Ask the Scholar

Document scope · 1 page
doc
Scholar
Ask about this object, its catalog metadata, its source description, or the page inventory. For page-specific OCR and visual context, open one of the page chats.

Scholar Source Context

Document identity
localId
323152821
label
Draper Engineering Award 2/20/90 [OA 6894]
core
doc
dtoType
document
pageCount
1
Source metadata
Source extras
naId
323152821
levelOfDescription
fileUnit
recordType
description
ocrSource
nara-archive
Single page context
seq
1
pageIndex
0
type
document
mediaId
089ab44019533705
ocrText
Originally Processed With FOIA(s): FOIA Number: S S FOIA MARKER This is not a textual record. This is used as an administrative marker by the George Bush Presidential Library Staff. Record Group/Collection: George H.W. Bush Presidential Records Collection/Office of Origin: Speechwriting, White House Office of Series: Speech File Backup Files Subseries: Chron File, 1989-1993 OA/ID Number: 13705 Folder ID Number: 13705-009 Folder Title: Draper Engineering Award 2/20/90 [OA 6894] Stack: Row: Section: Shelf: Position: G 26 19 6 4 OF U.S. Department of Energy STATES Assistant Secretary for Congressional, Intergovernmental BIOGRAPHY and Public Affairs Office of Public Liaison Washington, D.C. 20585 JAMES D. WATKINS 202/586-4292 ADMIRAL, U.S. NAVY (RETIRED) SECRETARY DESIGNATE James David Watkins was born in California on March 7, 1927, and claims the city of Pasadena as his home. A 1949 graduate of the U.S. Naval Academy, he served on destroyers, cruisers and submarines, as well as in various shore assignments, including three in personnel management. Admiral Watkins' tours as a flag officer include Commander of the Sixth Fleet; Vice Chief of Naval Operations; and Commander-in- Chief of the Pacific Fleet. Admiral Watkins was selected by President Reagan to become the 22nd Chief of Naval Operations on June 30, 1982. He retired from that post June 30, 1986, and entered civilian life. Admiral Watkins received his master's degree in mechanical engineering in 1958, and is a graduate of the reactor engineering course at the Oak Ridge National Laboratory. He was selected by Admiral Hyman G. Rickover to enter the Navv nuclear-powered submarine program in- 1959 and subsequently completed his qualification as an Engineering Officer of the Watch at the Navy's land-based reactor plant near Schenectady, New York. Thereafter, he had many years of experience in nuclear propulsion, including all aspects of bringing a new reactor plant on line as commissioning Executive Officer of a nuclear-powered submarine; Commanding Officer of a nuclear-powered submarine; and Executive Officer of the world's first nuclear-powered cruiser, the USS Long Beach. In addition to assignments at sea aboard nuclear-powered vessels, Admiral Watkins served ashore in a variety of assignments associated directly with the selection, education and training of personnel as well as the maintenance and operations of naval nuclear propulsion plants. The first of these was as assistant to Admiral Rickover for these same matters for three and one-half years at his headquarters in Washington, D.C., in the early 1960's. The second was as Director, Nuclear Power Distribution Branch of the Office of the Chief of Naval Personnel. In this capacity, Admiral Watkins was responsible to both the Navv and the then Atomic Energy Commission for proper execution of the stringent Navy personnel standards for maintenance of their qualifications. Later, as Chief of Naval Personnel and Vice Chief of Naval Operations, Admiral Watkins continued his leadership role as principal advisor to the Chief of Naval Operations and Secretarv of the Navy on safe and efficient operations of the Navy's nuclearpowered fleet. Finally, just prior to his assuming duties as Chief of Naval Operations, Admiral Watkins developed and effected implementation of the leadership transitional strategy from Admiral Rickover to his successor. This included documentation of all proven policies and - 2 - procedures employed so successfully over the years and conversion of them into Presidential Executive Order, and later into law. Extensive coordination with selected House, Senate and Department of Energy leaders was required. While Chief of Naval Operations, Admiral Watkins spoke out about various national issues including the growth of international terrorism, technology transfer, and the evolution of nuclear deterrence from an offensive to a defensive strategy. For his leadership efforts in these and other areas, Admiral Watkins was awarded an honorary Doctor of Humane Letters from Marymount College in Arlington, Virginia, in August 1982; an honorarv Doctor of Science degree in June 1983 from Dowling College, Long Island, New York; an honorary Doctor of Laws degree from Catholic University, Washington, D.C., in Mav 1985; and, in recognition of his technical expertise and for fostering technological growth while Chief of Naval Operations, Admiral Watkins received the Award for Creative Technology from Polvtechnic Institute of New York in May 1985. Admiral Watkins' military decorations include several Distinguished Service and Legion of Merit medals, the Bronze Star with combat "V" and other medals, and campaign and service ribbons. He has been decorated by many foreign nations, including Brazil, Korea, Italy, France, Spain, Japan, Pakistan and Sweden. He also was inducted as a Knight of Malta, an international order of leading Catholic laymen dedicated to humanitarian service, in June 1983. Since retiring from naval service, Admiral Watkins has remained actively involved in issues regarding America's youth, working for the establishment of a national program for personal excellence. He has served as a member of the Carnegie Council on Adolescent Development, the Math/Science Advisory Council of the National Executive Service Corps, the Board of Directors of the National Center for Health Education, the Board of Visitors of the New York Medical College, and as consultant to both the Exxon Education Foundation and the Education Commission of the States. Admiral Watkins' energy-related board service has included membership on the Board of Directors or Advisors of several firms: the Philadelphia Electric Company; a biopharmaceutical company, VESTAR, Inc.; SYNTEK Engineering & Computer Systems, Inc.; and the Ford Aerospace Corporation. He has also served as a Trustee on the Committee for Economic Development. In October 1987, Admiral Watkins was appointed Chairman of the Presidential Commission on the Human Immunodeficiencv Virus (AIDS) Epidemic, and submitted the Commission's final report to the President on June 24, 1988. For his work on this commission, he was awarded an honorary Doctor of Humane Letters from the New York Medical College in June 1988. Admiral Watkins married Sheila Jo McKinney of San Diego, California, in 1950. They have six children: Katherine Watkins Coopersmith, Laura Jo Watkins Kauffman, Susan, Charles, James Jr and Edward. Admiral and Mrs. Watkins have eight grandchildren. February 1989 THE WHITE HOUSE WASHINGTON 7 FACSIMILE TRANSMITTAL SHEET NUMBER OF PAGES INCLUDING COVER $2 DATE TO Corrie Levondowski FAX NUMBER 334-1563 OFFICE NUMBER COMMENTS FROM Stephenie Blessey FAX NUMBER OFFICE NUMBER NEWS National Academy of Engineering The National Academy of Engineering is a private organization established in 1964. It shares in the responsibility given the Na- tional Academy of Sciences under a congressional charter granted in 1863 to advise the federal government on questions of science and technology. This collaboration is implemented primarily through the National Research Council. The National Academy of Engineering also recognizes distinguished engi- Date: September 28, 1988 neers, sponsors engineering programs aimed at meeting na- tional needs, and encourages education and research. Contact: Gail Porter, (202) 334-2138 2101 Constitution Avenue, NW, Washington, DC 20418 MAJOR NEW INTERNATIONAL PRIZE ANNOUNCED BY ENGINEERING ACADEMY EMBARGOED FOR RELEASE at 11 a.m. EDT Wednesday, September 28 WASHINGTON - - The establishment of a major new international award for achievement in engineering and technology, consisting of a gold medal and $350,000 in prize money, was announced here today by Robert M. White, president of the National Academy of Engineering (NAE). Endowed by the Charles Stark Draper Laboratory of Cambridge, Mass., the prize recognizes engineering and technology achievements "contributing to the advancement of human welfare and freedom." According to White, the recipient of the first Charles Stark Draper Prize will be announced in October 1989. The award will subsequently be given biennially. The award recipient will be selected by a committee appointed by the NAE and chaired by Robert C. Seamans Jr., senior lecturer, department of aeronautics and astronautics, Massachusetts Institute of Technology. Seamans is also former U.S. Secretary of the Air Force, and former president of the NAE. "This award is designed to focus worldwide attention on the critical role that engineering and technology play in improving the quality of everyday life. Our society tends to reward the discoverer of basic scientific principles but overlook the engineer who puts that principle into practice in products and services that yield societal and economic benefits," said White at a news conference. (OVER) -2- "We hope that in years to come the Charles Stark Draper Prize will be just as well- known and respected an award in engineering as the Nobel Prizes are today for chemistry, physics, and medicine." White also praised the Charles Stark Laboratory for endowing the award. "It is fitting that this award has been established in honor of 'Doc' Draper," he said. "Draper's life's work epitomized the kind of far-reaching innovation the new award will recognize." Charles Stark Draper developed the theory and invented and developed the the technology of inertial guidance systems now universally used in aircraft, submarines, missiles, and space vehicles. For example, the space shuttle Discovery carries a computerized inertial guidance system that will automatically guide it to the correct orbit above the Earth's surface after launch, and will direct the craft safely back to Edwards Air Force Base when the mission is completed. Inertial guidance systems use gyroscopes and accelerometers to determine a craft's position in space without any outside reference points such as stars, landmarks, or radio contacts. Dr. Joseph V. Charyk, chairman of the board of Draper Laboratory said, "I can only surmise, but believe Doc would take great pride in knowing an international prize, recognizing engineering and technological achievements that contribute to the advancement of human welfare and freedom, has been established in his name. It is most fitting that he be so honored, and I'm sure that the people of Draper Laboratory share a sense of pride in the creation of the Charles Stark Draper Prize." (MORE) -3- Nominations of candidates for the prize will be solicited from "members and foreign associates of the NAE, National Academy of Sciences, Institute 00 Medicine; members and foreign associates of academies of engineering worldwide; members of recognized U.S. and international engineering societies; and other individuals deemed eligible by the NAE." Nomination materials describing the prize state that it may be given to any living individual or group of individuals from any country for either a specific engineering/technology achievement or for a body of work extending over a period of years. Work within all engineering disciplines will be eligible. A listing of the Draper Prize committee is attached. # # # EDITOR'S NOTE: A photographic print of the Draper Prize logo as shown on the front cover of the press kit folder is available from the Office of News and Public Information. gp: A,C,G,S CHARLES STARK DRAPER PRIZE COMMITTEE Robert C. Seamans, Jr. (Chairman) John W. Fisher Senior Lecturer Professor of Civil Engineering Department of Aeronautics and Director, ATLSS Engineering and Astronautics Research Center Massachusetts Institute of Technology Fritz Engineering Laboratory Lehigh University Lew Allen, Jr. Director Allen E. Puckett Jet Propulsion Laboratory Chairman Emeritus California Institute of Technology Hughes Aircraft Company Erich Bloch Simon Ramo Director Director Emeritus National Science Foundation TRW Inc. Harvey Brooks Daniel I. C. Wang Professor of Technology Professor of Biochemical Engineering and Public Policy, Emeritus Massachusetts Institute of Technology John F. Kennedy School of Government Harvard University Alvin M. Weinberg Distinguished Fellow Solomon J. Buchsbaum Institute for Energy Analysis Executive Vice President Oak Ridge Associated Universities Customer Systems AT&T Bell Laboratories Sheila E. Widnall Abby Rockefeller Mauze Professor Robert A. Charpie of Aeronautics and Astronautics Chairman Massachusetts Institute of Technology Cabot Corporation Thomas E. Everhart President California Institute of Technology ADVANCE COPY Not For Public Release Before SEP 28 88 11 00 AM OPENING STATEMENT Robert M. White, President, National Academy of Engineering News Conference Establishment of the Charles Stark Draper Prize September 28, 1988 Good morning. I am pleased to announce this morning the establishment of a major new award to recognize outstanding achievement in engineering and technology development. The Charles Stark Draper Prize will be given on alternate years and will include a gold medal and $350,000 in prize money, making it the largest award in monetary terms of its kind exclusively for engineering and technology achievement. The first award recipient will be announced in October 1989, at the National Academy of Engineering's 25th anniversary annual meeting. The award is made possible by a generous endowment from the Charles Stark Draper Laboratory in Cambridge, Mass. It is fitting that this award has been established in honor of 'Doc' Draper. Draper's life's work epitomized the kind of far-reaching innovation the new award will recognize. As a professor of aeronautical engineering at the Massachusetts Institute of Technology, director of the university's Instrumentation Laboratory, and later as head of his own independent laboratory bearing his name, Draper pioneered -2- advanced technology for navigational guidance of aircraft, submarines, missiles, and space vehicles. Derivatives of Draper's "inertial guidance systems" are used in all modern sea, air, and space vehicles to determine a craft's position in space without any outside reference points such as stars, landmarks, or radio contacts. Draper was also responsible for development of the guidance system that safely took the Apollo astronauts to the moon and back. The National Academy of Engineering has established the Charles Stark Draper Prize as part of a larger program to increase public awareness of the importance of engineering and technology. This award is designed to focus worldwide attention on the critical role that engineering and technology play in improving the quality of everyday life. Our society tends to reward the discoverer of basic scientific principles, but overlook the engineer who puts that principle into practice in products and services that yield societal and economic benefits. We hope that in years to come the Charles Stark Draper Prize will be just as well-known and respected an award in engineering as the Nobel Prizes are today for chemistry, physics, and medicine. We have asked our selection committee of NAE members to search the world over for the individual or group of individuals from any nation who has made the greatest engineering or technology achievements "contributing to the advancement of human welfare and freedom." The committee will be chaired by Robert C. Seamans, currently a senior lecturer with the department of aeronautics and astronautics at the Massachusetts Institute of Technology and -3- formerly U.S. Secretary of the Air Force, deputy administrator of NASA, president of the NAE, and last but not least a student of 'Doc' Draper's. Their task will be a difficult one, but, I suspect, quite rewarding, for in the process of selecting an award recipient they will undoubtedly trace the course of the greatest technological advances of modern times. At this point my colleagues and I will be happy to answer any questions you may have. ACADEMY OF NATIONAL ENGINEERING Charles Stark Draper Prize CHARLES S THE STARK DRAPER ORGANIZATIONS SOLICITED FOR NOMINATIONS CHARLES STARK DRAPER PRIZE COMMITTEE ROBERT C. SEAMANS, JR. (Chairman), Senior Lecturer, Department of Aeronautics and Astronautics, Massachusetts Institute of Technology LEW ALLEN, JR. American Institute of Aeronautics and Astronautics Director, Jet Propulsion Laboratory, California Institute of Technology American Institute of Chemical Engineers American Institute of Mining, Metallurgical and Petroleum Engineers ERICH BLOCH Director, National Science American Society of Civil Engineers Foundation American Society of Mechanical Engineers HARVEY BROOKS Argentinean National Academy of Engineering Professor of Technology and Public Policy, Emeritus, John F. Kennedy Australian Academy of Technological Sciences and Engineering School of Government, Harvard Belgium Royal Academy of Sciences University Berlin Academy of Sciences SOLOMON J. BUCHSBAUM Canadian Academy of Engineering Executive Vice President, Customer Systems, AT&T Bell Laboratories Danish Academy of Technical Sciences Finnish Academies of Technology ROBERT A. CHARPIE Chairman, Cabot Corporation French Academy of Sciences THOMAS E. EVERHART Hungarian Academy of Sciences President, California Institute of Indian Academy of Engineering Technology Institute of Electrical and Electronics Engineers JOHN W. FISHER Israel Institute of Technology Professor of Civil Engineering and Director, ATLSS Engineering Japanese Academy of Engineering Research Center, Fritz Engineering Mexican Academy of Engineering Laboratory, Lehigh University Netherlands Forum of Engineers ALLEN E. PUCKETT Chairman Emeritus, Hughes Aircraft Norwegian Academy of Technical Sciences Company People's Republic of China Academy of Sciences SIMON RAMO Polish Federation of Engineering Director Emeritus, TRW Inc. Royal Swedish Academy of Engineering Sciences DANIEL I.C. WANG Soviet Academy of Sciences Professor of Biochemical Engineering, Massachusetts Institute Spanish Center for Technological Industrial Development of Technology Swiss Academy of Technical Sciences ALVIN M. WEINBERG United Kingdom Fellowship of Engineering Distinguished Fellow, Institute for U.S. National Academy of Engineering Energy Analysis, Oak Ridge Associated Universities U.S. National Academy of Sciences SHEILA E. WIDNALL U.S. Institute of Medicine Abby Rockefeller Mauze Professor of Aeronautics and Astronautics, Massachusetts Institute of Technology NATIONAL ACADEMY OF ENGINEERING 2101 Constitution Avenue, N.W., Washington, D.C. 20418 USA Bush Quayle EXCERPTS OF REMARKS FOR VICE PRESIDENT GEORGE BUSH OHIO ASSOCIATION OF BROADCASTERS COLUMBUS, OHIO TUESDAY, OCTOBER 25, 1988 We have grown accustomec. in the political arena to speaking in the language of economics. We talk of Gross National Product, the consumer price index and the leading economic indicators. The economists sift and tally their numbers and present us with the facts of our economic existence. But I want to talk today about another kind of economic fact, one that is often over ooked by those numbers, but one that is, in many ways, more fundarental. Imagine a computer the ize of a room, shrunk down to a size that will fit comfortably on your lap. Imagine today's super-ccmputer shrunk down S1) that it fits on a single silicon chip -- this is the kind of Gramatic improvment the experts now predict This is the computer revolution -- the positive explosion of productivity at the heart of our economy. It is accelerating the rocess of discovery, of innovation and charge and has helped give America, in these last eight years, one of the most remar able periods of creativity our economy has ever known. But the fundamental poi it I want to make today is this -- these dramatic breakthroughs don't only effect silicon valley or other high-tech centers, its effects are spreading throughout our economy. It is a mistake to segregate in one's mind "high tech" from the rest: of our industrial base. In fact, one of the most profounc: effects of this technological revolution is the revitalization of our traditional industries -- not replacement, but revitalization -- making cur products more competitive in global markets. Technology is America's economic fountain of youth. We are in a new era of American industry, where the "service sector" melds with the industrial sector to create modern manufacturing. Americans are taking America's high-tech advantage and putting it to work reshaping our factories to be more competitive in the new information age. Some of the most dramatic examples are right here in Ohio. -more- 733 15th Street, N.W. Suite 800 Washington, D.C. 20005 202/842-1988 Paid for by Bush-Ousyle 88 INfoRmation only - do Not E-1 Cite or quote DRAFT PRELIMINARY 1/31/90 National Academy of Engineering 18-Month Program Plan January 1990-June 1991 Technology and the Environment Program It is already clear that humankind's damage to the environment has become a critical issue for all of us. The coming years will see a burgeoning of activities aimed at arresting and reversing environmental degradation at the local, regional, national, and international levels. The decisions that will be made and the actions that will be taken by governments, industries, and individuals are likely to involve significant economic impact and sweeping changes of our life-styles. A long-standing "paradox of technology" is that it can be both a source of environmental damage and our best hope for repairing such damage today and avoiding it in the future. Following two years of examination of linked technological, environmental, and economic issues, the Academy has made a new three-year program, "Technology and the Environment," its top priority, reflecting the Academy's conviction that this issue is of the utmost importance to society. The program focuses on three themes that underlie the solutions to any of the widespread environmental problems we now face: technological innovation, institutional and economic implications, and international incentives and cooperation. The steering committee list appears as an item at the end of this preliminary program plan. The program recently received a grant of $450,000 from the Andrew W. Mellon Foundation, and the staff is actively seeking additional private foundation funding. On January 8, 1990, the new NAE Technology and the Environment (T&E) Steering Committee, chaired by NAE President Robert M. White, met for the first time to plan an integrated program that would draw on the particular strengths of the Academy and could contribute substantially to public and private environmental strategic planning and policymaking. From among a wide variety of potential first activities, the committee selected five that could reasonably be initiated with the resources in hand during the first 12 to 18 months of the program. 1. A Technological Perspective on Urban Waste: A Systems Approach. The T&E Steering Committee advocated a systems approach to environmental issues in general. Urban waste was chosen as a case study to which such a systems approach could be applied. The waste explosion in all its manifestations is a universal problem. In the United States the evidence for declining environmental quality correlates with trends in production of solid waste (1/2 ton/capita/year in 1960 to an estimated 1 ton/capita/year in 1990). The purpose of the proposed project is to examine urban waste systems in a way that links production activities with the dispersive material flows to the environment from consumption activities. The NAE project would focus on the following questions: 1 E-2 What consumption activities contribute most to waste, and which activities and products mobilize and release the most toxic substances? Are there alternative product and process technologies that can reduce both the volume and the toxicity of waste? What are the flows of materials through the production and consumption systems in urbanized areas, and how can we better monitor or predict them? How can the industrial metabolism (products and processes) and financial analysis be harmonized to provide appropriate economic incentives associated with materials flows and linked to environmental goals? What kind of evidence would it take to compare production, product, and disposal technologies and to analyze their environmental impact, paying special attention to the systems effects (unintended and often unanticipated impacts) of technological environmental solutions? What is the potential of materials accounting as a way of measuring environmental progress? Assessing the urban waste problem in a broad social, economic, and technological context, it is hoped, may lead to an appreciation of the complexity and possible strategies for ameliorating the problem. 2. A Technology Assessment Study of Alternative Automotive Fuels. Despite two decades of effort on the part of the federal government and the automobile industry to reduce emissions from automobiles, air pollution in American cites has grown steadily worse. About half of the U.S. population lives in areas that do not meet federal clean air standards. Local problems in developed areas include carbon monoxide, oxides of nitrogen, various hydrocarbons, and ozone. There is also growing awareness of the global effects of automotive emissions. Transportation fuels yield about one-third of the air pollutants responsible for the greenhouse effect. Several alternative automotive fuels have been studied as possible substitutes for gasoline (as it is now formulated), so that a large body of knowledge now exists on each of the major proposed alternative fuels. Notwithstanding the extent of our knowledge, there has been little progress toward implementing alternative fuel technology beyond small demonstration projects. The topic remains both controversial and wrapped in uncertainty. The consensus of the T&E Steering Committee was that the strength of the NAE as a credible, impartial institution could be bought to bear to give policymakers an appropriately comprehensive perspective on the issue as well as a solid technical basis for deliberations. The proposed study would be a systematic assessment and comparison of leading alternative automotive fuel technology. The goals are (1) to compare the advantages and disadvantages of leading alternative fuels with respect to a common set of criteria-including various key emissions, related environmental effects, energy efficiency, infrastructure requirements, economic costs, and regulatory considerations-and (2) to recommend a strategy for research, development, and implementation, taking into account the total system needed to make use of alternative fuels. 3. Global Warming Policy Prescriptions and the World Energy System. Just as technological decisions lead to environmental effects (frequently unanticipated), upcoming environmental policy decisions will lead to possibly vast technological, social, and economic impacts. What effects would different strategies for environmental amelioration have on other national concerns such as industrial productivity, efficiency in the use of energy and materials, and international competitiveness, and on international trade and relations? As 2 E-3 seen in the example of the Montreal Protocol on Substances That Deplete the Ozone Layers, international agreements are being proposed and ratified ahead of the development of the technologies and institutions which the success of such agreements depends. Limiting emissions of carbon dioxide is the principal strategy now advocated to ameliorate global warming. Various individual investigations have studied the implications of this strategy for the nation's energy system. It is time for a technically qualified and interdisciplinary body to address the issue. With this in mind, the NAE will undertake a project to resolve some the confusion about the likely impacts of policies to reduce global warming on the world energy system in relation to the time phasing of the implementation of policies. The project will emphasize interdisciplinary examination of the topic in a broad system context, bringing together economists, energy technology experts, and social scientists as well as environmental science and policy experts. The goal is to provide decisionmakers an accurate picture of current understanding of the far-reaching and subtle linkages between their strategic planning on global warming and the changes that would be induced in different nations' energy extraction, production, distribution, and consumption sectors. 