustrate how the nature of the technologies themselves has created a global environment for research and applications despite the barriers mentioned above. George Pake describes a number of key advances in software: architecture of hardware systems used for software development; advances in writing, editing, running, and debugging of software; development of different programming languages; and systematic forward planning and task analysis. The creativity so evident in software technology today is not in danger, Pake says, despite the trend toward greater standardization and the possibility that ossification of the development system could occur in the future.

Pierre Aigrain addresses several provocative questions about materials, particularly pertaining to the rate at which discoveries are made, the extent to which applications are found, and the impact of these discoveries on industry and society. Citing the influence of the market and the continued interaction between science and materials research, Aigrain predicts that the rapid trajectory of materials discovery will continue. However, processing

costs, rather than the costs of the materials themselves, prevent materials from widespread application. The development of superconductors illustrates this point, and he concludes with a description of the impact these new materials in particular will have on industry and society.

Lars Ramqvist provides insight on several of the cutting edge technologies that have had a major impact on information technologies. These include VLSI technology, computers, software and artificial intelligence, fiber optics, networks, and standards. In addition, he looks at three main applications of information technologies—normal voice telephony, mobile telephony, and data communications—assessing, first, the current state of the art and, second, projections for the future. Ramqvist concludes that because information technologies allow for the dissemination of information, and thus understanding, they will form the basis for a more equitable, humane society.

Hiroshi Inose examines the telecommunications sector from a different angle—the effect of globalization on the entire industry. Particular technological advances, for example, the convergence of service modes and the microelectronics revolution, provide economies of scale but also require rapid inputs for capital investment. Among the problems and challenges Inose addresses are the software crisis, or the high cost of developing more sophisticated and diversified software; structural changes in industry, particularly in job design and labor requirements; standardization and maintaining interoperability between systems and equipment; reliability and security of systems against both external and internal disturbances; and integrity of information and protection of privacy. Like Ramqvist, Inose views telecommunications technology as the means to promote mutual understanding and cultural enrichment worldwide.

Perspectives on the impact of technology on another industrial sector—construction—are presented by Alden Yates who describes the most significant trends in the areas of construction-related design, construction equipment and methods, automation and expert systems, and construction management. Computer-aided design has, among other things, improved communication between designer and supplier and speeded up the design development process. Increases in productivity are being achieved through off-site fabrication and assembly and robotics. Logistics practices, skill requirements, and labor-management relations are also changing as a result of these new technologies. Yates suggests that improved management methods and automation hold the greatest potential benefit for the construction sector, and that to remain competitive in the global marketplace, firms must look at their R&D commitments. In the long run, however, the effectiveness of management will determine success.

Pehr Gyllenhammar makes a complementary point about the importance of management practices in his paper on the manufacturing industry. To claims that the manufacturing sector is on the decline in an increasingly

services-based, information society, Gyllenhammar responds that the manufacturing industry is adapting to today’s environment. One of the most influential changes has been the new technologies employed in the automotive sector, including new engineering materials, computer-aided design, robots, and microcomputers. These new technologies mean that decision making can become decentralized and that small-scale manufacturing can be cost-effective. Another important factor changing the manufacturing industry has been new demands from employees and customers, what Gyllenhammar refers to as the invisible contract between them and the corporation. In fact, the new technologies have brought about important changes in the way work is organized. Less desirable tasks have been taken over by robots; light, flexible technologies allow workers to organize themselves so that they command the technology instead of vice versa; and new materials-handling mechanisms permit the layout of equipment to fit particular work organizations. The challenge for managers lies in organizing production so that they can develop their workers through both technical and leadership training. To accomplish this goal, it will be necessary for the manufacturing industry to take a longer term perspective and use “patient capital” rather than striving for a quick return on investment. Gyllenhammar concludes that a viable manufacturing industry is necessary but not sufficient to solve the problems of unemployment and slow growth.

The manufacturing industry is also the subject of the paper by Emilio Carrillo Gamboa; however, he discusses the issue of production sharing as both a result and a means of globalizing industry. By moving production facilities abroad to low-wage developing countries, firms manufacturing products that have entered the downside of the product cycle can maintain a competitive cost advantage. Mexico, in particular, has become an important production-sharing partner for the United States because of proximity, demographic factors, and the Mexican economic crisis which has resulted in lower wage levels that are competitive with labor costs in the developing countries of Asia and government programs that support production-sharing.

The maquiladoras, or production sharing sites, have been the subject of debate in Mexico for a number of reasons: the benefits of foreign-owned assembly services are not extended to the rest of the economy, the maquiladoras do not absorb traditional unemployment, and they are too vulnerable to swings in the U. S. economy. In addition, some of the plants have been criticized for their poor working conditions. Nevertheless, the author contends that they are an important source of income, employment, and foreign exchange, and proposes that the production sharing offers significant economic opportunities if the competitive advantages of Mexico as a production-sharing site are improved and assembly activities are more closely linked with the domestic economy. Carrillo Gamboa acknowledges the objections to offshore production sharing but suggests that its economic and political advantages far outweigh the disadvantages.