4. The Economics, Politics, and Environmental Challenges in Technology Transfer to the Third World. Perhaps the most striking new aspect of environmental issues is the widespread recognition of their international nature. Global environmental awareness grows apace with the already significant globalization of production, markets, technology, and finance. The management of these concurrent changes poses complex and serious economic, social, and political problems for many nations. The NAE, working with the national academies of engineering of other nations through the international Council of Academies of Engineering and Technological Sciences, will investigate promising policy options. Through involvement of industrial and academic leadership of many countries, the NAE will seek to facilitate progress on environmental issues with global implications. The NAE will conduct an international project to examine what industrialized nations can do through aid, technology transfer, or trade negotiation to shift the technological aspects of the economic development paths of third world countries to development paths that are less environmentally damaging than those followed by the world's current industrialized nations. The approach could be to examine the question broadly or to pick a particular technological question. In this regard, the United Nations Environment Program has offered to sponsor an activity aimed at encouraging and facilitating transfer of chlorofluorocarbon-substitution technology to developing nations. An NAE workshop on this topic could be an international forum for industry and government representatives to develop ideas for exploiting appropriate and practical technology transfer opportunities and other means of advancing the global elimination of environmentally harmful chlorofluorocarbons. 5. Economic Incentives for Environmentally Compatible Innovation. A primary challenge for the next decades in the United States is to integrate environmental considerations into industrial design and production planning in a manner compatible with economic and regulatory imperatives. Recently, the challenge to innovation for environmental quality has been increased by the legitimate concerns of nations about maintaining or improving their international competitive positions. How does engineering for environmentally sound production and consumption affect the economics and competitiveness of an industry? What is the ability of a system of market forces and institutions to provide incentives internationally and to promote practices that lead to environmentally desirable outcomes? As a first phase in its approach to these issues, the NAE will initiate a study of barriers and incentives to environmentally sound innovation with a particular focus on commercializing more environmentally compatible technologies. The purpose of this activity 3 E-4 will be to develop an agenda for industrial leaders and government policymakers to provide economic incentives for adoption of process and product technologies that are more environmentally benign? Prospering in a Global Economy Over the last two or three decades, advances in communications and transportation technologies have changed the nature of the global economy. The degree of interdependence allowed by inexpensive and effective transportation and communications is unprecedented. U.S. businesses now have more than $1.2 trillion in assets abroad, and about one-third of earnings by U.S. multinationals comes from overseas operations. A recent complement to the expansion of U.S. direct investment abroad has been a virtual flood of foreign investment into the United States since the mid-1970s. Today more than 3 million Americans work for foreign multinational corporations with affiliates in the United States; in 1988 direct foreign investment in the U.S. totaled $328 billion, $2 billion more than American direct investment abroad. The ability to produce advanced goods in many nations, the trend toward globally operated engineering and production, and the homogenization of many previously national product markets have changed the nature of economic activity among industrialized nations. This change has occurred in such a way that volumes of capital, goods, services, components, people, data, and technological know-how flow across national boundaries as part of everyday commerce. Just as technological advance is allowing increased international economic interdependence, so international economic activity is driving changes in the character of the global technological enterprise. In particular, economic interdependence among industrialized nations has brought the technological activities of corporations and governments into closer relationship than ever before, and sometimes into conflict. The rapid transfer of technology across national boundaries has aided this trend, as have the research and scholarly exchanges among U.S. universities and foreign companies and institutions. Indeed, major U.S. research universities have become a model of truly international institutions-they are international educators, information exchange nodes, and global research facilities. With campuses abroad, student exchange programs, and philanthropic and research funding from both U.S.- and foreign-based multinationals, U.S. universities play an important and growing role in the international flow of technological know-how. The emerging international integration of industries and research and educational institutions poses new questions and issues for all nations. Although international technology questions are somewhat familiar in Europe and in isolated trading nations such as Japan, this is a new global reality for the United States. The U.S. policy structure is not experienced in dealing with the issues raised by these new relationships among national governments, universities, and multinational companies, especially as they affect the U.S. engineering enterprise. To address these issues, the NAE has launched a major new three- year program, "The Interdependence of Nations: Technology and Economics in Global Relations," aimed at understanding how the United States might prosper in this new global economy. The program recently received a three-year $600,000 grant from the Alfred P. Sloan Foundation-to be matched by NAEF or other funds-for a minimum program size of $1.2 million over three years; the Academy is actively seeking additional funding for the program. The initial project opportunities presented by this program were discussed by the International Affairs Advisory Committee, the Technology and Society Advisory Committee, 4 E-5 the Academic Advisory Board, members of the NAE committee on working on the precursor project to this program "Engineering as an International Enterprise," and with the on-site officers of the Academy. The three projects described below represent the projects proposed to be initiated or completed in the first 12 to 14 months of the program's operation. 6. Technology Policy Options in a Global Economy. The NAE will convene a committee to consider the history, current practice, and future prospects for national policies to encourage economic development through both direct and indirect government support of technological advance. This study would be carried out by a committee of the National Academy of Engineering, augmented when necessary by experts from other fields. The study addresses a topic about which volumes have been written-some by previous NAE committees-but the changing nature of the global economy raises new issues and calls for new approaches. Although the interests of companies (serving shareholders) and nations (serving citizens) have never been perfectly coincident, there were, in the post World War II period in the United States, few obvious breaks between the interests of U.S.-based multinationals and U.S. citizens. They continue to share closely linked futures, but the increasingly transnational nature of effectively competing U.S.-based multinational companies raises new questions. As the technological capacity of a firm or industry becomes increasingly transnational, it follows that the dependence of that particular firm or industry on any single national engineering enterprise may diminish. With the gradual dissolution of the long-standing special bond between the U.S. engineering enterprise and U.S. companies, decisionmakers are recasting their views of the link between corporate and national interests in, and responsibilities for, U.S. technological enterprise. Conversely the increasing role of foreign-based multinational corporations in the U.S. economy, while generally representing a positive contribution, also raises new questions for the U.S. technological enterprise. Corporations will do what they need to do to prosper, but can U.S. citizens (and their agent, the U.S. government) continue to rely on large U.S. (and foreign) multinational companies as the source of technological advance that will drive national as well as corporate economic growth? Has the burden of developing a sufficient technological infrastructure-a burden that used to be more evenly shared by firms and the public sector-shifted subtly to governments (local, state, and federal)? This is not an exclusively American dilemma. Corporate and national interests are significantly changing in the economies of Western Europe, and even the intimate partnership between Japanese government and industry i,s beginning to experience the strains of globalization. Because globalization has intensified competition among nations for increasingly mobile corporate resources, an important aspect of the challenge for technology policy for the next millennium may be to make the United States an attractive place for global corporations to do engineering and technology-intensive industrial activities. Although it is unclear how the distribution of engineering activities will develop or be affected by the actions of different governments, America's trading partners appear to be better prepared to cope with these developments and to compete more effectively for the increasingly mobile technological, managerial, and financial resources of transnational firms. These are obviously sensitive political questions, and the study itself is not intended to imply that corporate and national interests are now significantly at odds or mutually exclusive. The question that should be asked, however, is whether this diversity of interests requires new mechanisms to ensure that national concerns are recognized while multinational economic enterprises prosper. 5 E-6 7. The Role of Universities in Economic Development. Universities face a unique challenge in the emerging global economy. Unlike companies that are established to advance shareholder interests, or democratic governments established to represent citizens, universities are established to serve both an ideal-the pursuit and dissemination of knowledge-and an array of self-interested constituencies. U.S. land-grant colleges had explicit charters for economic development, but during the post World War II period, U.S. universities have become global intellectual utilities driving development and education not just in the United States but worldwide. It is an approach wholly consistent both with post-war U.S. government approaches to other nations and with the ideal of knowledge as the common heritage of mankind. As U.S. economic dominance has faded, however, the pressure has steadily increased for universities, especially scientific and technical research universities, to contribute to local, regional, national, and international economic development. At a regional level, every state wants a "Silicon Valley," a "Route 128," or a Research Triangle Park supported in part by local university-based technical talent. At a national level, government agencies increasingly expect research grants to contribute to national competitiveness, and there are congressional concerns about foreign firms' increasingly active use of U.S. university research as a means of gaining free access to emerging technologies. In the next 10 years, U.S. universities are likely to face increasingly searching examinations of purpose as more and more members of their immediate constituencies ask who pays for, and who benefits from, university research and education. A major study on this topic is proposed as part of the total program but is not yet funded. The topic was extensively discussed by the Academic Advisory Board of the NAE during its January meeting, and, because of the timeliness of this topic, the NAE Program Office will carry out an exploratory symposium in 1990 on the role of university research and education in national economic development. The symposium and subsequent publication will include industrial, academic, and federal and state government perspectives on the topic with a special focus on ways and means for U.S. universities to chart a course and continue to make an important economic contribution through the next 20 years of global economic change. 8. Linking Technology Policy, Industrial Policy, and Trade Policy: A Comparative Study of the Policies of Industrialized Nations. Governments encourage, aid, monitor, oversee, regulate, and control the workings of private industry in the international economy through trade policy, industrial policy, and technology policy in various ways and to differing degrees. One foreign view of the U.S. government position toward industry notes that, "America is the only nation among the advanced industrial countries that does not have a Department of Industry which is responsible for industrial policy. Instead, the Department of Commerce and USTR [U.S. Trade Representative] preside and their only real concern is trade related matters and they criticize others for the failure of American industry" (from The Japan That Can Say "No"-portion attributed to Akio Morita of Sony Corporation). No transnational company is free of the limitations of its history, the legitimate laws and regulations of countries in which it operates, and, in a grander sense, its place in the development of the world economy. The U.S. economy, like the economies of other industrialized nations is a product of both private decisions and government preferences, regulations, and controls. In contrast to their Asian or most European competitors, U.S. firms appear to be driven more by short-term profit maximization than by considerations of market share or longer-term, know-how- based proprietary advantages. The reasons for these apparent national variations in corporate behavior-and the performance of companies in world markets attributed to these variations-are part management practice and accounting procedures, part financial market regulations and shareholder preferences, and 6 E-7 part government tax and fiscal policy, all combined with a host of other legal cultural, institutional, and political influences. These influences, in combination with a nation's trade policy-ad hoc or planned-and both implicit and explicit technology policy, significantly influence competitive outcomes in world marketplaces. The historical approach of U.S. policy is one that (a) largely downplays attention to the structural composition of U.S. industry, (b) asserts that any (or most) government technology targeting for commercial purposes is doomed to fail because of incompetence and politics, and (c) holds that the only reason the United States deviates from the pure principles of free international trade is because we are forced to by other nations less enlightened than ourselves. It has become increasingly clear that this traditional U.S. stance and the approach it engenders are virtually unique among the world's industrialized countries. Unlike Japan, France, the Federal Republic of Germany, or Sweden, the United States elects to eschew a coordinated national economic development effort centered on technology development and diffusion, trade managed actively to promote the comparative strengths of U.S.-based production, and government-sponsored mechanisms for developing an industrial structure that can yield high value-added jobs for its citizens. Right or wrong, the United States has taken a different path than its major trading partners, and the NAE proposes to explore this difference in approaches with a special focus on the degree to which U.S. technology policy (implicit and explicit) differs from the technology policies of other countries in its linkages to national development and trade strategies. The primary activity will be a small symposium involving experts-many from outside the United States-to explain and explore how such linkages are made, both informally and formally, in other industrialized nations. Although no comprehensive attempt will be made to assess the effectiveness of such efforts, a successful symposium and subsequent publication could serve as a benchmark for those interested in understanding "how the Japanese organize to penetrate new high-technology markets" or "what limits the ability of small U.S. high-tech companies to find other than British financing for their expansion." The Continuing Technology Agenda Program (major projects in FY 1991 budget) 9. Time Horizons and Technology Investments. An activity is under way to gather evidence and sort out claims about the investment and planning time horizons of U.S. businesses. The project has a special focus on the interaction of managerial decision making and the overall financial and economic environment-cost of capital, financial markets, mergers and acquisitions, changing company capital structures, and increasing debt levels. Of particular concern are the allegations that the time horizons of U.S. businesses are shortening relative to those of foreign-based competitors and that these shortened horizons are creating a reluctance to invest in activities with slow payoff profiles, which are necessary for firms to build advantage on the basis of advanced technology. The project will focus on three questions. Do U.S. firms have inappropriately short investment and decision-making horizons? If so, what are the primary contributing factors and consequences? What, if any, private and public-sector actions can be taken to alleviate the problem?The project will first examine methods to measure time horizons and their variations in different industries and countries. The second portion of the research will be to examine financial markets and managerial practices to determine the causes and consequences of the differences in time horizons among firms. 7 E-8 10. Foundations of Manufacturing Systems. The 1987 NAE-sponsored conference "Design and Analysis of Integrated Manufacturing Systems: Status, Issues, and Opportunities" pointed to a growing need to explore whether a manufacturing system discipline can be created. A committee has been formed to identify likely elements of such a discipline and will seek to interest experts, both educators and practitioners, in developing position papers on this topic. The results of this project will be a report describing and discussing the major intellectual elements of manufacturing system design, analysis, and operation. If it does prove possible to create such a discipline, or elements of it, both the practitioner and the educator should benefit-the practitioner by the development of generic tools that would assist in analyzing, designing, and controlling systems, and the educator because the teaching of generic tools and the representation of a systematic body of knowledge would be of great value to the student. Elements of a discipline might include agreement on definition of terms and the "basic laws" of manufacturing systems; a taxonomy of manufacturing, including reference languages, data structure, and a classification of functions; primitive descriptors for timing, control, scheduling, etc.; metrics for common descriptors, such as flexibility, adaptability, and economies of scale; and the design of processes. In addition, the discipline could explore basic theories for product design, process design, and system optimization. 11. NRC Support (Projects executed outside the NAE Program Office but supported wholly or in part by NAE funds) Manufacturing Forum. It has been recognized that in the United States there is no means for policymakers to communicate on such key issues as technology development and utilization, incentives and disincentives for investment, strategic national plans as they relate to U.S. manufacturing industries, current and future trends in the labor force, and long- term educational needs and opportunities for the manufacturing sector. In March 1988 the Academies held a workshop under the chairmanship of Morris Tanenbaum (NAE) of AT&T to explore means by which policymakers from government, industry, and universities can meet to discuss these issues that influence the competitiveness of manufacturing industries. As a result, a Manufacturing Forum is being formed under the chairmanship of Dr. Ruben Mettler, former chairman and CEO of TRW, Inc. The Forum, a joint project of the National Academy of Engineering and the National Academy of Sciences, is supported by the National Science Foundation and the Office of Science and Technology Policy. The Forum will operate for at least two years. New Directions in Catalysis Science and Technology. Catalysts are the engines of U.S. industries that manufacture chemicals, refine petroleum, produce polymers and fibers, and use precisely controlled chemical reactions for environmental control of pollutants. Although the United States has led the development of catalysis science and technology since the late 1940s, in recent years this leadership has come under an increasingly aggressive challenge from researchers in Western Europe and Japan. The NAE, in its continuing examination of competitiveness of U.S. industries and in support of its Technology and Environment program, is providing the NRC's Board on Chemical Sciences and Technology with partial support for its project "New Directions in Catalysis Science and Technology." A committee of the Board will prepare a substantive examination of catalysis research frontiers to focus attention on new directions in the field and serve as a brief guide to promising research opportunities for an audience of researchers in formative stages of their careers, scientists and engineers in related research areas, and research managers in industry and government. A high-visibility short report is planned for publication within one year of the project's full funding. 8 E-9 Committee on Women in Science and Engineering. It is widely agreed that, to a greater extent than for men, women with the potential to be excellent scientists and engineers have not been recruited and educated for this purpose. This, along with a new concern about the possibility of serious skill shortages in the future, led the National Research Council to organize a Planning Group to Assess Initiatives for Increasing the Participation of Women in Scientific and Engineering Careers. In 1988 this group recommended the establishment of a Committee on Women in Science and Engineering with the goal of increasing representation of women in scientific and engineering careers. The NAE will provide the NRC's Office of Scientific and Engineering Personnel (OSEP) with partial support for this committee's three-year effort contingent on OSEP obtaining an additional commitment of funds from other sources. The committee is composed of individuals representing the diversity among the scientific and engineering disciplines and includes educators, employers of scientists and engineers, and researchers of the status of women in science and engineering. The committee will act as a resource, information clearinghouse, and catalytic agent to encourage better understanding of the issues and to promote unified, structured interventions, research, and data-sharing. It is expected that these activities will result in the publication of information based on the committee's data-collection activities, workshop and symposia proceedings, and analytical studies. This information would be disseminated to sponsors and members of the scientific community, decisionmakers, and program managers in government, industry, and academe; researchers; employers; and others interested in the issues. Other NRC Projects for Potential NAE Funding (capstone money or total funding only). Engineering and the Law (CETS project initiated with a workshop held at the behest of the NAE; submitted for approval by NRC Governing Board Executive Committee on November 15, 1989) Bioprocess, Engineering: Research Priorities and Policy Options (Commission on Life Sciences project; approval by NRC Governing Board Executive Committee on July 11, 1989) Competitive Status of Electrical Apparatus Equipment Industry (CETS project initiated at the behest of several NAE members; approved by NRC Governing Board Executive Committee on April 7, 1989) International Intellectual Property Protection (OIA project, exploratory funding provided by NAE; full study project approved by NRC Governing Board Executive Committee on September 14, 1988) 12. Engineering as a Social Enterprise (1990 Annual meeting technical session). The 1990 Annual Meeting Technical Session symposium concluding the 25th anniversary year of the Academy explores the ways in which technology and society form inseparable elements in a complex sociotechnical system. Each influences and constrains the other in both obvious and subtle ways. In the short term, technology often appears to be in the driver's seat-engineers and nonengineers alike tend unthinkingly to see technology as the main determinant of social change. For the longer term, the influence of society on technology is, in fact, at least equally crucial. In the end, social judgment, as much as technical performance, determines what counts as successful engineering. If this is true engineers, as well as nonengineers, need to gain a better understanding of engineering as a sociotechnical enterprise. Symposium participants should come away with an increased appreciation of how society influences technological choice and how the engineering community can be more aware of the society it serves. 9 E-10 The Continuing Technology Agenda Program (projects to be completed in FY 1990) 1. Engineering as an International Enterprise. The project focuses on international technological interdependence and its implications for sustaining national technological competence. The 18-month project culminated in a symposium at the Beckman Center on 4-5 December 1989; a report will be published in early 1990. The study addresses three basic types of questions. The first of these relates to scope, rate of change, and composition of global sourcing of engineering activities. The second set of questions focuses on causes of global sourcing, how they differ from one industry to the next, and how they have changed over time. Finally, there are questions that address implications of global sourcing for U.S. engineering capabilities as well as for U.S. economic growth. This work involves documenting and analyzing trends toward global sourcing of engineering talent, with the goal of providing U.S. policymakers and the U.S. engineering community with insight into them. possible alternative futures for the U.S. engineering enterprise and strategies for achieving 2. Profiting from Innovation: Commercialization of New Technologies. Commercial application of technological advance is fraught with challenges and problems, both inside a company working to bring a new product to market and in the interactions the company has with its suppliers, product users, and competitors. With the intent of enhancing the commercialization process, the NAE will examine these challenges in order to assist U.S. companies establish market positions and achieve an adequate return on investment. The activity will conclude with a report offered for comment and discussion among the U.S. business leaders, with the ultimate aim of dissemination to business leaders, decisionmakers, the business press, and students of technology management. More specifically, this study addresses the following questions, among others: (1) Why are many inventive contributions not brought to commercial success by the inventor, or within the inventor's own company, and sometimes not within the inventor's own country? (2) How can the needs, values, and preferences of the ultimate users of new products be perceived and incorporated in the process of product development? (3) Once the need for a product has been identified, how are the decisions made about the technology that will be included in the product that is considered to meet the need? (4) How can product adaptation to meet the requirement of different categories of buyers with varied performance and price criteria be planned and managed? 3. Human Resources and Adoption of Workplace Technologies. One of the major strategies used by manufacturing and service firms to increase productivity and improve quality has been the implementation of new workplace technologies. Frequently, however, the results have been less than satisfactory, and as a result, managers, policymakers, and scholars are now paying increasing attention to the organizational and human factors that facilitate or constrain the adoption and implementation of new technologies. Organizations faced with new technological frontiers must balance factors such as hiring decisions, training, and incentives in an attempt to establish a basis for operation in a changed, more competitive environment. This interdisciplinary project is being conducted jointly with the Commission on Behavioral and Social Sciences and Education (CBASSE) of the National Research Council. Reports will be published based on a symposiumentitled "Designing for Technological Change: People in the Process," held 13-14 March 1989 at the Beckman Center. The 10 E-11 symposium and related activities have explored three specific technology areas-automated manufacturing technologies, office automation, and medical technologies. The objective of the activity ts to provide insights on how social science findings can be converted into prescriptive guidelines for technologists and managers. Another outcome may be the development of an agenda of issues requiring further research. 4. Fostering Flexibility in the Engineering Work Force. Early in 1989, the Education Advisory Board of the NAE identified the adaptability of the engineering work force-i.e., the ability to transfer a given set of engineering skills among engineering fields and activities, between engineering and nonengineering fields and activities, and among sectors of the economy-as an issue with important implications for the United States' ability to exercise technological leadership and to compete effectively in international markets. The NAE asked the National Research Council's Office of Scientific and Engineering Personnel to conduct a study of what is known, and what needs to be known, about adaptability among the engineering work force in the United States, as a prerequisite to understanding what policy mechanisms may be needed, and what action might be taken to enhance the adaptability of the U.S. engineering work force. OSEP convened a steering committee of engineers and scientists from industry, academe, and the professional engineering societies and conducted a workshop on 29 September 1989 to explore the issue. The committee's principal conclusions will appear in the final report (currently in press) to the NAE. 5. Engineering, Engineers, and Engineering Education in 21st Century. Early in 1989, the Directorate for Science and Engineering Education (DSEE) of the National Science Foundation (NSF) requested the NAE to provide guidance to the NSF on the evolving character of engineering work, its effect on the characteristics of engineers who do the work, and its effect on engineering education. In response to the request, the NAE convened a workshop (supported by a grant from the NSF) on 19-20 December 1989 to elicit the ideas of 18 experts from a variety of fields--engineering, industry, education, government, etc.--on what engineering and engineers might be like as they evolve in the next century. Bold new insights were sought, without presumptive assessments of the ideas and without an expectation of consensus. The resulting collection of views will be submitted to the NSF in the form of a letter report, to be used to obtain reactions and stimulate discussions in the wider professional community. 11 TRANSFER SHEET BUSH PRESIDENTIAL MATERIALS PROJECT COLLECTION Bush PResideNtiAl RecoRds ACC.NO: Office of Speechwriting The following material was withdrawn from this segment of the collection and trasferred to the XXX AUDIOVISUAL COLLECTION BOOK COLLECTION MUSEUM COLLECTION OTHER (SPECIFY: ) DESCRIPTION: Photograph JAck S. Kilby - DRAPeR ENgiNeeRiNg AWARD Photograph Robert N. Noyce - DRAPeR ENgiNeeRiNg AWARD SERIES BOX NO. Office of Speechwaiting Speech File- BAckup FILE FOLDER TITLE: DRAPER ENgiNeeRiNg Award 2/20/90 [OA 6894 TRANSFERRED BY: DATE OF TRANSFER: RFH 6/27/96 RECEIVED BY: DATE RECEIVED many A. Fruch NEWS From National Academy of Engineering The National Academy of Engineering is a private organization es- tablished in 1964. It shares in the responsibility given the National Academy of Sciences under a congressional charter granted in 1863 to advise the federal government on questions of science and tech- nology. This collaboration is implemented primarily through the Na- tional Research Council. The National Academy of Engineering also Date: Oct. 3, 1989 recognizes distinguished engineers, sponsors engineering programs aimed at meeting national needs, and encourages education and Contact: Stephen Kay, (202) 835-8843 research. or Gail Porter (202) 334-2138 2101 Constitution Avenue, NW, Washington, DC 20418 CREATORS OF INTEGRATED CIRCUIT RECEIVE WORLD'S TOP ENGINEERING AWARD FOR IMMEDIATE RELEASE WASHINGTON The National Academy of Engineering (NAE) has awarded the first international Charles Stark Draper Prize to Jack S. Kilby and Robert N. Noyce. Each will receive a gold medal and the two will share the $350,000 cash award the largest prize in the world given exclusively for engineering achievement. The two will receive their award at a ceremony in Washington, D.C., in February. Kilby and Noyce are recognized by the scientific and engineering community as independent co-inventors of the monolithic (meaning formed from a single crystal) integrated circuit, better known as the semiconductor microchip. The NAE is honoring them as well for their separate work in bringing the integrated circuit into successful commercial production and application in commercial products. Kilby is an independent consultant in Dallas and chief technical officer for the Houston Area Research Center. He is also a former assistant vice president for Texas Instruments. Noyce is the current president and chief (OVER) NAE 25 - 2 - executive officer of Sematech in Austin, Texas, as well as co-founder of Fairchild Semiconductor and the Intel Corp. "Very few things have changed the world as dramatically as the integrated circuit," said Robert M. White, president of the National Academy of Engineering. "The development of the integrated circuit was the single most important event that helped usher in the Information Age. Like the invention of the telephone, the light bulb, or the automobile, the creation and widespread practical application of the integrated circuit has fundamentally changed our lives -- transforming computation, communications, manufacturing, and transportation and giving birth to a host of entirely new industries and services. The Academy is honored to present Jack Kilby and Bob Noyce with the first Charles Stark Draper Prize." The Draper Prize was established by the NAE in 1988 and is endowed by the Charles Stark Draper Laboratory Inc. of Cambridge, Mass. Charles Draper - - "Doc" to his friends and associates -- was the father of modern inertial navigation systems. He conceived the basic idea of combining gyroscopes with an accelerometer to provide precise course corrections for long-distance navigation. He then converted this idea into practical systems now universally used in aircraft, space vehicles, strategic missiles, and submarines. Draper also developed the sophisticated navigational system that landed the Apollo astronauts on the moon and returned them safely to earth. The Draper Prize, to be awarded every two years, honors individuals who have contributed significantly to the advancement of engineering and whose achievements have produced important benefits to the "well-being and freedom of all humanity." This year's recipients were chosen by a 13-member committee (MORE) - 3 - of prominent engineers from industry, government, and academe. Robert C. Seamans Jr., senior lecturer at the Massachusetts Institute of Technology, chaired the committee. A complete list of members is attached. "We believe," said White, "that the Draper Prize will focus world attention on the important contributions of engineers in the same way that the Nobel Prize now focuses attention on the accomplishments of scientists." Despite his many previous awards, Noyce said that receiving the Draper Prize is particularly special for him because "it is given by a prestigious body in the name of a man for whom I had a great deal of respect." Thirty years after the integrated circuit was developed by Kilby and Noyce, the ubiquitous integrated circuit is an essential component in items ranging from consumer goods to manufacturing equipment to medical imaging devices (such as the CAT scan) to automated bank tellers. Hand-held calculators, digital watches, automatic cameras, videocassette recorders, compact discs, and facsimile machines are among the multitude of everyday products that depend on integrated circuits. The invention of the integrated circuit in the late 1950s represented an enormous improvement in capability for storing and manipulating information in a very small space. Prior to the advent of the integrated circuit, electronic products such as computers were made with miniaturized, discrete components such as transistors, resistors, and capacitors. Depending on the electronic function being performed, the manufacture of these products required that thousands of electrical components be individually interconnected with wire and solder. Integrated circuits, by contrast, are constructed on a solid piece of (OVER) - 4 - silicon crystal. Through techniques that incorporate photographic processes and principles similar to those used in silk screening or lithography, hundreds of thousands of electronic components may be constructed and interconnected simultaneously in a space the size of a newborn's fingernail. The variety of electronic functions previously achieved through individual components is accomplished instead by creating a kind of bumpy silicon "sandwich," in which different layers and regions of the material have different electrical properties. The small size, low cost, high reliability, and vastly increased speed of integrated circuits allowed engineers to create an array of new products. Production of personal computers, for example, would be impossible with the old technology. Since Kilby's and Noyce's pioneering work, the information- processing capacity of a single integrated circuit "chip" has doubled about every three years -- a rate of improvement in performance that is unprecedented for any other type of technology. "When I started in electronics," commented Kilby, "all equipment was built with vacuum tubes. The transistor had not yet been invented. I don't think anyone would have thought at that time in terms of the revolution that's come about." Kilby and Noyce were also responsible for the commercial success and expansion of the integrated circuit within the electronics industry. Jack Kilby led the development of the first computer that used integrated circuits and that of a family of integrated circuits for the improved Minuteman missile, the first military system to use integrated circuits. He also co- invented the hand-held, solid-state calculator and invented the semiconductor (MORE) - 5 - gate array. His efforts helped to establish Texas Instruments as one of the world's largest manufacturers of integrated circuits. Noyce co-founded Fairchild Semiconductor in 1957, which provided integrated circuits to the National Aeronautics and Space Administration for the on-board computer of the Gemini space capsule, one of the company's first sales of the new technology. In 1968, he co-founded Intel Corp., the first company to produce high-density memory components and microprocessors. These developments led to the present far-reaching applications and accessibility of the personal computer. Both Kilby and Noyce have received additional honors for their inventions. They were named as joint recipients of the Franklin Institute's Ballantine Medal in 1967 and the Cledo Brunetti Award of the Institute of Electrical and Electronics Engineers in 1978. Kilby received the National Medal of Science in 1969, and in 1982 was inducted into the National Inventors Hall of Fame of the U.S. Patent and Trademark Office. A year later, Noyce was also inducted into the Patent Office's Hall of Fame. Noyce also received the National Medal of Science in 1979 and the National Medal of Technology in 1987. Both are members of the National Academy of Engineering. Kilby became an independent consultant in 1970 following a 12-year career at Texas Instruments. He currently lives in Dallas, Texas. In 1988 Noyce was named president and chief executive officer of Sematech in Austin, Texas, where he currently resides. He served Intel as president from 1968 to 1975, as chairman of the board from 1975 to 1979, and as vice chairman from 1979 to the present. The NAE is a nonprofit organization comprising approximately 1,500 (OVER) - 6 - members representing all engineering disciplines. Founded in 1964, it advises the federal government on issues in engineering and technology, sponsors engineering programs aimed at meeting national needs, and promotes the public understanding of the important role engineering and technology play in everyday life. # # # jt/gp: 1,3,7,8,12,S CHARLES STARK DRAPER PRIZE COMMITTEE ROBERT C. SEAMANS, JR. (Chair) Senior Lecturer, Department of Aeronautics and Astronautics Massachusetts Institute of Technology LEW ALLEN, JR. Director, Jet Propulsion Laboratory California Institute of Technology ERICH BLOCH Director National Science Foundation HARVEY BROOKS Professor of Technology and Public Policy, Emeritus John F. Kennedy School of Government Harvard University SOLOMON J. BUCHSBAUM Executive Vice President, Customer Systems AT&T Bell Laboratories ROBERT A. CHARPIE Retired Chairman Cabot Corporation THOMAS E. EVERHART President California Institute of Technology JOHN W. FISHER Professor of Civil Engineering and Director, ATLSS Engineering Research Center Fritz Engineering Laboratory Lehigh University ALLEN E. PUCKETT Chairman Emeritus Hughes Aircraft Company SIMON RAMO Retired Director Emeritus TRW Inc. DANIEL I. C. WANG The Chevron Professor of Chemical Engineering Massachusetts Institute of Technology ALVIN M. WEINBERG Distinguished Fellow, Institute for Energy Analysis Oak Ridge Associated Universities SHEILA E. WIDNALL Abby Rockefeller Mauze Professor of Aeronautics and Astronautics Massachusetts Institute of Technology JACK S. KILBY BIOGRAPHY Jack S. Kilby, co-inventor of the integrated circuit, was born in Jefferson City, Mo., in 1923. He is currently an independent consultant in Dallas and chief technical officer for the Houston Area Research Center. Kilby graduated from the University of Illinois in 1947 with a bachelor's degree in electrical engineering, and in 1950 received a master of science degree in electrical engineering from the University of Wisconsin. After designing small electronic parts for Centralab in Milwaukee, Wis., Kilby joined Texas Instruments Incorporated in 1958, where he set out to devise a solid- state instrument that could make electronics simpler, faster, and more reliable. His work culminated in the successful operation of the integrated circuit. Kilby retired from Texas Instruments in 1970. Since then, he has served as a consultant on integrated circuits and semiconductors for a variety of firms. In 1982 he was elected chairman of the Department of Defense Advisory Group on Electron Devices (AGED). Affiliated with AGED since 1966, Kilby has given counsel to several U.S. defense organizations. In addition to his nearly 60 U.S. patents, Kilby has received numerous awards, including the Ballantine Medal from the Franklin Institute and the Cledo Brunetti Award of the Institute of Electrical and Electronics Engineers (IEEE), both of which he shared with Robert Noyce. He received the National Medal of Science in 1969, and in 1982 was inducted into the U.S. Patent Office's National Inventors Hall of Fame. Other honors include the IEEE's Sarnoff Medal; the Zworykin Medal from the National Academy of Engineering; the Medal of Honor from the IEEE, and the Holley Medal of the American Society of Mechanical Engineers. Further recognition of his accomplishments in engineering, technology, and the sciences include the Alumni Honor Award from the University of Illinois's College of Engineering, the Alumni Achievement Award from the same institution, and membership in the National Academy of Engineering. ROBERT N. NOYCE BIOGRAPHY Robert N. Noyce, co-inventor of the integrated circuit, was born in Burlington, Iowa, in 1927. President and chief executive officer of Sematech in Austin, Texas, since 1988, he is also vice chairman of Intel Corporation, a firm he co-founded. Noyce graduated from Grinnell College in 1949 with a bachelor's degree in physics and mathematics and a membership in Phi Beta Kappa. He earned his doctorate in physical electronics at the Massachusetts Institute of Technology in 1953. Following college, Dr. Noyce engaged in research at Philco Corporation and Shockley Semiconductor Laboratory. He co-founded Fairchild Semiconductor Corporation in 1957. In 1968, Noyce co-founded Intel with long-time associate Gordon E. Moore with the objective of making large-scale integration a practical reality. Today the company is the nation's third-largest semiconductor producer. Noyce was a founding member and the first president of the Semiconductor Industry Association. He also was a member of the President's Committee on Industrial Competitiveness and the Defense Science Board. Noyce holds 16 patents for semiconductor devices, methods, and structures. He and Jack Kilby have jointly received the Ballantine Medal of the Franklin Institute and the Cledo Brunetti Award of the Institute of Electrical and Electronics Engineers (IEEE). He and Gordon Moore have received the Harry Goode Award for leadership in computer science from the American Federation of Information Processing Societies, Inc. Dr. Noyce was awarded the National Medal of Science in 1979 and and the National Medal of Technology in 1987. He has also received the Medal of Honor from the IEEE and the Faraday Award from the Institute of Electrical Engineers (Great Britain). He is a member of the National Academy of Engineering, the National Academy of Sciences, the American Academy of Arts and Sciences, and is an IEEE Fellow. Dr. Noyce has been inducted into both the U.S. Patent and Trademark Office's and Fortune magazine's National Inventors Hall of Fame. He also is a member of Grinnell College's Board of Trustees. NATIONAL ACADEMY OF ENGINEERING 2101 Constitution Avenue, N.W. Washington, D.C. 20418 THE NATIONAL ACADEMY OF ENGINEERING History and Objectives "The genie will not go back in the bottle, the rush of technology will not slow down, and we cannot stop the world and get off to take a breather. Our challenge is to learn not only to live in a global marketplace, but thrive in it so America can maintain its leadership position." Walter B. Wriston Retired Chairman, Citicorp/Citibank The United States has long stood in the front ranks of technology. Over the past twenty-five years, however, the staggering expansion and acceleration in the creation of new technologies around the globe has made it increasingly difficult for nations -- including our own -- to adapt. Governments require ever greater technical expertise in order to make enlightened policy decisions in an age of technology. The National Academy of Engineering of the United States (NAE), a private, nonprofit institution, has dedicated itself to the wise use of technology in this country and around the world. In the United States, the Academy serves as an adviser to the federal government, helping to apply the nation's best engineering talent to the field of public policy. Domestically and abroad, the NAE provides a focal point for engineering excellence by recognizing outstanding engineering achievement and encouraging the study and practice of the engineering disciplines. The NAE: Its Organization and Purposes The NAE was established in 1964 under the congressional charter of the National Academy of Sciences, which was granted in 1863 during the Lincoln administration. It is an autonomous Academy in its management and membership. Purposes of the NAE are to: Promote public education and discussion of technology, trade, engineering, innovation, education, and the impact that technology has on our society; Advise the federal government, when called upon, on matters of national importance pertaining to engineering and technology; Assist the changing technological and engineering needs of America, and encourage engineering activities that are in the national interest; NAE 25 THE NATIONAL ACADEMY OF ENGINEERING - 2 Recognize outstanding contributions to the nation by leading engineers ; and Promote public awareness of the role of engineering and technology. Selected NAE Activities The NAE conducts and oversees a large number of programs whose common goal is to maintain and enhance the technological health of the country. The NAE believes that the economic well-being of the United States is indissolubly linked to the advancement of technology. Recently, in response to the deep concern over the deterioration of the competitive position of many sectors of U.S. industry, the NAE prepared reports on the role of technology in economic growth, the state of engineering education in the United States, ways to improve manufacturing productivity, and the competitive status of various industries. These examinations have led the NAE to recommend new courses of action for government, industry, and academia in order to strengthen the technology base of the nation in an age of global competition. The Academy also has focused on national space and environmental policies, as well as on engineering research priorities. The NAE's many programs, along with those carried out within the National Research Council (described below), require the efforts of more than 400 NAE members every year, who give their. time voluntarily and without compensation. National Research Council Most NAE activities are implemented by the National Research Council, which also serves the National Academy of Sciences. With more than 900 study committees, the Research Council conducts studies of national importance involving science and technology, whenever called upon by Congress or agencies of the federal government. More than 9,500 men and women serve on a volunteer basis on Research Council committees. Membership Many of the nation's engineering and technology leaders in industry, government, and universities are members of the NAE. Members are elected to the Academy on the basis of pioneering achievements in the development of new technologies, for important contributions in engineering practice and theory, and for demonstrated leadership in the technology community. All engineering disciplines are represented by the NAE membership, which totals approximately 1,500 persons, including more than 100 foreign associates. More than half of the NAE's members are from industry and around 40 percent are from academia. Each year, the Academy elects about 70 new members. THE NATIONAL ACADEMY OF ENGINEERING - 3 Governing Council NAE members elect six officers and twelve additional members to the NAE Council; this body governs and directs the activities of the Academy. Officers for 1989-90 are: Robert M. White, President Edward R. Kane, Treasurer President Former President National Academy of Engineering E.I. du Pont de Nemours and Co. John F. Welch Jr., Chairman Alexander H. Flax, Home Secretary Chairman and Chief Executive Officer President Emeritus General Electric Co. Institute for Defense Analyses Ralph Landau, Vice President Gerald P. Dinneen, Foreign Secretary Consulting Professor of Economics Vice President, Science and Technology Stanford University (Retired) Honeywell Inc. NEW YORK TIMES NEW YORK, MONDAY, JULY 27, 1987 Charles S. Draper, Engineer; Guided Astronauts to Moon By JOHN NOBLE WILFORD Charles Stark Draper, a pioneer in terrifying airplane rides to prove some In 1973, the laboratory became inde- advanced guidance technology for air- point of aerodynamics. As a professor pendent of M.I.T. and was renamed the craft and missiles and developer of the himself, he was a compulsive and crea- Charles Stark Draper Laboratory. navigation system that steered Amer- tive tinkerer. Dr. Draper was awarded the Na- icans to the moon and back, died Satur- He was born Oct. 2, 1901, in the small tional Medal of Science in 1965. He was day at Mount Auburn Hospital in Cam- town of Windsor, Mo. After two years an honorary fellow of the American In- bridge, Mass. He was 85 years old. -at the University of Missouri, he trans- stitute of Aeronautics and Astronau- Described by his peers as one of the ferred to Stanford University and tics. He was also inducted into the Na- foremost engineers of our time, Dr. earned a bachelor's degree in psychol- tional Inventors Hall of Fame and the Draper was a longtime professor of ogy in 1922, intending to become a phy- International Space Hall of Fame. aeronautics and astronautics at. the sician. But on a trip East he visited the Survivors include his wife, the for- Massachusetts Institute of Technology. M.I.T. campus in Cambridge, became mer Ivy Hurd Willard; three sons, He founded M.I.T.'s Instrumentation fascinated with work in aeronautical James and Michael of Newton, Mass., Laboratory to develop his inventions engineering and decided to enroll. He and John of Hampton Falls, N.H.; a applying gyroscopic principles for learned to fly an open-cockpit biplane, daughter, Martha Draper Ditmeyer of World War II gunsights and for the earned another bachelor's degree and Fairway, Kan., and six grandchildren. guidance systems that made possible then a doctorate in physics in 1938. Funeral services will be private. intercontinental ballistic missiles. The following year, Dr. Draper be- Howard W. Johnson, a former chair- came a full professor at M.I.T. and man of the M.I.T. Corporation, said, founded the Instrumentation Laborato- "His research created a whole new in- ry. The group's first major achieve- dustry in intertial instruments and sys- ment was the Mark 14 gvroscopic gun- tems for airplanes, ships, submarines, missiles, satellites and space vehi- sight for the Navy, which made it possi- ble for antiaircraft guns to take deadly cles." accurate aim on attacking aircraft 'In the Category of Genius' even while a ship was rolling and toss- Inertial guidance is based on the ing. familiar principle that keeps a child's Out of this research came the guid- gyroscopic top from falling: a rapidly ance systems for jet fighter planes and sp/nning wheel will resist forces work- the Paiaris, Poseidon and Trident sub- ing to twist it from the plane in which it marines and missiles as well as key is revolving. For his guidance systems components for the Atlas and Titan Dr. Draper used three spínning gyros, rockets. pr Draper's laboratory was each responsive to only one direction of chosen in 1961 to develop the Apollo motion - up and down, right and left guidance and navigation system. and rolling. These gyros formed a basis As Dr. Draper recalled in an inter- view several months before the first for a self-contained system that re- members an object's course of flight moon landing in 1969, James E. Webb, and can measure changes in that the space agency administrator, told him: 'Stark, this is going to be a hell course.- The system devised by Dr. Draper of a job. Can it be done?' I said yes. We for the moonbound Apollo spacecraft used to give lunar navigation problems as thesis work for our students, and. I included telescopes, a sextant and a knew it could be done. 