Further discussion of specific regional issues concerning technology’s impact on development is provided in papers by Jan Kolm (Pacific Rim), Enrique Martin del Campo (Latin America), and Ralph Landau and Nathan Rosenberg (United States). In his paper on the consequences of globalizing industry in the Pacific Rim, Kolm uses a theoretical construct based on the technological complexity of goods and the product cycle to describe some general trends in the region’s economic development. For example, gross national product (GNP) has increased rapidly due to the globalization of industry, and export-driven economies have helped the Pacific Rim nations overcome the disadvantages of scale and the shortage of foreign exchange. Kolm asserts that progress in the region is likely to continue, considering that there are suitable gradations of development, ample raw materials in the region as a whole, and a populace that has demonstrated its ability to cope with technological change. The focus of the paper then narrows to an examination of the problems and challenges facing the major groupings of Pacific Rim countries: the Association of Southeast Asian Nations (ASEAN); the newly industrializing countries, in particular, the Republic of Korea; Australia; and the United States and Japan. Despite their diversity and the impediments they have faced in their industrialization, Kolm contends that technology transfer has been less problematic in the Pacific Rim than in other countries of the world, a sign of hope that competition can coexist with cooperation.

Enrique Martin del Campo deals specifically with the influence of technology on development in the Latin American and Caribbean countries. Shifts in economic strength and investment patterns influence the developing countries and make it imperative for them to develop strategies for growth through improved technological and entrepreneurial activity. Martin del Campo suggests that the region’s technology strategy must combine development of both advanced and intermediate technologies, linkage of smaller and large enterprises, and diffusion of technological development through many sectors.

Because the economies of the region, like most developing countries, participate in the international sphere through foreign trade, competitiveness in foreign markets is crucial. The rate of innovation, the ability to apply advanced technology, the degree of capital investment, use of natural resources, and the existence of technological support services all affect the competitiveness of Latin America in foreign markets. Two major factors, however, hamper economic growth in Latin America. First, investment is curbed by an economically depressed environment, and second, global demand for the region’s traditional exports is weak. Any plan to remedy these problems would require a strong technological component, including development of local capabilities in technology, internal and external transfer of technology, strategic projects that integrate science and technology, and government policies that support scientific and technological endeavors.

Ralph Landau and Nathan Rosenberg review the impact of technological change on U. S. economic growth. They cite several key influences on such growth, including technological innovation, high capital investment rates, and increased training of the total work force. The authors conclude that U. S. economic policies are not conducive to innovation and capital formation, and they propose strategies to ensure continued economic growth.

One change that poses both opportunities and difficulties is the rapid diffusion of technology to other countries. As a result, the exploitation of new technologies is no longer an exclusive strength of the United States. The maintenance of a high-wage economy will depend on the ability of U. S. firms to compete in international markets, particularly in manufacturing because of that sector’s contribution to GNP, foreign trade, and national security; its purchases of services; and its productivity increases and consequent contribution to the overall economy.

Landau and Rosenberg also focus on the role of government in creating a favorable environment for business decision making. Policies that encourage personal savings from which investments could be made, reduce the budget and trade deficits, and support a long-term financial climate are essential. However, because U. S. business interests and government do not work as closely as they do in some other countries, Japan, for example, this goal may be difficult to achieve. If the United States is to remain competitive, increases in productivity must be sustained, and this will happen only if training, management, and investment in manufacturing and services are part of public and private strategies.

In the volume’s final paper, Hajime Karatsu reminds us of some fundamental points about the role of technology in improving the quality of life. Technology is instrumental to economic growth, and as a result, economic strength is no longer a function of a nation’s size and population, as it was before the industrial revolution. Although some will argue that technology is the cause of the problems resulting from industrialization, Karatsu describes how technology has been used to provide solutions to some crucial problems—the oil crisis and pollution—in his own country, Japan. Although not explored in his paper, one issue Karatsu’s point raises is the extent to which technological decisions operate in concert with other strategic policies. For example, Japan’s pollution problem, and that of many other industrialized countries, has been solved in part by the export of the pollution-causing industries to other nations.

Karatsu supports his views on the importance of technology to economic growth by commenting that Japan’s methods of applying technologies have allowed it to achieve a 1986 GNP of $2.3 trillion, or 11 percent of the world’s economic activity. One characteristic of Japanese methodology is that new, advanced technologies are applied in practical and simple ways that can be easily commercialized. He cites as an example the use of carbon fiber in

golf clubs and fishing rods. This practice contrasts with that of the United States, where advanced technologies are frequently applied to complex products in the defense industry. A second aspect of Japanese practices in commercializing new technologies is their attention to incremental changes and improvements in product and process. Karatsu concludes by stressing the importance of technological cooperation so that standards of living can be improved worldwide.

The papers in this volume reflect a diversity of national perspectives on the impact of cutting-edge technologies on the individual, industry, and society; appropriate means for harnessing technology to facilitate economic growth for all nations; and the roles that should be played by institutions and governments in the emerging global economy. Nevertheless, agreement on several key issues is apparent: First, technology will continue to fuel economic growth and rising standards of living around the world. Indeed, technology’s influence is pervasive, for it shapes trade patterns and policies, employment, and even relations among nations. A second area of consensus centers on the important role to be played by the engineering community in facilitating international technological advancement. As mentioned by Stephen Bechtel in his introduction of the keynote speaker at the convocation, “…we (engineers and technologists) can only benefit by being more attuned to the factors that influence each country’s technological interests and capacities.” Although this process is frequently constrained by national competitiveness concerns, Bechtel asserts that it is only through increased cooperation that nations remain competitive. “A nation’s strength as a participant in the world economy is derived in part from its ability to adjust to rapidly fluctuating economic conditions and technological change. Cooperation provides access to regional and national trends in technology, thereby benefiting individual nations as well as the international engineering endeavor.” Indeed, industrial competition can be a source of creative tension for the world economy when viewed within the larger global framework of cooperation directed at improving the quality of life for all.