'It'll be ready be- computerized inertial guidance device that told the astronauts where they fore you need it,' I told Webb - and, I were in space, where they were headed might add, it is." and how fast. Such data were used to A few months after the moon land- direct all the spacecraft's propulsion ing, Dr. Draper was forced to step systems. down as director of the Instrumenta- James Killian Jr., a former M.I.T. tion Laboratory. He was caught in the president, described Dr. Draper as a middle of widespread protests against. "great teacher as well as an engineer military work being done on university whose technological achievements campuses. He insisted that any organi- clearly placed him in the category of zation has an obligation to society to genius." provide "services which fall within its Doc Draper, as he was usually called, special competence," adding: "That became a legend on the M.I.T. campus includes defense work. If defense is ne- almost from the day he arrived there glected, all is lost." as a student in 1922. A stocky man with a fighter's broken nose and a scrappy temperament to match, he was the kind of student who took professors on Office of Public & Employee Communication The Charles Stark Draper Laboratory, Inc. 555 Technology Square, Cambridge, Massachusetts 02139 Telephone (617) 258-2605 DR. CHARLES STARK DRAPER (1901 - 1987) Founder and Senior Scientist The Charles Stark Draper Laboratory The "father of inertial navigation," Dr. Charles Stark Draper evolved the theory, invented and developed the technology, and led the effort that brought inertial navigation to operational usage in aircraft, submarines, missiles, and space vehicles. Inertial guidance systems use gyroscopes (rotating devices that react to changes in direction) and accelerometers (instruments that detect changes in velocity over time) to keep a steady course. The information obtained from the gyroscopes and the accelerometers is fed into a computer, which calculates the degree of drift from the intended course and recommends appropriate corrections. Completely automatic inertial navigational systems can sense tiny deviations from the intended course and quickly correct them, resulting in very precise navigation anywhere in the world. Before Draper developed his inertial guidance systems, navigators depended upon more laborious methods, such as celestial navigation and radio navigation. Founder of Draper Laboratory in Cambridge, Mass., and Institute Professor Emeritus at Massachusetts Institute of Technology, "Doc" Draper advanced from the position of assistant professor in the department of aeronautics and astronautics at MIT in 1935 to the post of Institute Professor in 1966. During his tenure at MIT, he also held posts as associate professor and department head. Dr. Draper stood among the pioneer members of the first group of aircraft engineers. Such monumental efforts as the Apollo landing on the moon and the guidance systems for all strategic missiles in the U.S. inventory, both land- and sea-based, bear the stamp of his genius. Nationally, Dr. Draper's work has created a multibillion-dollar industry. First sponsored by the Sperry Gyroscope Co., Dr. Draper's engineering work led to the development of the Mark 14 gunsight during World War II. He continued work with gun pointing and firing control developments until the late 1950's, which earned him the title "Mr. Gyro" because of the persistence and effectiveness with which he applied the gyroscope to guidance and control instruments and to gun, bomb, and rocket pointing and firing control instruments and systems. His later research resulted in the development of a complete inertial navigation system for manned and unmanned vehicles, which perform successfully in unfavorable weather and do not rely on information from external sources. DR. CHARLES STARK DRAPER -- 2 In 1942 the USS South Dakota using Dr. Draper's gunsights shot down 32 Japanese kamikazes, an unprecedented anti-aircraft score. Under Dr. Draper's supervision, the MIT FEBE system in 1949 was the first to employ inertial properties of gyroscopic instruments for purposes of aircraft navigation. The Space Inertial Reference Equipment -- SPIRE -- followed in 1953. As the first fully inertial system, SPIRE is considered a milestone in the development of the inertial art. SPIRE Jr., an improved version of the system, was ready for flight in 1957. Dr. Draper's work on inertial navigation systems for marine vessels proved successful in the 1954 sea tests of MAST (Marine Stable Element). This led to the SINS (Submarine Inertial Navigation System) later that year. The Air Force applied Dr. Draper's work on inertial guidance for intercontinental ballistic missiles to the THOR guidance system. Since 1957, Draper Laboratory has developed the guidance systems for the family of Fleet Ballistic Missiles for the U.S. Navy: Polaris, Poseidon, Trident I, and is currently working on the Trident II system. Dr. Draper's work on the guidance and navigation system for NASA's historic Apollo moon landing was the largest single program at Draper Laboratory until the Trident II program. Born in Windsor, Mo., on Oct. 2, 1901, Dr. Draper began his college work in arts and sciences at the University of Missouri in 1917. In 1919 he entered Stanford University, Calif., and graduated in 1922 with a B.A. in psychology. He entered MIT the same year, earning a B.S. in electrochemical engineering in 1926, S.M. in 1928 without specification of department, and Sc.D. in physics in 1938. Dr. Draper extended the curriculum of courses in the fields of instrument engineering and fire control while he was head of the department of aeronautics and astronautics at MIT. He wrote extensively in the fields of instrumentation and control, and served as consulting engineer to many aeronautical companies and instrument manufacturers. He held a number of patents for measuring and control equipment. Dr. Draper's small team of students and technicians at MIT expanded to become the Instrumentation Laboratory (a part of MIT). The laboratory later divested from MIT in 1973, and formed a separate, nonprofit research and development laboratory -- The Charles Stark Draper Laboratory, Inc. Dr. Draper was a member of several government science advisory groups and served as chairman of the National Inventors Council. He was a past president of the International Academy of Astronautics; an Honorary Fellow of the American Institute of the Aeronautical Sciences and the British Institution of Mechanical Engineers; and an honorary lifetime member of the Instrument Society of America. He held an honorary fellowship with the British Interplanetary Society and the Royal Astronautical Society, and was an honorary member of the German Society for Guidance and Navigation and the British Institute of Navigation. He was also a fellow of the American Physical Society, the American Academy of Arts and Sciences, the American Society of Mechanical Engineers, the American Association for the Advancement of Science, the Institute of Electrical and Electronics Engineers, the American DR. CHARLES STARK DRAPER -- 3 Astronautical Society; and a member of the National Academy of Engineering, the National Academy of Sciences, the American Institute of Consulting Engineers, the Society of Automotive Engineers, the American Ordnance Association, the American Society for Engineering Education, the Massachusetts Society of Professional Engineers, the New York Academy of Sciences, and the French National Academy. He was a past president of the MIT Soaring Society, and a member of Sigma XI, Tau Beta Pi, and Sigma Alpha Epsilon. Among his more than 70 honors and awards, five have come from foreign countries, including the U.S.S.R. and Czechoslovakia. He was inducted in the National Inventors Hall of Fame and into the International Space Hall of Fame. He received the prestigious Langley Medal of the Smithsonian Institution, the NASA Public Service Award, the Dr. Robert H. Goddard Trophy of the National Space Club, and the National Medal of Science from President Lyndon Johnson. Dr. Draper was named the New England Inventor of the Year in 1981. In 1978, MIT established the Charles Stark Draper Professorship of Aeronautics and Astronautics in his honor. Dr. Draper received the "Engineering for Gold Award" from the National Society of Professional Engineers in 1984. The society cited his work in inertial guidance systems as one of the 10 outstanding engineering achievements of the past 50 years. Among the honorary degrees he received are doctoral degrees from Eidgenossische Technische Hochschule, Zurich, Switzerland, in 1966; the University of Portland, Portland, Oregon, in 1970; the University of Missouri, Rolla, in 1975; and Boston University in 1984. Many of Dr. Draper's former students are leaders in government, industry, the military, and academia. Dr. Draper was married to Ivy Hurd Willard, with whom he had three sons, one daughter, and six grandchildren. His children are James Draper and Michael Draper of Newton, Mass.; John Draper of North Andover, Mass.; and Martha Draper Ditmeyer of Fairway, Kansas. OPENING STATEMENT -- DRAPER PRIZE NEWS CONFERENCE Robert M. White, President National Academy of Engineering October 3, 1989 Good morning. It is a pleasure to be here today to announce the recipients of the first international Charles Stark Draper Prize. Following extensive deliberations conducted over the past year, the National Academy of Engineering's Charles Stark Draper Prize Committee has selected Jack S. Kilby and Robert N. Noyce as the first recipients of the Draper Prize, the largest prize in the world given exclusively for engineering achievement. We are fortunate to have Jack Kilby with us here today, as well as Robert Seamans Jr., chairman of the Draper Prize Committee, and Joseph Charyk, head of the Draper Laboratory Inc. of Cambridge, Mass., which endowed the prize. Robert Noyce had hoped to attend but was unable to because of prior commitments. Kilby and Noyce are being honored here today for their separate co-invention of the single-crystal integrated circuit, better known as the semiconductor microchip. The award is also based on their skill in bringing the integrated circuit to successful production and application in commercial products. - 2 - Very few things have changed the world as dramatically as the integrated circuit has. Its development was the single most important event that helped usher in the Information Age. Like the invention of the telephone, the light bulb, or the automobile, the creation and widespread practical application of the integrated circuit has fundamentally changed our lives -- transforming computation, communications, manufacturing, and transportation, and giving birth to a host of entirely new industries and services. In just a moment, Dr. Seamans will describe the Draper Prize Committee's selection process, followed by some remarks by Mr. Kilby. But first, I'd like to tell you something about Charles Stark Draper, for whom this prize is named. Draper is often referred to as the "father of inertial navigation," and is best known for creating and developing the navigation guidance system that landed the Apollo astronauts on the moon. Similar versions of this system today continue to provide aircraft, submarines, missiles, and space vehicles with pinpoint navigational accuracy. Draper's work in this important area strengthened our nation's space and defense programs and evolved into an industry that generates billions of dollars in sales each year. We are grateful to the Charles Stark Draper Laboratory Inc. for providing the endowment necessary to establish this prize in "Doc" Draper's name. It is fitting that the prize should be - 3 - named after Draper because he epitomizes the kind of engineering excellence -- especially the successful commercial application of new technologies -- that we want to highlight with this prize. The Draper Prize, with its accompanying $350,000 cash award and gold medal, will be given every two years to an individual or individuals who have made outstanding contributions to the advancement of human welfare and freedom through their engineering achievements. We believe that the Draper Prize will focus world attention on the important contributions of engineers to society in the same way that the Nobel Prize now focuses attention on the accomplishments of scientists. At this point, Dr. Seamans will describe the committee's selection process and tell you why we believe that Jack Kilby and Robert Noyce aptly meet the Draper Prize criteria described above. Currently a senior lecturer at the Massachusetts Institute of Technology, Dr. Seamans is uniquely qualified to chair the Draper Prize Committee as a former Secretary of the Air Force, former president of the National Academy of Engineering, and as one of "Doc" Draper's former students. Thank you. OPENING STATEMENT -- DRAPER PRIZE NEWS CONFERENCE Robert C. Seamans, chairman, Charles Stark Draper Prize Committee, National Academy of Engineering, and senior lecturer, Massachusetts Institute of Technology October 3, 1989 Thank you, Bob. During my 48-year career in numerous government, industry, and academic posts, I have held many difficult jobs, but serving as chairman of the Draper Prize Committee has to rank among the most challenging. Choosing just one engineering achievement that has had the greatest impact in advancing human well-being and freedom is a very tall order. We are literally surrounded by the products of engineering from the moment we wake up to an automatically prepared cup of coffee, put on our no-iron, wash and wear clothing, make a telephone call from our cars while driving to work, and sit down at a personal computer to write a letter, balance the books, read the mail, or draw a picture. Our 13-member committee of prominent engineering leaders from industry, academia, and government began the job of selecting the Draper Prize recipients in November of 1988. We invited more than six thousand individuals, institutions, and professional societies from around the world to submit nominations. We also welcomed any unsolicited nominations. After several long and detailed discussions about the many high quality submissions we received, we unanimously settled on Jack Kilby and Robert Noyce for a number of what we believe to be persuasive reasons. First, their separate co-invention of the monolithic integrated circuit has been credited by many as the initial step of the microelectronics revolution and the advent of the Information Age. This one invention has affected virtually all industries from banking, to transportation, to communications, while at the same time having a profound effect on everyday living through such consumer products as the pocket calculator, digital watches, automatic cameras, videocassette recorders, and compact discs. Second, the men who created this invention were instrumental in designing cost-effective manufacturing processes to produce actual commercial products. Kilby's work with colleagues at Texas Instruments led to development of the first computer made with integrated circuits and later to production of the first hand-held calculator. As co-founder of Fairchild Semiconductor, Noyce helped produce the computerized navigation system used for the Apollo missions. Later as co-founder of Intel Corp., his company produced the first high-density memory components and microprocessors, the critical element that made production of personal computers practical. Finally, our committee was convinced that no other invention in modern times has had as pervasive an effect in meeting the true spirit of the Draper Prize by advancing human welfare and freedom. It has often been said that just as the first Industrial Revolution, based on motors and improved machinery, freed humans from back-breaking labor, the second industrial revolution, based on the semiconductor microchip, has freed us from mind-numbing intellectual chores. For these reasons, the National Academy of Engineering is very pleased to honor Jack Kilby and Robert Noyce as the first recipients of the international Charles Stark Draper Prize. We are planning a special event in February during National Engineers Week, when they will formally receive a gold medal and $175,000 each. It is a fitting reward for two men whose work has done so much to improve all of our lives. At this point, perhaps Jack Kilby would like to make a few comments and then we will be happy to answer your questions. Office of Public & Employee Communication The Charles Stark Draper Laboratory, Inc. 555 Technology Square, Cambridge, Massachusetts 02139 Telephone (617) 258-2605 THE CHARLES STARK DRAPER LABORATORY, INC. A Brief Overview The Charles Stark Draper Laboratory, Inc., is a private, nonprofit corporation dedicated to scientific research, development, and education. It is engaged primarily in research and development of guidance, navigation, and control systems (inertial, satellite, and radio-aided); fault -tolerant system design; precision pointing and tracking system design; flexible and automated manufacturing methods; undersea-vehicle systems design; advanced spacecraft, both manned and unmanned; and specialized scientific instrumentation. Located adjacent to the Massachusetts Institute of Technology (MIT) in Cambridge, Mass., the Draper Laboratory was originally established as the Instrumentation Laboratory of MIT in 1938. It was renamed in 1973 to honor Charles Stark Draper, the technological pioneer whom, in the words of James Killian, Jr., a former MIT president, was, "...a great teacher as well as an engineer whose technological achievements placed him in the category of genius." Presently, the Draper facility contains more than 100 laboratories. In its early years, the laboratory pioneered the development of gyroscopically based gun pointing and firing systems for shipboard and fighter-aircraft use. These systems are driven by three spinning gyros, each of which responds to only one direction -- up and down, right and left, and rolling. This enabled the development of a system that remembers an object's course in flight and can measure changes in that course. Over the past 50 years, the Draper Laboratory has: continually improved the performance levels of new inertial components and systems; been a leader in the development of highly reliable digital computers and their applications to fly-by-wire vehicle controls for vehicles ranging from spacecraft to hydrofoils; and developed fault-tolerant computing systems for a number of diverse applications. Constantly searching for the brightest minds in engineering, the Draper Laboratory actively recruits engineers from academic fields such as aeronautical, electrical, and mechanical engineering; computer sciences; and physics. With more than 2,000 employees, the Draper Laboratory is a major source of seasoned personnel for government agencies and private industry. Its employees are trained to plan, manage, technically direct, design, fabricate, and test complete avionics and advanced digital control systems. CHARLES STARK DRAPER LABORATORY - 2 The Draper Laboratory provides services to the U.S. Air Force, the National Aeronautics and Space Administration (NASA), and the U.S. Navy as an engineering design agent. Beginning as early as 1957, the laboratory designed the U.S. Fleet's ballistic missile guidance system for the Polaris and continues in the same manner for the Navy's new Trident series missiles. Current projects at the Draper Laboratory include: Guidance, Navigation, and Control: continuing design and development of guidance, navigation, and control systems for spacecraft, missiles, and ships. This work supports programs of the U.S. Navy and NASA; Fault Tolerant Computing: developing fault-tolerant computing to ensure reliability among on-board navigational systems for NASA; Strategic Defense Initiative: designing the inertial and interceptor guidance systems for ballistic missile defense; Applications of Artificial Intelligence: progressing toward higher levels of automation and artificial intelligence for computer and guidance systems. Use of this technology can be applied to a variety of systems; Industrial Automation: contributing to improvement of the nation's industrial sector to keep it competitive by improving industrial productivity and robotics. One area of concentration lies within the textile/clothing industry by designing automated robotics systems to assemble clothing. THE WHITE HOUSE WASHINGTON MEMORANDUM TO: Sig Rogich FROM: JOSEPH W. HAGIN SUBJECT: APPROVED PRESIDENTIAL ACTIVITY EVENT: Present the Draper Engineering Award DATE: February 20, 1990 Tuesday TIME: 8:30 p.m. DURATION: 30 minutes LOCATION: The State Department, 8th Floor ATTIRE: Black Tie REMARKS REQUIRED: Yes MEDIA COVERAGE: TBD FIRST LADY No PARTICIPATION: ADDITIONAL POTUS will arrive after dinner as program begins INFORMATION: CONTACT: Phil Peter (General Electric) 637-4455 TELEPHONE: OFFICE HOME NOTE: PROJECT OFFICER, SEE ATTACHED CHECKLIST Ed Rogers Marlin Fitzwater David Bates James Cicconi David Demarest David Valdez Fred McClure Jean Lamb USSS- PPD Susan Porter Rose Sig Rogich Gary Walters Patty Presock John Keller WHCA Audio/Visual Chriss Winston Tim McBride WHCA Operations Laurie Firestone J. Bonnie Newman C. Boyden Gray William Kristol Paul Bateman John Herrick Jackie Kennedy 1/6/90 Droper Phil Peter (Gen. Electric) 637-4455 (Kothleen) Chris Schroeder 647-8745 Judith Bostock X 3840 Dr.Bob Notl Acodemy White of Engineering 334-3200 Chrorhes Stork (BCholstok- Draper MIT then lob. in Clambr. fisther inertial navigation colled upon for pridence system for the moon non - profit research lob. submirine pre eminent contributing to human welfare affreedon Nobel never had Award for engin. nuver received "pthertion "other sciences $350, 000 of sold medel largest ward for angineering bring home the impor tonce of engineering prestigious substion comm. requirement for award potunts for microctory frait 2 people J reduction to practice — then on idea into something practical telephone washing mochine T.V. the Annonnement mode in Oct. This is presentation Chrmn of G.E. will introduce POTO POWS hong awards Steve Becktull visibud POLUS this wk Highlight Transformed st society Engineer's week Internoth prize - one did it @ II 1 founders of Intel pgus 55 of 60 Sprrix Leviondows N.E.A. 334-1657 334 - 16377 CARTIE Jack Kilby TI Robert Noycle - founders of Intel harnessing theck (13 essential to protecting (preventing the environmental defradation greater strangth you people - - Jort. , members, of spouses Droper Ded the world by (inventing) the guidence system that brought 35 to the moon Appropriate that the 15 honorees here Ded the world that crubled (detained) hear by advancing determent systems Press kit Competitiveness - lost how yrs. Lounching environmental program how technology can product the environment 18 months inspire kids to gar involved in engineershy Dong Watford Phil Reter Nodl. Engineer's Week started 1951 Discover E Teaching D class engineers going to schools Stephene Bechtel - former Hon. Chrirmon of Notl. Eng. Week 500 engineers teaching in h.s. Society of Prof. Engineers They Deek highlight of Notl. Engineer's ] sibtellite communication = Bob White Choirman of Droper Lob. shy endowed - Joe Choryk - -Bob Sepmons -chrmn of selection process Jack Pal In the space of one transistor took you con fit / million Retridgerator pen cokulator GE- - Pronl Ostersord 203 373-2250 Draper Prize Presentation Dinner Department of State February 20, 1990 6:30 p.m. Reception - Jefferson and Adams rooms 7:30 p.m. Dinner - Benjamin Franklin Room Welcome and Opening Remarks 8:30 p.m. Robert M. White, President, National Academy of Engineering Goes to podium Welcomes guests Recognizes host - Ivan Selin, Under Secretary of Management, Department of State Presents overview of prize including that recipients each receive $175,000 Introduces Joe Charyk Returns to table 8:34 p.m. Joseph V. Charyk, Chairman, Charles Stark Draper Laboratory, Inc. ; Retired Chairman and Chief Executive Officer, Communications Satellite Corporation Goes to podium Presents brief remarks about why Draper Laboratory endowed the prize and Charles Stark Draper Introduces Bob Seamans Returns to table 8:37 p.m. Robert C. Seamans, Jr., Chairman, Draper Prize Committee; Senior Lecturer, Massachusetts Institute of Technology Goes to podium Discusses selection process Introduces Jack Welch Returns to table Presentation 8:40 p.m. John F. Welch, Jr., Chairman, National Academy of Engineering; Chairman and Chief Executive Officer, GE Goes to podium Brief remarks about Kilby and Noyce and that Academy is pleased to recognize them with the first Charles Stark Draper Prize Introduces President Bush to present awards Stays at podium with Bush 8:44 p.m. President Bush goes to podium - speaks for five minutes Calls Kilby and Noyce to podium Welch hands Kilby's medal to President Bush President Bush congratulates and puts medal on Kilby Welch hands Noyce's medal to President Bush President Bush congratulates and puts medal on Noyce Welch acknowledges that Kilby and Noyce will each make brief remarks, Kilby going first President Bush, Welch, and Noyce return to their seats [If Bush leaves at this point, appropriate thanks and recognition should be given before Welch acknowledges Kilby for his remarks.) Acceptance Remarks 8:48 p.m. Kilby presents brief remarks Returns to table 8:58 p.m. Noyce returns to podium Presents brief remarks Returns to table Conclusion 9:08 p.m. White goes to podium Gives appropriate congratulations and thanks and closes program. 9:10 p.m. Program ends. they OFFICE OF PRESIDENTIAL ADVANCE IN-TOWN EVENT CONTACT SHEET Office Phone Number Name 456-7565 Presidential Advance Glades B D 99s Press OfficerState Dest) 456-2820 647-2492 Presidential Advance Office Fax Number Kay Brice Protocol 647-2299 Lucy Muckerman Pres. Advance 456-7565 Bill DAVIS STATE MG2 8th (WOR. 647-3742 Lee Henderson General Services 647-2275 KElviN ARRINgtoN TEchNICAL SERVICES (AUDIO) 647-1630 Cynthin BIENVENUE Besit Ellenes national Academent Engn 979-9462 334-2345 Design Cuisine Catering Kaz Nielsen Design Wisine Catering 979-9400 334-3200 BARBARA HUFF NAT'L ACADEMY of ENGINEERING CARRie Levandork. NAE 334-1657 Dept sport Marilyn Knowt Undai Sect Walin (Knet 1322 Suphonix Bussey L.).H. Speechwriting 456-7750 DOUGLAS WOLFORD NAT'L ACADEMY 7 ENGINEERING 334-1657 Susan Jurner-Lewis Nat I Acad. of Engineering 334-2138 334-2138 Gail Porter Nar Acad of Engineering Steven Ross W.H. Press Advance 633-2415 JOHN GIBBONS WH LEAD ADV. 0-377-5001 H.25C-1987 Milie Pose usss. EAD 395-4011 BRUCE CAUGHMAN WH MILITARY OFFICE 456-2150 DAVID PISTILLI WH COMMUNICATIONS 345-4012/2000 Daniel Petrol PPD 395-4011 Steve Sctt DOUG Hollowd USSS/WRO U<S,S LIA 634-8700 535-5838 Chits DS/PRD 6631363 L38 Wood DAUL MCLAIN DS/PRD DS/UPB 663-1885 647-0249 E300 6 w5 Wilson, Wood wow, PREE U.S., 1856-1924 ", v.35 t: WH THE PAPERS OF WOODROW WILSON ARTHUR S. LINK, EDITOR DAVID W. HIRST, SENIOR ASSOCIATE EDITOR JOHN E. LITTLE, ASSOCIATE EDITOR ANN DEXTER GORDON, ASSISTANT EDITOR PHYLLIS MARCHAND AND MARGARET D. LINK, OODROW WILSON EDITORIAL ASSISTANTS ION UNIVERSITY Volume 35 October I, 1915-January 27, 1916 PRINCETON, NEW JERSEY PRINCETON UNIVERSITY PRESS 1980 1915 OCTOBER 11, 1915 47 or ten years and whom I burden upon you will now be lightened by the exhilarating love nd integrity. of a charming and lovely woman. W. A. Candler Most heartily do I congratulate you and remain, as ever, Faithfully & affectionately yours, R. H. Dabney. ALS (WP, DLC). October 9, 1915. An Address to the Daughters of the American Revolution1 few minutes conversation [Oct. II, 1915] eral and a few minor mat- Madam President and ladies and gentlemen: Again it is my : to the St Regis to take the very great privilege to welcome you to the City of Washington ring to get at some of my and to the hospitalities of the capital. May I admit a point of ig- Tuxedo for the week-end. norance? I was surprised to learn that this association is so ion and bade the President young, and that an association so young should devote itself wholly to memory I cannot believe. For, to me, the duties to it the Attorney General and which you are consecrated are more than the duties and the e Loulie and the Mezes met pride of memory. Minnie K. Young.2 There is a very great thrill to be had from the memories of e President would be glad the American Revolution, but the American Revolution was a sday or Thursday and ad- beginning, not a consummation, and the duty laid upon us by t through the British Am- that beginning is the duty of bringing the things then begun to a noble triumph of completion. For it seems to me that the pe- culiarity of patriotism in America is that it is not a mere senti- 'oung. ment. It is an active principle of conduct. It is something that was born into the world, not to please it, but to regenerate it. It is something that was born into the world to replace systems that had preceded it and to bring men out upon a new plane igton, D. C. IO Oct., 1915. of privilege. The glory of the men whose memories you honor ry avalanche of congratula- and perpetuate is that they saw this vision, and it was a vision of the future. It was a vision of great days to come, when a little cending upon you since the handful of three million people upon the borders of a single sea nd I am not certain whether should have become a great multitude of free men and women rt of nuisance to you. Yet do not feel that I can, in spreading across a great continent, dominating the shores of two oceans, and sending West, as well as East, the influences of in- g you how I rejoice in the dividual freedom. These things were consciously in their minds boms so auspiciously before nderly you loved your wife, as they framed the great government which was born out of the American Revolution. And every time we gather to perpetuate nce that, the more happily their memories, it is incumbent upon us that we should be worthy ly he craves feminine love une to lose his wife, I can of recalling them, and that we should endeavor by every means ness of your situation since in our power to emulate their example. The American Revolution was the birth of a nation. It was at has come into your heart .te weighing upon you have 1 At Memorial Continental Hall, on the occasion of the twenty-fifth anniver- ountry must rejoice that the sary convocation of the Daughters of the American Revolution. Daisy Allen (Mrs. William Cumming) Story, president-general, presided at the meeting. To SB Date Time 1:35 WHILE YOU WERE OUT M Poul Ostergard of G.E. Phone 718-248-7296 Area Code Number Extension TELEPHONED PLEASE CALL CALLED TO SEE YOU WILL CALL AGAIN WANTS TO SEE YOU URGENT RETURNED YOUR CALL Message Call him to go over speech. THE WHITE HOUSE washington 328 - 3225 Yuri Dubinin Bush Quayle 10/25/88 SCIENCE, TECHNOLOGY AND INNOVATION FACT SHEET Today, America stands as the freest, the fairest, the most productive nation on the face of the earth. That's how George Bush wants America to enter the 21st Century -- on the leading edge. To maintain our technological edge, we must make a national commitment to the best education and the strongest competitive spirit in the world. Technology is the key to the future, but people are the key to technology. As we move into the 1990s and the 21st century, George Bush believes that America's economic success and national security depend to an ever greater extent on our scientific and technological progress. Technology is America's economic fountain of youth. Technology has created productivity growth in both the service sector and the industrial sector. Flexible manufacturing systems and numerically controlled machining depend on sophisticated computer software and skilled people. Never before has such a symbiotic relationship existed between the service sector and the industrial sector to produce technological breakthroughs in manüfacturing. Scientific and technological advancement has always been at the very heart of our nation's pioneer spirit, pushing the boundaries of our knowledge, creating economic opportunity and increasing our standard of living. It is the spirit that drove Henry Ford, that soared with the Wright brothers, and it is the spirit that enabled Americans to walk on the moon. A hero of the 19th century, Thomas Edison, inventor, technician and entreprenuer, embodied the pioneer spirit. The pioneer spirit pushed George Washington Carver, scientist and educator, to make advances of world renown in agricultural research. The pioneer spirit carried Sally Ride, physicist, astronaut and explorer, into space in the 20th century. The 21st century will demand even more of America's pioneer spirit. We must be prepared to step up to the challenge. THE REAGAN-BUSH RECORD Growth in research and development. The percentage of our gross national product dedicated to research and development is now at its highest level since the late 1960s. Since 1981, the Reagan-Bush Administration has increased funding for basic research - 1 733 15th Street, N.W. Suite 800 Washington. D.C. 20005 202/842-1988 by over 50 percent, after adjusting for inflation. Industry and government will spend $132 billion on research and development (R&D) in 1988, an increase of 131 percent since 1980. Establishment of new research centers. The Reagan-Bush Administration has started creating university-based, interdisciplinary research centers in engineering, science, and technology. These centers bring the federal government, industry and university labs together to promote the long-term competitiveness of the American economy. Advances have been made in manufacturing and biotechnology; others will follow. THE BUSH PHILOSOPHY The following principles would guide science and technology policy in a Bush Administration: Federal government investment in R&D should focus on basic research. The private sector has the best incentives for deciding which technologies will have the most potential in the marketplace. The federal government should ensure that the rules of the game are fair in the global market. It is up to the federal government to ensure that American intellectual property is protected in world markets and that American companies have as much access to foreign research projects as foreign companies have to American research projects. There are many active players in R&D in the United States -- federal government, state governments, national laboratories, university laboratories, and business. The federal government should not attempt any kind of central planning of American research activity. However, the federal government should promote greater cooperation among these different groups. CHALLENGES OF THE FUTURE George Bush believes science and technology forms the foundation of economic power -- the power to create value. George Bush believes that the combination of dedicated, skilled people and technological advancement can improve our standard of living and our competitive position in the global marketplace. - 2 - George Bush will focus on four priorities critical to America's technological advancement and economic growth: Strengthening Federal Science and Technology Policy Improving Math and Science Education Encouraging Private Sector Investment Promoting Commercialization of Technological Breakthroughs THE BUSH PLAN -- THE ROAD TO INNOVATION AND WORLD LEADERSHIP Strengthening Federal Science and Technology Policy o George Bush will upgrade the President's Science Advisor to Assistant to the President for Science and Technology and reinvigorate the Office of Science and Technology Policy (OSTP). George Bush will also seek advice on science and technological matters from the private sector. George Bush will create a President's Council of Science and Technology Advisors, composed of leading scientists, engineers and distinguished executives from the private sector. The Assistant to the President for Science and Technology will report directly to the President and be an active member of interagency policy groups such as the Economic Policy Council and will also be involved with the national security planning process. The Assistant to the President for Science and Technology will head the Office of Science and Technology Policy and be responsible for developing, and coordinating a federal science and technology strategy. George Bush believes an integrated approach is needed to better manage the federal science and technology process. George Bush will seek the active involvement of a diverse group of American scientists and engineers in this process. George Bush believes we need an overview of the entire federal R&D picture. He also believes a stronger OSTP is needed, one that can coordinate the President's federal science and technology policy among agencies. OSTP should be able to perform analyses and help prepare budgets on an across-the-board basis. o George Bush proposes to double the National Science Foundation's budget over the next five years. George Bush supports both large and small science projects. He will consider a key priority of the National Science Foundation's increased funding the retooling of science and engineering labs at colleges and universities. - 3 - o George Bush supports making all federal R&D authorizations for 5 years and all federal R&D appropriations for 2 years to provide greater certainty to laboratories. Currently, the federal government typically provides R&D authorizations for only 1-3 years and appropriates funds for only 1 year. However, R&D projects have long time horizons -- 5, 10, or even 15 years long. Universities, businesses, and government labs need more assurance of federal R&D funding in future years to plan projects better. Improving Math and Science Education We must redouble our efforts in science and technology by focusing on developing the core of people needed to continue pushing the nation forward. Too many elementary schools graduate children who have not learned basic skills, especially in math and science. Today's and tomorrow's production workers need the right mathematics and science background to operate computers and sophisticated machinery. By 1995 the United States will need an estimated 300, additional secondary-school math and science teachers. Fifty years ago a production worker could get by having only arithmetic. But the operator of a sophisticated robot needs to know algebra and basic physics. In our colleges and universities we need improvement and expansion in science and engineering. We need better trained college graduates to satisfy our economy's expanding needs for engineers, physicists, chemists, and computer professionals. Foreign students represent about 40 percent of enrollments in U.S. graduate schools of engineering. George Bush knows that better science education is needed for our young people in order to prepare them for jobs which are increasingly technical. Science education is an integral part of George Bush's education policy: o George Bush believes study of the sciences should be part of every child's basic education; he believes all students -- whether in academic or vocational-technical programs -- should graduate with an understanding of scientific principles and their application. o George Bush supports increased funding for magnet schools, recognizing that many of them emphasize science education. o George Bush believes that support for science education must continue to be a key priority for the National Science Foundation. O George Bush knows that in many states, teachers who are trained in the sciences and in mathematics are hard to find. He supports efforts of states to enhance math and science education by developing alternative certification programs which can bring distinguished professionals with strong backgrounds in the sciences to the classroom. - 4 - o George Bush will convene a White House Conference on Education placing special emphasis on math and science education. George Bush and the governors from the 50 states will discuss and define the goals of our Math and Science curricula. Encouraging Private Sector Investment We must ensure the economy provides a climate which encourages businesses to take economic risks and invest in new, bold technologies. George Bush understands how important a strong economy is to technological advancement. During the late 1970's, industry did not find it profitable to invest in new technology. High interest rates and high inflation squelched investment and modernization. The Reagan-Bush Administration cut interest rates in half and slashed inflation by two-thirds. George Bush will work hard to keep interest rates low and to ensure incentives are in place for the private sector to fund a high level of advanced research. o George Bush will make the R&D tax credit permanent. Instead of just extending the 20 percent R&D tax credit for short periods of time as Congress has done over the past several years, George Bush supports making the tax credit permanent to provide a stable economic environment for American business. o George Bush supports cutting the capital gains tax rate from 28 percent to 15 percent on all assets held more than one year. We have seen countless examples like Silicon Valley in California and Route 128 around Boston of what cutting the capital gains tax rate can do to stimulate entrepreneurship. Many of our most important technological developments have taken place in small, start-up firms. There is no more powerful incentive for individuals to start up a business than a low capital gains tax rate. Promoting Commercialization of Technological Breakthroughs George Bush will enhance the ability of American business to commercialize new ideas and new technologies. The commercialization of technology requires consistent economic incentives, regulatory reform and a coordinated approach to federal science and technology policy making. O George Bush supports and encourages Partnerships for Progress -- partnerships between business, universities, and government to advance base-building technologies and the rapid transfer of new knowledge from laboratory to marketplace. o George Bush is committed to working vigorously in international negotiations, especially the new round of multilateral trade negotiations, to ensure that American intellectual property rights are protected. - 5 - THE WHITE HOUSE WASHINGTON January 23, 1990 Dear Mr. Welch: On behalf of the President, I wish to acknowledge and thank you for your letter inviting him to present the first Draper Award in commemoration of Engineers Week this February. The President is pleased to accept. This has been entered on his schedule for February 20, and nearer the date, Mr. John G. Keller, Jr., Deputy Assistant to the President and Director of Advance, will contact you about the President's attendance. The President's acceptance of this invitation should not be announced to anyone until official notification is given by the White House Press Office, and any public announcement of this event must be coordinated with Mr. Jay Allison who may be reached at 202/456-2100. You should be aware that certain physical facility requirements exist for any Presidential appearance. The costs associated with these requirements are generally the responsibility of the host and are summarized on the attached list. If you wish to alter the current plans for this event in any way, such as changing any part of the format, the location, or the participants, please direct your request for the proposed change to the Office of Presidential Appointments and Scheduling. With best wishes, Sincerely, JOSEPH W. HAGIN II Deputy Assistant to the President for Appointments and Scheduling Mr. John F. Welch Chairman of the Board General Electric Company 3135 Easton Turnpike Fairfield, Connecticut 06431 JWH/lhw CC Fincominato Helen Donalderon CC May Rawlins GE DWP 4 John F. Welch General Electric Company Chairman of the Board 3135 Easton Turnpike, Fairfield, CT 06431 November 21, 1989 The President The White House Washington, D.C. 20500 Dear Mr. President: I need your help. Engineers Week is February 19 - 23, 1990, and as Chairman of the National Academy of Engineering, I would like to invite you to make it a memorable and important one by presenting the first Draper Award for "outstanding achievement in engineering and technology that contributes to the advancement of human welfare and freedom." We would hope that you could present it on either the evening of February 20 or 22, after a black-tie dinner at the State Department. We believe the Draper Award will become the "Nobel Prize for Engineering," with a cash award of $350,000 to the annual honoree. We feel this event will reemphasize the importance of engineering to national competitiveness and way of life, and your presentation of it would impart a significance that would make it an enduring symbol of excellence and achievement in engineering in the years to come. Every engineer in the country will be honored -- I know I will be -- if you could set aside this event for us. I hope you can do it. Sincerely, JACK GE PHILLIPS S. PETER VICE PRESIDENT Nov. 22, 1989 Dear Tony, As discussed, here is the invitation from Jack Welch, GE's Chairman, to the President for him to present the Draper Award ( the engineering /technology equivalent to the Nobel Prize same $350,000 cash dward ) on the evening of February 20 or 22, 1990 at the State Department during Engineering Week. Thanks for your help on this. Sincerely, this GENERAL ELECTRIC COMPANY 1331 PENNSYLVANIA AVE.. N.W. WASHINGTON, D.C. 20004 (202) 637-4455 GE PHILLIPS S. PETER VICE PRESIDENT Nov. 22, 1989 Dear Ed, As discussed, here is the invitation from Jack Welch, GE's Chairman, to the President for him to present the Draper Award (the engineering /technology equivalent to the Nobel Prize + same 350,000 cash award) on the evening of February 20 02 22, 1990 at the State Department during Engineering Week. Thanks for your help on this. Sincerely, Phil P.S. Tony Benedi is aboard on this. GENERAL ELECTRIC COMPANY 1331 PENNSYLVANIA AVE., N.W. WASHINGTON, D.C. 20004 (202) 637-4455 Milkens are no admiration or of the "Greed The indispensable lionaires on the beards in some rious scratching engineers figuring their can get by for a oming in. I am by all meas- en and women What engineers do is so infinite and various the turn of the century-just one more eather and the that the discipline beggars description. They decade-the United States will be short other cities, far take science and use it to solve the problems 150,000 engineers. $ and sounds of and challenges of life, from the eraser on For our part, we've launched a number nåking plans. I your pencil to the exploration of Mars. Lately of programs to attract the best students-in after all these id ourselves. there's been a lot of discussion about the engineering and other disciplines we begin. "knowledge-based" society to come, but require-for careers at Mobil. At certain key 301 engineers have always lived in a knowledge- universities, a team of Mobil employees from based society. They've shaped our high- different operating units visits regularly to tech world-and starting February 18th, meet students and teachers, share ideas, the whole country will honor them through and set up internships that provide potential National Engineers Week. recruits with hands-on technical experience. Mobil's interest in the celebration is obvi- We also provide scores of grants designed to ous: we make our living through high tech- keep U.S. engineering expertise among the nology. Engineers-probing oceans, jungles, world's best and to fund research that and mountains; in their research labs; at fense, and to expands U.S. technological capabilities. tealth bomber their computers-help us find and produce Engineers are the world's worst at toot- did not name the raw materials and natural resources that ing their own horn. Most are so busy getting ; is by now a Mobil customers require. Engineers help us the job done-turning out quality products, out of Buck move these resources to where they're protecting the environment, safeguarding erg. Skeptics needed, design ways to refine and manufac- public health-that they have little time to refore, if the stem and the ture them, market the fuels and products crow. But this reticence has harmed their structure (to that result. We couldn't get along without need to attract tomorrow's crop of engi- ic needs) are them-and neither could you. neers: The young people who must design to the 'threat' est, or actually So many simple needs-thread, a paper and manage the 21st Century. There are le Republican clip, a spoon, a shoelace, good water from rewarding careers and immense challenges the tap, a clean sheet of paper-depend on e President's awaiting any youth who prepares for the be misled by engineers. Their name itself means they are engineering profession. In fact, mili- the contrivers, and at its root, that they The global economy is upon us. Those ip, though not predicted. The embody talent. They make things. They fix countries-and companies-that prepare for e $295 billion, things. They dream things-like light bulbs, its highly competitive enterprise and techno- IS a reduction moon rockets, and horizontal oil wells-that logical sophistication will flourish. Since ted Pentagon never were. And we are all better off because esents an in- engineers will be in the front lines of that in actual dol- they make those dreams come true. struggle, we hope everyone will join their ar. Proposed Not everyone wants to be an engineer, coming celebration of science, invention, : limited and S Aspin, the at play (as Isaac Newton put it) upon the and creativity. of the House shores of the great ocean of truth. Business, They'll probably be as quiet as usual tee. the arts, and many other occupations and during National Engineers Week-but let's 7 force, bris- weapons sys- professions offer satisfying careers to make sure they all hear three rousing cheers project U.S. millions. But engineers are in demand. By from the rest of us. world, won't he embattled rdly see the romised him, g in the face 14 retreat and ary power. Mobil® country who ation, health comfort only ven with the ray, George lard against S. NYT 2/8/90 ©1990 Mobil Corporation Marcon VOLUME 18 M to Mexico City THE ENCYCLOPEDIA AMERICANA INTERNATIONAL EDITION COMPLETE IN THIRTY VOLUMES FIRST PUBLISHED IN 1829 GROLIER INCORPORATED International Headquarters: Danbury, Connecticut 06816 304 MARCONI nations to both the University of Bologna and the Naval Academy at Leghorn. Marconi's later TI testimony that at age 20 he was "fairly well March acquainted" with prior work on radio waves by Écult Maxwell, Kelvin, Hertz, Édouard Branly, Oliver shoul Lodge, Augusto Righi "and many others" cannot west easily be attributed to the resources at Leghorn. carrie His oldest daughter Degna's 1962 biography of Mors her father says that Righi, a professor at the Uni. and versity of Bologna and a neighbor of the Villa 3.38 Grifone, allowed the eager young Marconi to time, audit classes and do laboratory exercises at the only university, and offered advice when requested. rond Whatever the preliminaries, Marconi seems to 11 have first hit on the idea of communication by for = radio waves in mid-1894, after reading a memo- xhie rial review of Hertz' work written by Righi. In trans the Villa Grifone's long attic he assembled a finall Hertz-Righi spark transmitter and a Branly-Lodge den. coherer receiver, and by early 1895 he could ring T a bell a few yards away. For greater distance the 5 the experiments were moved outdoors. Major drivi improvements resulted when horizontal wires a Marc few feet long were extended from each side of thou the transmitter spark circuit and terminated in irrep suspended metal plates, and a similar structure the was attached to the receiver circuit. When in late man: 1895 these wires were changed to a vertical posi- lentl coni tion, and the lower plates laid flat on moist earth, BROWN BROTHERS U.S. Marconi's radio operated a Morse "inker" at the Guglielmo Marconi at one of the radio transmitting and 1915 receiving stations that inaugurated the era of radio. remote end of the estate, more than a mile away and over a small hill. This antenna-ground struc- side a di ture was a major invention. sent MARCONI, mär-kõ'nē, Guglielmo (1874-1937), Marconi's parents now agreed that it was time nica Italian inventor, who received half of the 1909 to explore commercial prospects. Following re- wee Nobel Prize for physics for his work in develop- jections in Italy, an Irish relative and grain- mun ing wireless telegraphy. This award surprised milling engineer, Henry Jameson Davis, invited quel many physicists, since previous awards had been Marconi to come to London. Marconi arrived dire for such laboratory studies as revealing X rays, there with equipment in February 1896. By its ti radium and radioactivity, and the electron. What July a patent was applied for and granted, and ect, had Marconi done? Measured by the extent to a successful demonstration was made to Post H. J which he had shattered firmly established "laws Office engineers over a distance of almost a mile. Offi of nature," Marconi was well qualified for the When the Wireless Telegraph and Signal Com- way prize. Mainly in the years 1900-1903, he had pany was formed a year later, the distance meg shown that the electromagnetic waves predicted achieved was close to 10 miles (16 km). I by James Clerk Maxwell and demonstrated by For the next three years Marconi, with com- a 2: Heinrich Hertz could carry messages at frequen- pany money, engaged mainly in building several nam cies of a few hundred kilohertz 2,000 miles experimental wireless stations, extending the maxi- erni (3,200 km) and more around the earth's curva- mum distance of transmission and making demon- own ture, many times farther than any known theory strations whose publicity might bring business. tory A major obstacle to commercial success was the would allow. It was a major geophysical dis- of h covery not fully explained until the 1920's. total government monopoly in Britain and many last European countries of all facilities for commercial Marconi's background for the accomplishment crov message-handling within or between the coun- was unusual. His 38-year-old widower father, high Giuseppe, a businessman of Bologna, Italy, had tries. Communications exempted from the mo- boo eloped in 1864 with 17-year-old Annie Jameson, nopoly included ship-to-ship and ship-to-shore the service and a few transoceanic routes. Thus the a music student from a well-to-do family in Ire- niqu land. Their children were Alfonso, born a year company's first small income-producing contracts were with Lloyd's of London, the British Army Mai later, and Guglielmo, born in Bologna on April and Navy, and three shipping companies. elit 25, 1874. About 1855, Giuseppe's father had By mid-1900, Marconi had persuaded his to sold the Marconi ancestral estates and bought the Villa Grifone, a manor house with several hun- directors that transatlantic service was of prime usu dred acres at Pontecchio near Bologna. This was financial importance. The company's first super- eng Marconi's home until the age of 22, and here he power station, with a transmitter designed by first performed his first crucial experiments in wireless consultant John A. Fleming of the University of Iris London, was ready at Poldhu in Cornwall a year terr telegraphy using radio waves generated by elec- later, followed shortly by a similar station at mai tric sparks. South Wellfleet on Cape Cod, Mass. When both in ] Frequent childhood visits with his mother to relatives in Britain made Marconi fluently bi- flimsy antenna structures collapsed in autumn bea lingual at an early age. Formal schooling started storms, Marconi had a simpler one built at Poldhu and then hurried to Newfoundland with for with a tutor at home, and ended about 1894 after seven years at the Leghorn Lyceum, a sort receivers and kite antennas to establish the his- Ma of technical institute. He failed entrance exami- toric priority of transatlantic wireless by receiving Ital the famous letter S on Dec. 12, 1901. University of Bologna and at Leghorn. Marconi's later There will always be those who doubt that age 20 he was "fairly well Marconi received the legendary S, given the dif- rior work on radio waves by ficult conditions and the claimed frequency of ertz, Édouard Branly, Oliver shout 800 kilohertz. However, on his next east- hi 'and many others' cannot west Atlantic crossing a few weeks later, Marconi to the resources at Leghorn. carried equipment that received confirmed Degna's 1962 biography of Morse-inker messages to 1,550 miles (2,500 km), Righi, a professor at the Uni. and the letter S in headphones to 2,100 miles and a neighbor of the Villa 13,380 km), from Poldhu. It was noted at the e eager young Marconi to time, but not fully appreciated, that this occurred 0 laboratory exercises at the only at night, and that nothing was received be- red advice when requested. vond 700 miles (1,130 km) in the daytime. eliminaries, Marconi seems to While always pursuing other projects, Marco- e idea of communication by ni focused his primary attention after 1902 on the 1894, after reading a memo- achievement of commercially reliable two-way work written by Righi. In transatlantic wireless telegraph service. He was long attic he assembled a finally successful in 1908, with stations in Clif- insmitter and a Branly-Lodge den. Ireland, and Glace Bay, Nova Scotia. This attainment of his original dream marks AP/WIDE WORLD I by early 1895 he could ring away. For greater distance the summit of Marconi's role as innovator and Ferdinand and Imeldo Marcos as they were about to be- re moved outdoors. Major driving force behind the company, now called come president and first lady of the Philippines in 1965. ed when horizontal wires a Marconi's Wireless Telegraph Company, al- extended from each side of though he remained a world-famous figure and k circuit and terminated in irreplaceable company representative. In 1910 MARCOS, mär'kõs, Ferdinand E(dralin) (1917- ates, and a similar structure the company acquired an aggressive general ), Philippine political leader. He was the eceiver circuit. When in late manager, Godfrey Isaacs, who waged such re- country's first president to succeed himself, its e changed to a vertical posi- lentless legal warfare against infringers of Mar- first prime minister, and its first chief executive coni's strong patents that by 1912 the biggest to be exiled. lates laid flat on moist earth, U.S. companies were forced out of business. In ated a Morse "inker" at the Marcos was born in Sarrat, Ilocos Norte (Lu- 1915, when Italy entered World War II on the zon), on Sept. 11, 1917. Throughout his political tate, more than a mile away side of the Allies, Marconi began a long period as career he capitalized on his claim that he had led This antenna-ground struc- a distinguished international diplomatic repre- ention. a guerrilla unit against the Japanese during sentative of his native land. His interest in tech- now agreed that it was time World War II, an assertion that U.S. Army docu- nical experimentation reappeared for a few ments made public in 1986 denied. Marcos was al prospects. Following re- weeks in 1916 when he carried out pioneer com- Liberal minority leader in the lower house of 1 Irish relative and grain- munication tests with "very short waves" at fre- Congress from 1949 to 1959 and a senator from enry Jameson Davis, invited quencies of 100 to 300 megahertz, using highly ) London. Marconi arrived 1959 to 1965. After becoming Senate president directional antennas. The work was far ahead of int in February 1896. By in 1963 he switched to the Nationalist party, and its time. A decade later his assistant on this proj- pplied for and granted, and in the 1965 election for president of the Philip- ect, company engineer C.S. Franklin, along with pines he defeated Diosdado Macapagal. stration was made to Post H. J. Round and others, built for the British Post a distance of almost a mile. During his first term as president, Marcos Office a worldwide system of high-power short- Telegraph and Signal Com- built roads, bridges, airports, and schools, and wave stations using vacuum tubes at about 10 a year later, the distance oversaw a tenfold increase in rice productivity. megahertz. He was reelected in 1969, but campaign waste 0 10 miles (16 km). By 1921, Marconi was wealthy enough to buy and mounting inflation led to violent demonstra- e years Marconi, with com- a 220-foot (67-meter) oceangoing steam yacht, d mainly in building several tions. In 1971 grenades were exploded at a pub- named by him the Elettra, which the British gov- lic rally of the opposition senatorial candidates, stations, extending the maxi- emment had seized in wartime from its Austrian all of whom were wounded. Marcos took advan- smission and making demon- owner. Using it as both a globe-roaming labora- licity might bring business. tage of this incident to suspend habeas corpus tory and a home, Marconi spent much of the rest and to intern thousands of dissidents. Mean- commercial success was the of his life aboard. In 1932 it was the base for his while, in order to circumvent the constitutional nopoly in Britain and many last important experimental discovery, that mi- limit of eight consecutive years for a president's f all facilities for commercial crowaves at frequencies of 500 megahertz and term of office, Marcos had called a constitutional thin or between the coun- higher bent farther below the horizon than text- convention to create a parliamentary form of gov- ns exempted from the mo- books said they should. This work anticipated ernment. As prime minister under this system, p-to-ship and ship-to-shore the "scatter propagation" communication tech- he could rule indefinitely. insoceanic routes. Thus the nique used 20 years later in polar regions. By 1971, Muslim unrest was increasing in the income-producing contracts Living in the heyday of the giant ocean liners, south, and open revolt had broken out in the London, the British Army Marconi greatly enjoyed traveling with socially north led by the New People's Army, a Maoist shipping companies. elite passengers in first-class luxury. He is said group. Disorder spread to central Luzon in mid- arconi had persuaded his to have made more than 100 Atlantic crossings, 1972 following disastrous floods. In September lantic service was of prime usually at company expense. Several shipboard 1972, Marcos proclaimed martial law. As tempo- The company's first super- engagements were made and broken before his rary president and (from 1973) concurrent prime a transmitter designed by first marriage in 1905 to a charming, aristocratic minister under the new but suspended constitu- leming of the University of Irish girl, Beatrice O'Brien. Romances with in- tion, he ruled by decree. He muzzled the press, Poldhu in Cornwall a year ternational socialites recurred at intervals. The ly by a similar station at nationalized major industries, and seized proper- marriage was terminated by Vatican annulment ties of his opponents-whose leader, Sen. Benig- ape Cod, Mass. When both in 1927, when he married Cristina Bezzi-Scali, a no Aquino, was convicted of subversion by a tures collapsed in autumn beautiful titled Italian less than half his age. military tribunal and imprisoned until 1980. ] a simpler one built at For many reasons, including company trans- ried to Newfoundland with formations and health problems, the center of International groups protested Marcos' violation tennas to establish the his- Marconi's life after 1927 gradually reverted to of human rights, charging his government with torture and murder. tlantic wireless by receiving Italy. He died in Rome on July 20, 1937. In 1978, his emergency rule endorsed by n Dec. 12, 1901. ROBERT A. CHIPMAN, University of Toledo questionable referenda, Marcos permitted the 305 thenry Ford VOLUME 11 Falstaff to Francke THE ENCYCLOPEDIA AMERICANA INTERNATIONAL EDITION COMPLETE IN THIRTY VOLUMES FIRST PUBLISHED IN 1829 GROLIER INCORPORATED International Headquarters: Danbury, Connecticut 06816 566 FORD FORD, Henry (1863-1947), American automobile the low-priced Model N, he moved to the manufacturer, who revolutionized the early in- T, which appeared late in 1908. dustry with his low-priced Model T, produced sturdy vehicle had a 4-cylinder, by assembly-line methods. He popularized the motor; ignition was provided by automobile as a means of transportation for the into the engine; a planetary average American and created a major company. Early Life. Ford was born in Springwells gears; "splash" lubrication was used; and OF nated the gear shift and danger of stripping township (now part of Dearbom), Mich., on July 30, 1863. He attended rural schools and early dis- strength, was employed in many of the dium steel, easy to machine but of high terms VESID played mechanical and inventive skills. In 1879 parts. Although his associates contributed he moved to Detroit, where he obtained a job as a machinist's apprentice. During the next few nificantly to the novel features of the vehicle sig, Ford was responsible for the overall concept years he worked for several different companies, repaired watches and clocks as a sideline, and many of the basic ideas embodied in the of and struction of the Model T. improved his knowledge of machinist and engi- neering skills by reading and practice. The car, which sold for $825 as a roads: After his apprenticeship, Ford set up and re- and $850 as a touring car, clearly met the needs paired Westinghouse steam engines in southern and means of the American public. In the the Michigan for about a year. He married Clara J. year more than 10,000 Model T's were sold. Bryant on April 11, 1888. They moved to De- 1914 the number reached 250,000, and Ford heid IL troit in 1891 and two years later Ford was made just under 50% of the nation's automobile mari, chief engineer of the Edison Illuminating Com- By the time its production ceased in 1927. 13 million T's had changed American motoring pany. On Nov. 6, 1893, the Fords' only child, Ford's concentration on the Model T Edsel Bryant, was born. mitted him to utilize standardized parts pay. 271 Car Builder and Racer. Fascinated by the prom- assembly-line production. The volume of produce ise of the internal combustion engine and its tion made it possible to reduce the price of the application to a self-propelled vehicle, Ford con- car steadily without detriment to profits. structed a 1-cylinder gasoline motor in 1893. He A major advertising campaign kept the Model T went on to build his first car, a light carriage the public's eye, and nationwide distribution "as in powered by a 2-cylinder engine, which was handled through a carefully devised network of completed in June 1896. He resigned from the branch agencies and dealerships. "Road men Edison company in 1899 to organize the Detroit working out of branch agencies, ensured that Automobile Company. dealers, who numbered some 7,000 by 1913 The new company was forced into bank- provided adequate repair service and presented ruptcy in less than two years, and Ford decided a favorable image. to make a reputation for his cars as racers. This Patent Victory and $5 Daily Wage. Ford Has decision brought him into conflict with the always of an independent frame of mind, and he backers of the reorganized Detroit Automobile refused to join the automobile manufacturers who Company, now known as the Henry Ford Com- accepted the validity of a patent obtained In pany. Unable to develop a racer on company George B. Selden on a basic gasoline engine and time, he left the firm (which then dropped his paid royalties to the holders of the patent. A name) in March 1902. Ford's racers brought court fight resulted, and in 1911 Ford's position him the publicity he sought. He defeated that he had not infringed the patent was upheld Alexander Winton in a memorable race at Grosse His reputation was further enhanced in 1914 Pointe, Mich., in October 1901, and Barney when the company announced a $5 daily mins. Oldfield, driving a Ford racer, added to the mum wage for employees who met certain bask builder's reputation. Ford drove his "999" to a requirements. This step was hailed as an innova. world's record of 39.4 seconds for a mile over tion in employee compensation and made em- the ice on Lake St. Clair in January 1904. ployment at the Ford plant a prize. Ford Motor Company Organized. Meanwhile, Changes and Troubles. Ford's position in the Ford, with the financial backing of a Detroit coal company was so strong that he could dictate dealer, Alexander Y. Malcolmson, and a small policy when he was so inclined. After 1914 he group of investors, had organized the Ford Motor became increasingly disposed to exercise this Company on June 16, 1903. Its principal assets power. His decision to integrate operations from were Ford's talent and that of his assistant, C. H. raw material to finished vehicle threatened the Wills, backed by the business acumen of James Dodge brothers, parts suppliers who held a 10% Couzens, Malcolmson's office manager and later interest in the Ford firm. A controversy erupted U.S. senator from Michigan. Ford owned 25.5% but Ford acquired the Dodges' stock, and by of the stock of the new company, which was 1919 he and his immediate family held complete capitalized at $150,000, of which only $28,000 control of the Ford Motor Company. was paid in cash. The first car produced by the Despite setbacks, especially in the post-World new company was sold within a month, and from War I Depression, Ford continued to integrate then on orders and production rose rapidly. production processes under one roof at the huge In 1905, Malcolmson and Ford were at odds new Rouge plant in Dearborn. However, he lost over the type of car on which the company or dismissed many of the key individuals who should concentrate. Malcolmson favored an ex- had helped to build the company's early success pensive car that the market appeared to demand, Ford's son, Edsel (1893-1943), became presi- but Ford argued for a simple, inexpensive model. dent of the company in 1919 and displayed con- As a result of their disagreement, Malcolmson siderable executive talent. The automobile mar- was put under pressure to sell his interest in the ket was changing and the purchasing public company. When he finally did so, Ford became wanted more than a sturdy, compact, black car the majority stockholder and president in 1906. such as the Model T. The car buyer was willing Success of the Model T. Free to follow his own to buy on the installment plan, but Henry Ford ideas, Ford found overwhelming success. From had little sympathy for sales on credit. Edsel was Ref. PN6081 P55 WH Respectfully Quoted A Dictionary of Quotations Requested from the Congressional Research Service edited by Suzy Platt Congressional Reference Division PROPERTY OF LIBRARY EXECUTIVE OFFICE OF THE PRESIDENT LIBRARY OF CONGRESS . WASHINGTON . 1989 Santa Claus "Dear Editor: I am 8 years old. "Some of my little friends say there is no Santa Claus. "Papa says 'If you see it in The Sun it's so.' "Please tell me the truth; is there a Santa Claus? "Virginia O'Hanlon. "115 West Ninety-fifth Street." Virginia, your little friends are wrong. They have been affected by the skepticism of a skeptical age. They do not believe except they see. They think that nothing can be which is not comprehensible by their little minds. All minds, Virginia, whether they be men's or children's are little. In this great universe of ours man is a mere insect, an ant, in his intellect, as compared with the boundless world about him, as measured by the intelligence capable of grasping the whole of truth and knowledge. Yes, Virginia, there is a Santa Claus. He exists as certainly as love and generosity and devotion exist, and you know that they abound and give to your life its highest beauty and joy. Alas! how dreary would be the world if there were no Santa Claus. It would be as dreary as if there were no Virginias. There would be no childlike faith then, no poetry, no romance to make tolerable this existence. We should have no enjoyment, except in sense and sight. The eternal light with which childhood fills the world would be extinguished. Not believe in Santa Claus! You might as well not believe in fairies! You might get your papa to hire men to watch in all the chimneys on Christmas Eve to catch Santa Claus, but even if they did not see Santa Claus coming down, what would that prove? Nobody sees Santa Claus, but that is no sign that there is no Santa Claus. The most real things in the world are those that neither children nor men can see. Did you ever see fairies dancing on the lawn? Of course not, but that's no proof that they are not there. Nobody can conceive or imagine all the wonders there are unseen and unseeable in the world. You may tear apart the baby's rattle and see what makes the noise inside, but there is a veil covering the unseen world which not the strongest man, nor even the united strength of all the strongest men that ever lived, could tear apart. Only faith, fancy, poetry, love, romance, can push aside that curtain and view and picture the supernal beauty and glory beyond. Is it all real? Ah, Virginia, in all this world there is nothing else real and abiding. No Santa Claus! Thank God! he lives, and he lives forever. A thousand years from now, Virginia, nay, ten times ten thousand years from now, he will continue to make glad the heart of childhood. FRANCIS P. CHURCH, "Is There a Santa Claus," editorial, The Sun, New York City, September 21, 1897, p. 6. After Church's death on April 11, 1906, The Sun broke its policy of editorial ano- nymity to announce that he had written this editorial. Science 1661 It is not enough that you should understand about applied science in order that your work may increase man's blessings. Concern for the man himself and his fate must always form the chief interest of all technical endeavors; concern for the great unsolved problems of the organization of labor and the distribution of goods in order that the creations of our mind shall be a blessing and not a curse to mankind. Never forget this in the midst of your diagrams and equations. ALBERT EINSTEIN, speech at the California Institute of Technology, Pasadena, Cali- fornia, February 16, 1931, as reported in The New York Times, February 17, 1931, p. 6. 1662 Science without religion is lame, religion without science is blind. 312 Science ALBERT EINSTEIN, paper prepared for initial meeting of the Conference on Science, Philosophy and Religion in Their Relation to the Democratic Way of Life, New York City, September 9-11, 1940.-Einstein, Out of My Later Years, chapter 8, part 1, p. 26 (1950, rev. and reprinted 1970). Hanlon. Street." 1663 Modern civilization depends on science James Smithson was well aware that ticism of a knowledge should not be viewed as existing in isolated parts, but as a whole, each portion of be which is which throws light on all the other, and that the tendency of all is to improve the human be men's or mind, and give it new sources of power and enjoyment narrow minds think nothing of ant, in his importance but their own favorite pursuit, but liberal views exclude no branch of science or intelligence literature, for they all contribute to sweeten, to adorn, and to embellish life science is the pursuit above all which impresses us with the capacity of man for intellectual and moral generosity progress and awakens the human intellect to aspiration for a higher condition of humanity. hest beauty JOSEPH HENRY, first secretary of the Smithsonian Institution. Inscription on the would be as National Museum of American History, Washington, D.C. ) poetry, no ept in sense 1664 What is a scientist? We give the name scientist to the type of man who has felt iguished. experiment to be a means guiding him to search out the deep truth of life, to lift a veil from u might get its fascinating secrets, and who, in this pursuit, has felt arising within him a love for the lanta Claus, mysteries of nature, SO passionate as to annihilate the thought of himself. Nobody sees hings in the MARIA MONTESSORI, The Montessori Method, trans. Anne E. George, p. 8 (1964). dancing on conceive or 1665 A new scientific truth does not triumph by convincing its opponents and making them see the light, but rather because its opponents eventually die, and a new generation e, but there grows up that is familiar with it. the united MAX PLANCK, Scientific Autobiography and Other Papers, trans. Frank Gaynor, pp. ancy, poetry, 33-34 (1950). beauty and Ise real and Sea I years from ) make glad 1666 I have seen the sea lashed into fury and tossed into spray, and its grandeur moves the soul of the dullest man; but I remember that it is not the billows, but the calm level of the sea from which all heights and depths are measured. V York City, Representative JAMES A. GARFIELD, speech nominating John Sherman for presi- dent.-Proceedings of the Republican National Convention, Chicago, Illinois, June 2-8, ditorial ano- 1880, p. 184 (1881). Garfield himself was ultimately nominated at this convention. 1667 As they say on my own Cape Cod, a rising tide lifts all the boats. And a partnership, by definition, serves both partners, without domination or unfair advantage. Together we er that your have been partners in adversity-let us also be partners in prosperity. must always ed problems President JOHN F. KENNEDY, address in the Assembly Hall at the Paulskirche, ations of our Frankfurt, West Germany, June 25, 1963.-Public Papers of the Presidents of the United idst of your States: John F. Kennedy, 1963, p. 519. Kennedy used the "rising tide" image a number of times. adena, Cali- 1931,p.6. 313 312 Mator Policy Initrative BUDGET OF THE UNITED STATES GOVERNMENT netet. may not.add to the titals OF THE THE PRESIDENT OF OFFICE OFFICE OF AND BUDGET OF UNITED THE 03 FISCAL YEAR 1991 III.C. ENHANCING RESEARCH AND DEVELOPMENT RESEARCH AND DEVELOPMENT: AN INVESTMENT IN THE FUTURE Research and development (R&D) yields new ments on space platforms to be developed knowledge, products and processes that, over by the U.S., Europe and Japan over sever- the long term, result in economic growth and al decades. improved quality of life for all Americans. In- Agricultural Research Initiative.-The vestment in research and development is a top priority for an Administration that believes in budget proposes the first step of a new investing in the future. It is the key to enhanc- program in agricultural research, designed to enhance production efficiency, food ing American competitiveness, improving our safety and environmental quality. quality of life, and laying the groundwork for building a better tomorrow. Human Immunodeficiency Virus/Acquired Immune Deficiency Syndrome.-An overall The budget proposes to allocate about $71 increase of 18 percent in all aspects of the billion in budget authority for research and Federal response to HIV/AIDS: research, development, including R&D facilities, in 1991. prevention, treatment, and income sup- This is an increase of $4.5 billion, or 7 percent port. over 1990 enacted levels. Civilian R&D will increase by 12 percent while defense-related Moon-Mars Exploration.-A major new R&D will increase by 4 percent. Within this effort of $1.3 billion to develop the ena- total, $12 billion will be allocated for basic re- bling technologies and begin the robotic search, an increase of $1 billion or about 8 science missions needed to carry out the percent over 1990. President's goal of manned exploration of space beyond Earth orbit. This effort is the The 1991 budget contains a number of new first step toward a manned lunar base and and expanded programs and initiatives that a manned mission to Mars. will contribute greatly to the Nation's R&D enterprise. Examples include: Space Station Freedom.-A 36 percent in- crease for the development of Space Sta- Doubling of the National Science Founda- tion Freedom to a total of $2.6 billion. This tion budget.-An increase of over 14 per- increase will provide for the critical transi- cent which will continue progress toward tion from design to the initial fabrication doubling the NSF budget by 1993. of long-lead hardware elements. Global Change.-An increase of 57 percent Superconducting Super Collider (SSC).-An for the U.S. Global Change Research Pro- increase of $100 million (or 46 percent) for gram (USGCRP), to a total of over $1 bil- the SSC to a total of $318 million. This lion. This program places the United will support continued work to complete States in a world leadership role in cli- the design of the prototype magnets, and mate change research. A major portion of transition from prototype to production. this increase will be used to initiate the The funding level maintains the 10-year Earth Observing System, a series of instru- design and construction schedule. 67 68 THE BUDGET FOR FISCAL YEAR 1991 ENHANCING RESEARCH AND DEVELOPMENT (Dollar amounts in millions) Budget Authority Outlays 1990 1991 Dollar Per- 1990 1991 cent En- Pro- Dollar Per- En- Pro- acted posed change acted posed change cent change change Major initiatives: 1 гизмчолауза Doubling the NSF budget 2,084 2,383 +299 +14 1,959 2,213 +254 +13 Global Change 659 1,034 +375 +57 595 853 +258 +43 Agricultural Research Initiative 43 100 +57 +133 36 46 +10 +28 HIV/AIDS 2,932 3,463 +531 +18 2,454 3,203 +749 +31 Moon/Mars Exploration 859 1,267 +408 +47 767 1,037 +270 +35 Space Station Freedom 1,928 2,627 +699 +36 1,434 2,198 +764 +53 Magnetic Levitation Transportation 2 10 +8 +400 2 7 +5 +306 Superconducting Super Collider 218 318 +100 +46 188 293 +105 +56 Advanced Technology: Robotics 150 192 +42 +28 126 166 +41 +32 Science and Engineering Education 839 1,061 +222 +26 723 871 +148 +20 Government-wide totals: Conduct of R&D: Basic Research 11,398 12,366 +968 +8 10,961 11,886 +925 +8 Civilian 10,459 11,372 +913 +9 10,016 10,911 +895 +9 Defense 2 939 994 +55 +6 945 975 +30 +3 Applied Research and Development 52,313 55,773 +3,461 +7 51,124 53,745 +2,622 +5 Civilian 13,375 15,346 +1,971 +15 12,321 14,449 +2,129 +17 Defense 2 38,938 40,427 +1,490 +4 38,803 39,296 +493 +1 Subtotal, Conduct of R&D 63,711 68,140 +4,429 +7 62,085 65,632 +3,547 +6 R&D Facilities 3,023 3,059 +36 2,590 2,738 +149 +6 Total 3 66,734 71,199 +4,465 +7 64,674 68,370 +3,695 +6 1 Major initiatives include funds for research and development which also are included in the Government-wide totals for R&D as well as funds from other non-R&D programs. 3 2 Includes military-related programs of the Departments of Defense and Energy. Components may not add to totals because of rounding. wen R&D for Advanced Technology.-An in- Intellectual Property.-The Administration crease of 28 percent for robotics R&D, and will aggressively pursue improved interna- continued support for R&D on high-per- tional protection of intellectual property. formance computing, semiconductors, su- The current negotiations in the Uruguay perconductivity and advanced imaging. Round of the General Agreements on Tar- Science and Engineering Education.-The iffs and Trade are an important forum for Administration is committed to improving this activity. the quality of science and engineering edu- cation. The budget will propose over $1 R&E Tax Credit.-The Administration will billion for science and engineering educa- propose to make the Research and Experi- tion activities in five agencies. mentation Tax Credit permanent. Magnetic Levitation Transportation.-An Encouraging R&D by Transnational Com- increase of nearly 400 percent in funding panies.-The Administration will propose to $10 million to explore the possibility of to make permanent the rules for alloca- stepped-up U.S. efforts in this emerging tion by transnational companies of R&D technology. 91 III.C. ENHANCING RESEARCH AND DEVELOPMENT 87 nd search) will be funded at $3.4 billion in 1991. The "pipeline" of young people that feeds 20 The Department of Energy R&D activities in- the S&E workforce may not be adequate in a- clude the research, development and testing of either numbers or quality to provide the work- S. all nuclear weapons. The Department also con- ers that will be needed during the next décade as ducts R&D on nuclear-powered directed energy and beyond. Between 1980 and 2000, the or weapons for the Strategic Defense Initiative, number of 18-24 year olds will decline by 19 ill Naval reactor systems, and technology to percent while the overall population will in- on verify arms control treaties. crease by 18 percent. Even if the historic aver- in age holds, and 5, percent of 18-24 year olds STRENGTHENING SCIENCE AND obtain S&E degrees, the resulting shortfall in TECHNOLOGY EDUCATION the S&E workforce could reach into the hun- dreds of thousands. Moreover, many students At a time when the number of American with an expressed interest in science and engi- e students pursuing advanced science and engi- neering careers leave the pipeline before get- neering education is declining, the scientific ting a degree in science and engineering. This and engineering (S&E) workforce is becoming is particularly true for underrepresented mi- more critical to the strength of the overall norities Currently Black and Hispanic chil- economy. This is a disturbing trend dren constitute 25 percent of our school chil- d Many jobs created in the future will require dren; by the year 2000 this percentage will rise people who are well-versed in mathematics to 47 percent. Yet it is these groups that are and science and who have greater facility with now the most underrepresented in the S&E it higher order reasoning skills than most high- workforce: in 1988, only 231 Black and Hispan- school and college graduates now have. Be- ic Americans earned doctorates in science or tween 1976 and 1986, S&E employment grew engineering fields (excluding psychology or the at an average annual rate of over 6 percent, social sciences). Together, Black and Hispanic four times as fast as annual growth in the Americans constitute 20 percent of the Na- total U.S. workforce and twice the yearly rate tion's population but only 4 percent of em- 1- of increase in total professional employment. ployed scientists and engineers. is ONLY A SMALL PROPORTION OF STUDENTS RECEIVE SCIENCE AND ENGINEERING (S&E) DEGREES IOL S&E Students nowho are onTotal S&E under- student represented population minorities Total sophomores in 1977 856,000 4,000,000 High school sophomores with S&E interest 86,000 730,000 High school seniors with S&E interest bas 2065,000 590,000 College freshmen, S&E preference bs40,000 340,000 College juniors, S&E major 14,000 214,000 S&E B.S. degrees 13,000 206,000 S&E graduate students noilling 2,500 60,000 S&E M.S. degrees U. 2,000 46,000 S&E Ph.D. degrees Under 400 10,000 Note: Science and engineering participation reported here excludes: psychology and the social sciences. (Uperib 480 ons e JB bemis 88 THE BUDGET FOR FISCAL YEAR 1991 This situation is compounded by an even ings in the Nation's science and technology more serious factor. The performance of U.S. education enterprise. The 1991 budget provides precollege students in math and science is far the concrete manifestation of the Administra- below that of students in other major industri- tion's commitment in this area. It should be alized nations. The quality of education, par- noted, however, that the responsibility for both ticularly science, mathematics, and engineer- the quality and the quantity of the Nation's ing education, must be improved if America is to be competitive in the future. S&E workforce belongs to every sector, not just, and not primarily, to the Federal Govern- The Administration is moving aggressively ment. on a number of fronts to address the shortcom- to INVESTING IN SCIENCE, MATHEMATICS, AND ENGINEERING EDUCATION (Dollar amounts in millions) Budget Authority Department or Agency 1990 1991 Dollar Percent Enacted Proposed change change National Science Foundation 357 463 +106 +30 Education 136 230 94 +69 National Aeronautics and Space Administration 42 51 +8 +21 Energy 17 25 +8 +47 National Institutes of Health 287 292 +5 +2 Total 839 1,061 +222 +26 The 1991 budget proposes a total of $1 bil- the numbers of students entering and staying lion in direct spending in four agencies for in the S&E pipeline. Examples include: work- science, mathematics, and engineering educa- shops for teachers, development of innovative tion, an increase of 26 percent above 1990. The educational materials, research experiences for direct spending programs include a variety of high-school and college students in working re- measures to support teacher training, curricu- lum development, and direct assistance to stu- search laboratories, and support for innovative dents. In addition, there is a much greater programs at many of the Nation's science mu- amount of funding for fellowships and other seums. In addition, NSF supports many pro- forms of support that is provided indirectly grams aimed specifically at recruiting and re- through research grants. taining underrepresented groups. The 1991 budget provides $463 million to the The Department of Education maintains National Science Foundation for a range of strong relationships with State educational en- activities designed to improve education and tities and has the ability to reach thousands of develop human resources for science and engi- students and teachers through its large formu- neering. This is an increase of $106 million or la grant programs. The 1991 budget proposes 30 percent over 1990. NSF directly supports $230 million, an increase of $94 million or 69 high-leverage science, math, and engineering percent over 1990, for the Dwight D. Eisenhow- education programs aimed at improving the er Mathematics and Science program, which quality of teaching, the quality of students and will be provided to States to develop and im- III.D. INVESTING IN HUMAN CAPITAL 103 Student aid.-The other large program area and management abilities to be teachers and for Federal funding is postsecondary education principals, increase the endowment funds of financial aid. The 1991 budget continues to the nation's Historically Black Colleges and support over $18 billion in aid to almost 6, Universities, and provide special funding for million students with budget authority of $9.5 the school districts with the worst drug abuse billion. This aid, in the form of grants and problems. subsidized loans and jobs, helps make it finan- cially possible for qualified students to obtain Congress did not complete action on the bill. a postsecondary education, regardless of family Appropriations were provided for 1990 for the income. two largest programs, Merit Schools and Magnet Schools of Excellence, contingent upon In recent years, some schools have taken ad- passage of the authorizing legislation. vantage of the availability of Federal student aid to enroll students who are not truly quali- The budget assumes that Congress will pass fied for postsecondary education or for whom the Educational Excellence Act on a timely they will not be providing a good education basis. For 1991, the budget includes $401 mil- Many of these students are not equipped for lion in budget authority for these programs. the job market when they leave school and often drop out of school very. early while the Other Education Initiatives school keeps the Federal aid. Some of these Support for programs for the disadvantaged dropouts have taken out large loans which absorbs the bulk of Federal education spend- they cannot repay, and thus default. The Edu- ing. Other Federal program activities are less cation Department is taking aggressive regula- costly, but perhaps in the long run more im- tory and administrative actions to stop these portant for educational improvement. The schools from taking advantage of Federal aid budget for research and statistics and the Even and of disadvantaged students. Additional leg- Start program have already been discussed. islative proposals will further strengthen the Other key policies in the 1991 budget include: Secretary's enforcement powers to prevent pro- gram abuses. Summit follow-up.-$20 million is requested Much of the Federal student aid now sup- for activities related to implementing the ports vocational training, in addition to the Summit Agreements. Uses may include activi- traditional support for students attending two ties to help States implement proposed legisla- and four year colleges. The Administration is tion providing flexibility and enhanced ac- considering means to rationalize support for countability, and additional funding for devel- vocational training under the student aid pro- opment of measures of progress toward nation- grams, the Job Training Partnership Act, and al educational goals. the Vocational Education Act. Dropout demonstrations.-$45 million is re- quested for a program of dropout prevention The Educational Excellence Act demonstrations. These projects will be careful- Shortly after taking office, President Bush ly designed to build on the learning from $22 proposed eight education initiatives. In addi million in dropout demonstrations now coming tion to providing renewed Presidential commit- to an end. Coupled with evaluation of the prior ment to improved education, his goal was to demonstrations, and $5 million in new dropout reinvigorate the education reform movement research, these projects will help States learn by selectively adding Federal money in select- how to prevent young people from dropping ed areas. out of school and how to help them return to The President transmitted his bill, "The school if they do drop out. Educational Excellence Act", on April 5, 1989. School principals.-Principals and other ad- This bill would give incentives to schools to ministrators play essential leadership roles in improve educational achievement, expand the school reform. A new $25 million program is use of magnet schools, reward excellent teach- included in the budget that will improve the ers and students, promote the hiring of per- abilities of school principals and other admin- sons with proven subject matter knowledge istrators. Under this program, talented persons 104 THE BUDGET FOR FISCAL YEAR 1991 preparing to become principals will receive Working Group on Education is coordinating some short-term training and then spend a literacy initiatives across many agencies of year with a proven successful principal to government, and is developing plans for close learn from this "mentor" how best to address cooperation with volunteer and private sector the complex problems of school administration. literacy action efforts. Mathematics and science education.-$230 Historically black colleges and universities. million is proposed for the Dwight D. Eisen- $95 million is provided to support the oper- hower Mathematics and Science Education ations of historically black colleges and univer- programs, a 70 percent increase over what sities and graduate institutions. Most impor- Congress provided in 1990. These programs tantly, an additional $15 million is provided provide funds to States to improve the knowl- for matching endowment grants for these insti- edge and teaching abilities of mathematics and tutions, triple the amount provided in 1990. science teachers. In addition, programs for sci- Encouraging the building of endowments is the ence, mathematics and engineering education government's most effective contribution to in the National Science Foundation are pro- the future financial independence of these in- posed to be increased by $100 million, to $460 stitutions: million, a 28 percent increase over 1990. Other iborios Federal agencies, such as the National Aero- nautics and Space Administration and the SUMMARY OF THE EDUCATION BUDGET Energy Department, also have education ini- AND POLICIES FOR 1991 tiatives. The Domestic Policy Council Working The 1991 budget for the Education Depart- Group on Education is providing coordination ment asks Congress to provide $1.2 billion across agencies. more in 1991 than it did in 1990 for discretion- Literacy.-$239 million is proposed for the ary programs. This is a 6 percent increase. The Adult Education programs of the Department projected decline in interest rates, to which of Education, an increase of more than 25 per- guaranteed student loan subsidies are tied, cent over what Congress provided in 1990. In produces anticipated savings of nearly $700 1991, $200 million would be distributed to million which help finance the discretionary States to help finance remedial education and program increases. The combination of discre- thus to improve the literacy levels of adults tionary increases and loan subsidy savings re- The Education Department will also create a sults in a total Federal Education Department new Adult Literacy Clearinghouse to help budget of $24.6 billion, an increase of $500 mil- States, volunteer groups and the private sector lion over total 1990 budget authority. This is share knowledge of what works in literacy pro- the largest education budget ever proposed. grams. Funding is also proposed to be doubled The Presidential and State commitments to from $3 million to $6 million in 1991 for the educational improvement supported by this VISTA (Volunteer in Service to America) Lit- budget represent a new beginning for national eracy Corps of the ACTION agency, which sup- education policy. There can now be some cau- ports volunteer efforts to overcome the prob- tious optimism for improvements in education lems of illiteracy. The Domestic Policy Council in the 1990s and far into the next century. IMPROVING JOB TRAINING OPPORTUNITIES Learning does not end with graduation from though most job training is provided by em- high school or college. It is a constant life-long ployers for their employees, the government process. If giving every child the opportunity also provides second chance job training for for a basic education is essential in a demo- those with poor skills who have not succeeded cratic society, so is providing access to addi- in the traditional education establishment or tional training beyond the classroom. Al- work environment. BUILDING A BETTER AMERICA "We live in a peaceful, prosperous time, but we can make it better A new breeze is blowing, and a nation refreshed by freedom stands ready to push on. There is new ground to be broken, and new action to be taken." " -- President Bush Inaugural Address January 20, 1989 December 11, 1989 15 restructuring of the education system; and measuring performance. A commitment was made to develop national goals and initiatives to increase flexibility and accountability by early 1990. On April 5, the President submitted to Congress a comprehensive set of education initiatives, The Educational Excellence Act of 1989. The Act proposes: -- The Presidential Merit Schools program -- to reward schools that are making substantial progress in raising students' educational achievement, creating a safe and drug-free school environment, and reducing the drop-out rate. -- A new Magnet Schools of Excellence program -- to support the establishment, expansion or enhancement of magnet schools, focusing on disciplines important to the Nation's economic competitiveness such as math and science, increasing parental choice and improving quality education. -- The Alternative Certification of Teachers and Principals program -- to assist States interested in broadening the pool of talent from which to recruit teachers and principals. -- President's Awards for Excellence in Education -- to recognize public and private school teachers in every state who meet the highest standards of excellence. -- Drug-free Schools Urban Emergency Grants -- to provide special assistance to selected urban school districts that are disproportionately affected by drug trafficking and abuse. -- A National Science Scholars program -- to provide college scholarships to high school seniors who have excelled in the sciences and mathematics. -- Additional Funding Authorization for Endowment Matching Grants at Historically Black Colleges and Universities (HBCUS) -- to strengthen HBCUs by building endowments, an especially effective way to create financial strength and long-term security. On April 24, the President issued a new Executive Order on Historically Black Colleges and Universities. Highlights of the order include: 861-4000 522-1212 Corrie Levendasoki 334-1563(9) 1 334 - 1657 on smbitions 1st in the world in moth de science by the YOAR 2000 1 -Roe Moon Landing NGINEERING AND ADVANCEMENT OF Application Satellites HUMAN WELFARE WE II I / Jumbo Jet Microprocessor Outstanding Achievements Lasers 1964-1989 Computer-Aided Design and Manufacturing Fiber-Optic Communication CAT Scan Genetically as Engineered Products Advanced Composite NAE 25 Materials The National Academy of Engineering is a private organization established in 1964. It shares in the responsibility given the National Academy of Sciences under a congressional charter granted in 1863 to advise the federal government on questions of science and technology. This collaboration is implemented primarily through the National Research Council. The National Academy of Engineering also recognizes distinguished engineers, sponsors engineering programs aimed at meeting national needs, and encourages education and research. © 1989 by National Academy of Engineering Library of Congress Catalog No. 89-63947 International Standard Book No. 0-309-04185-6 Copies of this brochure are available from: Office of Public Awareness National Academy of Engineering NAS-069 2101 Constitution Avenue, N.W. Washington, D.C. 20418 Carrie Levandoski Public Awareness Officer ENGINEERING AND NATIONAL ACADEMY OF ENGINEERING 2101 Constitution Avenue, N.W. Washington, D.C. 20418 THE ADVANCEMENT OF (202) 334-1657 Note poges HUMAN WELFARE 14 14-17 17 NAE 25 CONTENTS Introduction 2 Outstanding Moon Landing 4 Achievements Application Satellites 10 Microprocessor 14 1964-1989 Computer-Aided Design and Manufacturing 18 CAT Scan 22 Selected by the National Academy of Engineering on the occasion of its 25th anniversary Advanced Composite December 5, 1989 Materials 26 Jumbo Jet 30 Lasers 34 Fiber-Optic Communication 38 Genetically Engineered Products 42 Further Reading 46 Acknowledgments 48 NAE 25 Introduction The years 1964 to 1989, the first 25 years of gave modern living conveniences to tens of the National Academy of Engineering, have thousands of people in the desert. The witnessed more advancement in technology Alaska pipeline, deepwater oil platforms, and, consequently, greater change in the lives and drilling technologies help supply much of people than any previous 25-year period of our energy need. Auto emission control in recorded history. As part of its anniversary systems, including the catalytic converter, celebration, the Academy has selected what and processes for vitrifying hazardous it considers to be the 10 outstanding engi- waste-sealing them in glass for long-term neering achievements that have reached the storage-provide additional protection for public since the Academy's founding on our environment. Artificial hearts, cardiac December 5, 1964. Each represents a major pacemakers, and orthopedic implants give advance or breakthrough in engineering and new life to thousands of people. a significant contribution to human welfare. The top 10 achievements are presented This brochure presents each of the 10 here in nearly chronological order. In some achievements in a separate story, where we cases we have grouped related achieve- share with you some of the engineering ments. For instance, lasers stimulated the challenge, insight, and excitement that development of fiber-optic communication, attended the achievements. In doing so, we so we placed them together. And we chose to hope also to convey a better understanding lead the list with the moon landing, which is of what engineering does and how it has truly one of the outstanding engineering contributed to human welfare over the past achievements of all time. quarter century by improving our lives, The most striking aspect of these 10 extending our possibilities, and expanding diverse achievements is how closely they are our horizons. tied together. The microprocessor, which has Members of the Academy and represen- probably had the widest impact of all, has tatives of several professional engineering contributed to the development of today's societies submitted suggestions of outstand- application satellites, the CAT scan, computer- ing engineering achievements. More than aided design and manufacturing, as well as 340 suggestions were reviewed by the NAE genetically engineered products. Modern Advisory Committee on the 25th Anniver- jumbo jets benefit from microprocessors, sary Celebration. The Council of the Acade- computer-aided design and manufacturing, my approved the top 10. lasers, fiber-optic communication, advanced No such list can encompass all the composite materials, and application technological advances important to society; satellites. In turn, many of these achieve- many other engineering accomplishments ments are closely tied to earlier, sometimes nearly made our list. The Indus Basin seemingly unrelated advances in the basic Scheme and its Tarbela Dam, for instance, sciences, including mathematics. bring flood relief and stable water supply to It is also striking how widely and deeply millions in Pakistan. The entirely new cities these engineering advances have affected of Jubail and Yanbu-ports at either end of our daily lives. Weather satellites, which the crude-oil pipeline across Saudi Arabia- have been routinely used only since 1966, generate the satellite pictures seen on almost every television weather report. The micro- processor, invented in 1971, operates toys, televisions, videocassette recorders, 2 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE microwave ovens, and burglar alarms in chemical analysis of the body without probably the majority of U.S. homes. breaking the skin? We've used microproces- Advanced composites, which first appeared sors to make soda machines talk, but can we in commercial products in 1973, are now use them to make computers really think used by most people who golf, ski, or play before they speak? And yes, we have been to tennis. And every telephone call of any the moon, but what about going to Mars? distance is undoubtedly carried on beams of The engineering achievements of the future laser light flashed through fiber-optic cable, a are limited only by the laws of nature and service that has been commercially available our own imagination. only since 1977. Because some engineering achievements are often viewed as sources of environmental degradation, it is important to note the Robert W white beneficial effects many of these 10 have had on the environment. For example, the ROBERT M. WHITE famous pictures of the earth taken by Apollo President astronauts on their moon flights vividly show us how delicate and small our planet is compared with the forbidding immensity of space. Photos from Landsat and other earth- observation satellites for the first time have given us a good look at our fragile global environment, pinpointing areas needing help. And microprocessors, by improving the efficiency of everything from cars to power plants, help conserve scarce natural resources and greatly reduce the amount of pollutants released into the environment. The next 25 years will witness even more advances in technology, bringing ever- greater changes to our way of life. It is therefore important, if we are to ensure the wise use of technology, that all of us- engineers and nonengineers alike- understand the nature of engineering and how it can be used to benefit us individually and as a society. Finally, it is obvious that many more fascinating challenges for engineers lie in the future. We've built CAT scans and other wonderful machines that peer into the unopened human body, but can we develop devices and techniques that perform a total INTRODUCTION 3 Moon Landing Right: The first steps of Six hundred million people- an earthling on another celestial body are recorded in nearly one-fifth of the world's moon dust. population-watched on television in July 1969 as an earthling first set foot onto another celestial body. With that step, human conscious- ness leaped a quarter million miles into space, expanding mankind's vision to a degree unequalled since Columbus's voyage to the New World. "The astronauts didn't just go to the moon," said one observer. "All our minds went to the moon." back revealed that the moon was formed at the same time and of the same elements as Looking back from the moon, people earth but that it lacks water, atmosphere, and saw white wispy clouds and blue sparkling life. The astronauts also left instruments to water covering a planet framed by immense gather data on ground tremors and other darkness. Earth appeared as a highly phenomena. A laser reflector left by Apollo 11 integrated unit, not just a collection of astronauts is still being used to measure the isolated oceans and continents. And it was earth-to-moon distance and study the strikingly obvious how small, fragile, and movement of continents. beautiful our planet really is, a precious oasis The feat of landing men on the moon in the vastness of space. and returning them safely home ranks the The Apollo program sent nine spacecraft Apollo project with the Egyptian pyramids, to the moon from 1968 to 1972, landing a the Panama Canal, and the Manhattan dozen astronauts at six different sites. The Project as outstanding engineering achieve- rocks and scientific information they brought ments of all time. It stands alone for the advances in size and sophistication it made over prior technology. Apollo required a 4 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE = U asse = ID rocket 15 times more powerful, a navigation worked together well enough SO that Apollo 17 is readied for a system far more reliable, a unique lunar millions of parts would arrive where they nighttime launch toward the landing craft, and improved space suits should on schedule and would fit and moon, peeking out from the clouds beyond. The spacecraft capable of withstanding a very hostile function properly. carried the first scientist to environment. In addition, the program The Saturn/Apollo system was com- the moon and was the only demanded a novel, comprehensive manage- posed of an Apollo spacecraft, a lunar lander, one launched at night in the ment system to ensure that thousands of Apollo series. government and industrial organizations MOON LANDING 5 and a three-stage Saturn V rocket, which engines of the Saturn V, however, each launched them toward the moon. Once in produced 1.5 million pounds, and there were lunar orbit, the spacecraft released the two- five. Together they burned 3 tons of kerosene stage lander, which carried two of the three and liquid oxygen per second. Building astronauts to the surface. The lander's ascent reliability into such monstrous engines was a stage later returned them to the spacecraft monumental challenge. Yet, all 12 Saturn V and was abandoned. Just before they rockets launched in the Apollo series suc- reentered the atmosphere, the astronauts ceeded. jettisoned the large service unit that supplied To fuel the second and third stages, engineers chose liquid hydrogen, which gave 40 percent more thrust per pound of fuel burned than kerosene. The second stage was a cluster of five engines, while the third had just one. But unlike those in lower stages, the third-stage engine had to be restartable in order to push the spacecraft toward the moon after coasting an hour and a half in earth orbit. Building a rocket of such size and design required many new and advanced engineer- ing techniques. The field of fracture mechan- ics, for example, advanced greatly in answer- ing questions raised during construction of the second-stage fuel tank, which was 65 feet long, 33 feet in diameter, and held liquid hydrogen at -423 degrees F. The aluminum tank was pieced together with literally miles of welds, which could contain a few tiny cracks. But how big could the cracks be before they began to weaken the tank? By analyzing aluminum with similar cracks, engineers calculated the amount of pressure the metal could stand before cracks of various sizes begin to grow and thus become dangerous. To ensure its safety, they tested each second-stage tank by loading it with liquid hydrogen at a pressure 5 percent higher than the maximum required for flight. If cracks did not grow at that pressure, they would not grow at the lower pressure during An Apollo 11 astronaut power, water, and oxygen and returned to flight. unpacks a scientific earth in the small command capsule of the The Apollo flights would have been experiment to measure ground tremors on the moon. spacecraft. impossible without inertial navigation, The small laser reflector, on Buildings shook and the ground trem- which was developed in the 1950s and was the ground behind the bled when a Saturn V rocket roared skyward just being installed in the early 1960s on astronaut, is still being used with the first trio of astronauts heading for aircraft, submarines, and ballistic missiles. for laser measurements of the lunar orbit in December 1968. The rocket Radio navigation from earth was impractical distance between the earth and moon. developed roughly enough thrust to hurl a during the final minutes of a landing small house into earth orbit. Thirty-six stories approach to the moon. The time radio signals tall and weighing as much as a good-sized take to travel that distance is too long for the Navy destroyer, the Saturn/Apollo vehicle immediate reactions needed to land a craft used the biggest, most powerful rocket ever safely. Radio navigation was also useless for built. flights behind the moon because it requires The first stage of the three-stage Saturn line-of-sight transmission from earth. V dwarfed the largest rockets of its day. An Atlas ballistic missile, for instance, produced 360,000 pounds of thrust. The first-stage ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE Apollo's navigation-the rocket, The five first-stage engines of spacecraft, and lunar lander each had a the mighty Saturn V rocket lift Apollo 11 off the launch pad separate system-included gyroscopes and and start the spacecraft accelerometers, which sensed change in toward the moon. Astronauts direction and speed. They were combined in are in the conical command single subsystems, called inertial measure- capsule atop the rocket. Just ment units, or IMUs, which measured below the capsule is the cylindrical service unit. Below movement along, as well as off, the desired that, the lunar lander is course due to rocket thrust or atmospheric packed in another cylinder resistance. When leaving or approaching the just above the rocket's third earth or moon, IMUs were critical for making stage. quick guidance decisions. Gravitational influences of the earth and moon were calculated before flight and added to onboard guidance computers. This informa- tion and the IMU data permitted control systems to keep the craft almost exactly on course. During the flight, astronauts used a sextant in calculating midcourse corrections. In practice, however, ground radar stations usually performed this time-consuming task and radioed up commands to correct deviations. The two-stage lander that ferried astronauts to the lunar surface was the first manned vehicle designed to fly solely in space. Its structure could be extremely lightweight, since the moon's gravity is only one-sixth that of earth. And aerodynamics did not need to be considered, since there is no air on the moon. The lander was essential- ly built inside out. Its thin aluminum pres- surized cabin was inside, wiring and tubing surrounded that, and a patchwork of black or golden insulating materials covered the outside. These materials absorbed or reflect- ed light, depending on whether that part of the lander needed protection from cold or heat. Its four spiderlike legs with wide foot pads could keep the lander upright, whether it touched down on a slope, in deep dust, or under any of 500 other combinations of terrain and landing conditions anticipated by the engineers. One of the most critical parts of the lander was the small ascent engine. Once the astronauts landed, they were completely dependent on this engine to return them to the mother ship. There was no backup. The basic portion of the flight engine had been briefly test-fired on earth. Its fuel system, however, had not previously been exposed to the highly corrosive propellants for fear of weakening its seals and corroding its valves. So engineers ground-tested ascent-engine prototypes for every failure they could MOON LANDING 7 required more than 450 persons in the launch control center and nearly 7,000 others on 9 ships, in 54 aircraft, and at stations around the world. At its peak, 400,000 people were working on Apollo at three major space centers and 20,000 contractor sites. The people who managed Apollo pioneered techniques that remain the model for operating a massive, well-run engineering program. In 1961 NASA estimated that the project would cost $20 billion and would put a man on the moon before 1970. The space agency actually spent $25.4 billion for all the Apollo flights. And two Apollo 11 astronauts stepped onto the moon on July 20, 1969. On the planning and control side of the program, the Apollo managers created a monitoring system that gave them enough information to ensure that the millions of pieces for the project were coming together at the right time and place, in the right engi- neering configuration, and for the right price. To do this, they identified a few hundred critical milestones-such as "rocket first stage complete" or "stage shipped to Cape Kennedy"-for each program area. Once a month, contractors reported their progress to the three NASA centers, who reported to the Apollo managers. The managers, in turn, identified projects that were falling The lunar lander, seen from imagine that might happen in flight. None behind-most of them did-and devised the Apollo 11 spacecraft, did. solutions to bring them back on schedule. heads for a landing on the Astronauts who walked on the moon moon. The descent stage, For instance, when a tragic fire killed three with outstretched legs and wore a three-piece space suit and backpack astronauts during a ground test of their protruding rocket nozzle, will of life-support equipment for up to four spacecraft, managers swiftly reviewed the remain on the moon when the hours outside the lander. The ensemble safety of nearly the entire Saturn/Apollo upper ascent stage brings the weighed 190 pounds on earth but only a system, redesigned the spacecraft and space two astronauts back to the mother ship. sixth of that on the moon. The first piece was suit, and brought the program back on a cooling undergarment of knitted nylon- schedule in little more than a year. spandex with a network of plastic tubes Right: Dressed in a three- filled with water circulating from the piece space suit, an Apollo 11 backpack. The next piece was the basic suit, a astronaut climbs down a leg of the lunar lander and hops rubber-coated nylon bladder sandwiched onto the hard, dusty surface between a cloth lining and a nylon cover to of the moon. His life-support shape the suit. The third piece was a protec- back pack carried enough tive outer garment of 17 layers, including 6 oxygen for a 4-hour tour layers of Beta cloth. This is a fireproof fabric outside the lander. of fiberglass threads coated with Teflon to prevent itching. The outfit was completed by a helmet, boots, gloves, and the backpack, which also carried a radio and antenna. The Apollo program was probably the most complex and ambitious engineering project ever attempted. A moon flight 8 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE On the technical side, the great challenge astronauts traveled over the lunar surface was to create a management system that in a motorized rover to gather rocks and would ensure the precise interface among conduct scientific experiments. Apollo 17, the millions of pieces-the Saturn V alone had last of the program, carried the first scientist- 6 million-manufactured by thousands of a geologist-to the moon in December 1972. contractors. Careful records were kept of Since the inception of the Apollo specifications for all the parts and the program, nearly all the known planets in our interfaces between them. This documenta- solar system and many of their moons have tion was especially valuable when, for been visited by unmanned spacecraft. instance, during the unmanned second Between them, the United States and the Apollo flight, the first-stage engines began to Soviet Union have sent automated probes to Apollo 15 astronauts explore flicker, a piece of an aluminum panel fell off, Earth's two neighbors, Mars and Venus, as the moon in a lunar rover, and two second-stage engines quit early. By well as to Mercury, the planet nearest the which was packed aboard the lander and unfolded on the comparing flight instrument data with the sun. U.S. probes have journeyed to all the lunar surface. It carried the documentation, engineers were able to find other planets except Pluto. The most cele- astronauts 17.5 miles during the problems, simulate them on the ground, brated unmanned spacecraft, Voyager 2, left three exploratory tours and and correct them with enough confidence to Earth in 1977, rendezvoused with Jupiter in helped them collect 170 go ahead with the next flight-the first with 1979 and then with Saturn, Uranus, and pounds of moon rocks for the return to earth. astronauts aboard. finally Neptune in 1989. Yet, it was man's The first two moon flights-Apollo 8 and landing on the moon that truly captured the The earth, like a sparkling 10-put astronauts into lunar orbit; Apollo 11 world's imagination, an engineering achieve- jewel against black velvet, and 12 put them on the moon. An exploding ment that has extended the human domain rises above a barren lunar oxygen tank in the service unit crippled landscape to greet the Apollo far beyond the boundaries of earth. 11 astronauts 240,000 miles Apollo 13, whose astronauts took temporary out in space. shelter in the lunar lander during the emergency return to earth. Apollo 14 went smoothly. During the next three missions, MOON LANDING Application Satellites In November 1982, a U.S. satellites later, Early Bird's descendants weather satellite spotted a handle up to 120,000 calls at once or share the capacity with TV broadcasts, computer data, hurricane developing south- and electronic mail. They are part of a west of Hawaii and watched it worldwide communications network start moving north. Suddenly launched by the International Telecommuni- cations Satellite Organization, or Intelsat, the storm turned east and which now has more than 100 member raked across the islands less nations. Communications satellites have dramat- than 24 hours later, leaving CHARLESTON ically altered the nature of our global com- nearly a quarter billion dollars munity. Twenty-five years ago, reliable of damage in its wake. But communications existed only between only one life was lost. Hurri- countries in the developed world. But communications satellites and the develop- cane warnings, based largely ment of small, portable television cameras on satellite pictures, had have linked people together around the alerted most people in time to globe. In 1969, for example, communications satellites brought TV coverage of the first take shelter. manned lunar landing-live from space- The 125-mile-per-hour winds Twenty-five years ago, there were no to nearly a fifth of the world's population. of Hurricane Hugo begin operational satellites for weather forecasting Today they bring instant coverage of news to lash the coast of the or for any other routine application. Today, and events to every corner of the earth. southeastern United States under the constant gaze of a however, satellite systems girdle the earth Scores of civilian and military communi- U.S. weather satellite. watching for storms, relaying communica- cations satellites sit in a ring around the earth Satellite images warned tions, mapping uncharted terrain, and 22,300 miles above the equator. At that residents of Charleston (upper helping ships and airplanes navigate any- altitude they complete one revolution every left) of the approaching Hugo, where on the globe. 24 hours and therefore remain stationary still 210 miles away in this Satellites started to become routine in relative to the surface of the earth below. picture, giving them several days to prepare for the storm April 1965, when the first nonexperimental Satellites in this geostationary orbit provide and evacuate the city. commercial satellite flew into space and high sky platforms for relaying signals to parked in orbit over the Atlantic. Early Bird and from ground stations, vehicles, boats, carried circuits for 240 telephone calls or and planes scattered over the surface below. television service between Europe and North The idea for a system of radio-relay America. Today, several generations of satellites in geostationary orbit maintained by astronauts was described by science fiction writer and futurist Arthur C. Clarke 10 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE An astronaut retrieves a communications satellite, Westar VI, that failed to go into high geostationary orbit after being launched into low earth orbit. The space shuttle brought the satellite back to earth, where it was refurbished. Pending U.S. government approval, the satellite will be launched aboard a Chinese rocket and will provide a communications link for East Asia. Communications satellites relayed live television coverage of moon missions to millions of people around the world. Here, Apollo 15 astronauts collect rock samples. in 1945. Astronaut custodians, however, were northern latitudes. These satellites were not impractical and, when Early Bird went up in geostationary. However, one always rose the 1960s, shown to be unnecessary. Transis- above the country just as another set. Now tors and other solid-state components of the more than 40 countries have established their satellite's innards were far more reliable than own satellite communications systems, often the vacuum tubes of 1945-vintage radios and by constructing ground stations and renting small enough to fit into a tiny satellite. Early circuits on commercial satellites. Bird lasted more than three years without Before the era of routine satellite use, maintenance, and today's communications weather observations were available for less satellites frequently last until their fuel runs than 20 percent of the globe. Much of the out, about a decade. unobserved region covered the vast oceans A country divided by mountains, of the Southern Hemisphere and the tropics, jungles, water, or distance is now often where a storm could churn into a hurricane united by a domestic satellite communica- with no one knowing until it sank a ship or tions system. In 1965 the Soviet Union washed away a town. But since 1966, when established the Molniya system using the first fully operational weather satellite satellites in oblong orbits looping over the APPLICATION SATELLITES 11 system was launched, no major tropical Weather satellites frequently carry storm has gone undetected anywhere in the equipment to relay data collected by thou- world. sands of remote automatic ground stations Two U.S. weather satellites circling from from instruments such as rain or river-flow pole to pole scan the earth from low orbit gauges. And, since 1982, increasing numbers twice a day. Soviet satellites also routinely of U.S. weather satellites, as well as Soviet survey global weather from polar orbit. navigation satellites, have also been carrying High-flying satellites in geostationary orbit search-and-rescue radio equipment, some of monitor wide reaches of the planet and it supplied by Canada and France. The generate the weather pictures seen on devices pick up distress calls from ships and television. The United States launched the planes in trouble, leading to the rescue so far first such operational satellite, GOES of more than 1,200 persons. (Geostationary Operational Environmental Images generated by weather satellites Satellite), in 1974 and now maintains one have been used to study snow cover, geolog- above the western Atlantic and another over ic faults, and other large ground features. But the eastern Pacific. A European satellite the need for more detailed information hovers over Africa, an Indian satellite over gathered in a systematic, repetitive way led the Indian Ocean, and a Japanese satellite to the development of specialized terrain- over the western Pacific. These five provide observation satellites. These orbiters create high-quality images that can be used to help Two dish antennas near study worldwide crop production, search for Bogota, Colombia, aim at a minerals and petroleum, monitor environ- communications satellite in geostationary orbit above the mental problems such as desert creep and equator. deforestation, and measure snowmelt to predict water resources and control flooding. In 1972 the United States launched the first in a series of Landsat satellites, which scrutinize the entire earth from near-polar orbit, observing each spot at the same local time every 18 days. All Landsats have carried multispectral sensors that measure solar energy and infrared radiation at four or more wave- lengths. Every type of terrain reflects and absorbs sunlight and emits infrared radiation in ways that reveal its identity and condition. Objects often show up better at one wave- length than another, which gives this technique an advantage over conventional photography. The data are transmitted back continuous coverage of weather throughout to one of several ground stations, processed the equatorial and midlatitude regions of the into images, and made available to the earth. public. France and the Soviet Union have Radiometers carried by weather satel- launched similar satellites and make their lites measure reflected solar energy and images available commercially. The French infrared energy radiating from the earth and SPOT system produces particularly high atmosphere. Computers then turn the data quality images. into images of clouds and weather patterns. Infrared satellite images do not show as Radiometers also measure radiation at much detail as visible images, but they yield precise wavelength intervals, generating thermal information that the others cannot information that allows scientists to deter- provide. Water, for example, that collects in mine atmospheric temperature, water vapor, faults usually holds more heat than sur- and ozone levels. Today's radiometers are rounding rock. Infrared sensors detect this sensitive enough to sound the atmosphere heat differential, revealing an otherwise from geostationary satellites more than hidden geologic formation. Infrared imaging 22,000 miles up in space. is also useful for monitoring pollution, observing volcanic activity, and leading 12 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE fishing boats to warm waters where fish might be gathered. More recently, experimental terrain- observation satellites have been carrying microwave radar, which penetrates all types of weather, day or night. Microwave radar can, to a certain extent, penetrate leaves and is used to map jungle terrain. It can also penetrate dry sand and has been used to trace buried watercourses in the desert. Radar return signals also tell much about the land that is useful for mineral and petroleum exploration. The military forces of the United States, the Soviet Union, and other countries use their own terrain-observation satellites to keep track of foreign troop movements, electronic communications, military installa- tions, and rocket launchings. The satellites are hardier than their civilian counterparts, as well as more sophisticated, capable, and flexible. These "eyes in the sky" have greatly reduced the possibility for surprise attack and have thus helped maintain peace among world powers for the past quarter century. In the future, satellites may be used to monitor the health of the entire earth bio- sphere. A major step in that direction will be taken as part of the International Space Year in 1992. A "Mission to Planet Earth" is being organized using earth-observation satellites their locations to within 10 meters. The heart Satellite image reveals and other means to study such problem of the system is an atomic clock in each extensive clear cutting in areas as polar ozone holes, deforestation, satellite that loses or gains just one second Tongass National Forest on ocean productivity, landcover change, and the northern tip of Prince of every 33,000 years. A plane, for example, Wales Island, Alaska. Recently global warming caused by the "greenhouse receives signals from four satellites, each cleared areas appear pink, effect." signal telling the time it was emitted and the cleared areas that have The precision of their orbits makes position of the satellite. The plane's comput- started to recover are light satellites ideal instruments for navigation. erized receiver calculates how far each signal green, and undisturbed They have all but replaced the sextant since forests are dark green. has traveled, then uses this data to pinpoint about 1968, when the Navy completed a its position in space. system of navigation satellites, called Transit, In 1988 a satellite was launched to track for ballistic missiles fired from submarines. long-haul trucks in the United States. A Transit employs satellites in near-polar orbits freight company using the system immedi- that are spaced to provide global coverage. ately found one of its trucks 300 miles off Using data encoded on satellite signals, a course. More advanced systems used by computer-aided receiver on a ship or plane some military aircraft show pilots a map of can determine its location to within less than the local area. Cars may someday be a quarter mile. equipped to receive satellite signals that Several satellites have already been provide drivers with a street map of the city launched for a new navigation system- being traveled. Indeed, satellites may the Global Positioning System (GPS), or become our standard means of navigation, Technicians prepare a Navstar-that will have 18 satellites plus whether on land, in the air, or at sea. Navstar navigation satellite 3 spares when completed. Using GPS, for launch. The 12 spike receivers in ships, planes, ground vehicles, antennas will form the and portable packs will be able to determine satellite's signal into a cone covering the entire hemisphere below. APPLICATION SATELLITES 13 Microprocessor The microprocessor-a tiny room. At work, they help "computer on a chip" no design complex buildings and bigger than your fingernail- control huge manufacturing has quickly and quietly machines. In between, they infiltrated our lives since it coordinate traffic lights and was introduced in 1971. At improve fuel efficiency in cars. home, microprocessors are the And everywhere there is a personal computer, there is a microprocessor churning away inside. A microprocessor works something like a juke box's record player, which plays the tune on a record retrieved from its collection. A microprocessor, however, plays the set of instructions retrieved from a memory chip, performing simple functions-such as addition or subtraction-programmed into the instructions. Microprocessor and memo- ry chips alike rely on microscopic integrated circuits to perform their tasks. Before microprocessors, integrated circuit chips were generally not programmable. They could do only a single function for which they were designed, like a record player playing one tune engraved on its turntable. The first microprocessor, in fact, A web of electronic brains in electronic devices was developed by an American engineer circuitry spreads across the who was given the task of designing 12 face of the 4004, the first that control microwave single-function chips for a Japanese calcula- microprocessor. The chip ovens and change television tor. Instead, the engineer designed one contains 2,300 transistors yet measures only 1/6 inch by 1/4 channels from across the general-purpose chip that performed all 12 inch, about the size of a functions according to instructions stored in child's fingernail. a memory chip. Because each instruction contained only four bits-the electronic 1's 14 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE and O's of digital code-the microprocessor Microprocessor chips in a variety of sizes Microprocessors are the was classified a 4-bit chip. provide the delicate control that improves tiny "brains" inside Microprocessors of the first generation the efficiency of power plants, cars, and microcomputers and hundreds of other electronic devices. were too feeble to power anything resem- heating and cooling systems in buildings, bling a personal computer. But they which translates into lower operating costs were-and still are-powerful enough to and less pollution. They are also widely used drive pocket calculators and control in the cockpits of advanced commercial machines performing simple tasks. They airliners to control navigation and other have become, like the motor, a tool for every avionics systems, thereby improving the use. Millions are sold each year to operate efficiency of aircraft and crew. home burglar alarms, remote television Second-generation microprocessors- controllers, programmers for videocassette the mighty 8-bit chips that appeared in recorders, and dozens of toys. The "4-bitter" 1974-had enough calculating power to was the hottest selling microprocessor every operate low-performance computers. These year until 1988, when 8-bit chips took the "microcomputers" were built around lead. microprocessors and remained curiosities, the electronic playthings of hobbyists, until MICROPROCESSOR 15 Microprocessors make modern airliners easier to fly by displaying flight instrument data on video screens, as in the cockpit of this advanced 747. These data display screens and other design improvements helped reduce the number of cockpit lights, switches, and gauges to fewer than 400 in this aircraft compared with nearly 1,000 in earlier models. the introduction of third-generation chips in tasks such as word processing. For instance, 1975. These delivered much better perfor- word processing software might be pro- mance than their forerunners and brought grammed SO that typing C-O-P-Y initiates down microprocessor prices to as low as $25 the thousands of instructions for duplicating from nearly $200. Within two years, they a page of text on the computer screen. spawned commercial lines of home micro- Software was not readily available for computers that were soon being used for the earliest microcomputers. Hobbyists nonhome tasks. labored to compose their own operating It was, however, the fourth generation- systems-programs telling a computer how mostly the powerful 16-bit microprocessors- to run itself-and application programs for that convinced the traditional computer tasks such as word processing or playing industry that microcomputers based on these Space Invaders. However, a cottage industry chips were powerful enough for more than of programmers began to sprout in the mid- home video games. And in 1981 the main- 1970s and was soon turning out commercial frame-computer industry began marketing programs for a multitude of applications, microcomputers for such computational including word processing, video games, tasks as graphics, desktop publishing, inventory control, and personal finance managing large data bases, and computer- management. aided design in business and industry. The combination of ready-made soft- Microcomputers would have been ware and low-cost microcomputers pro- Small, inexpensive personal useless without software, the programs of duced the true personal computer, a machine computers built around simple commands that tell computers how to so affordable and easy to use that it was microprocessors bring perform complex tasks. Each computer has available to almost everyone. The impact has computer power into millions of homes around the coded operating instructions already wired been enormous. PCs have done for comput- world. Ready-to-use programs into it, but they are awkward for people to ing power what the printing press did for have made it easy for children use. So the codes have been translated into knowledge-gave it to the masses. Connect- as well as adults to use these languages, such as BASIC, FORTRAN, and ed by telephone lines, PC users tap into computers for video games, COBOL, based on easy-to-use words and networks of computers as well as into data word processing, and dozens of other applications. symbols. The languages further simplify banks for stock quotations, medical informa- programming by using single symbols for tion, and legal cases. In the future they may some simple functions that are generated by be able to draw on data bases of library a series of instructions. For example, "X" books, newspapers, and magazines from all might trigger the series of instructions for the over the world. function "multiply". The languages, in turn, are used to program larger sets of instruc- tions, or programs, that perform complex 16 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE Today's microprocessors greatly outper- form their 4-bit ancestors. One 32-bit chip, for example, is a thousand times faster. Another carries 500 times more transistors, packing 1 million of them onto a chip no bigger than a postage stamp. Others-made by a process called CMOS, for complementary metal- oxide semiconductor-use less energy and produce less heat than conventional chips. They are used in satellites, portable comput- ers, and other devices where energy con- sumption is critical. The speed of some microprocessor chips has been improved by a design known as RISC, or reduced instruc- tion set computer, which uses a small number of simple instructions. Complex instructions, which occur infrequently, are handled in software. Larger memory chips have also been developed to hold the complex programs that exploit the power of the new microprocessors. In the future, multipurpose microproces- sor chips will probably grow to 64 bits, some containing as many as 10 million transistors. Application-specific processors will be designed for just a few specific tasks. Such chips are faster and more efficient at a single job than a chip designed to do everything. The key to making application-specific processors will be advanced computer-aided design (CAD) systems-themselves based on microprocessor chips-that design such specialized chips quickly and inexpensively. The new microprocessors and the systems they run will have the power to generate better graphics and higher-quality three-dimensional images for CAD systems. Microcomputers, for example, will certainly be more adept at human talents, such as understanding spoken words, speaking, or even learning and reasoning-artificial An even greater challenge lies in figur- The i486 microprocessor intelligence. And they will be able to process ing out how to take best advantage of the squeezes 1.18 million incredible amounts of data at lightning wonderfully powerful computers based on transistors-500 times more than the first speeds. Work is under way on a new genera- these new microprocessors. That is the task microprocessor-onto a chip tion of supercomputers, which would link of the programmers, whose work is limited about the size of an adult's hundreds, even thousands, of microproces- only by their ability to think creatively. thumbnail. sors in parallel arrays. Each chip would work on a different part of a massive problem, such as a global weather forecast, solving the entire problem in a fraction of the time needed if each part were solved one after the other. The challenge of parallel-array systems is to develop mathematical formulas and operat- ing systems to coordinate the work of all the microprocessors. MICROPROCESSOR 17 Computer-Aided Design and Manufacturing Hidden behind factory instructions for the automatic tools that will walls throughout the world, create the part. Small computers on the machines themselves allow the machines to another industrial revolution be quickly changed from producing one part is unfolding around the to making another. Small computers have computer. It is changing also spread to other areas of the factory, controlling manufacturing processes, industry as profoundly as operating robots that move pieces from one power machinery did in the machine to another, and guiding automatic eighteenth century and mass carts that move materials, parts, and finished products around the plant. production, typified by the Modern CAD and CAM systems began assembly line, did early this appearing on the market around 1970, following the marriage of CAD and CAM century. computer programs to minicomputers in the Computer-aided design and computer- $100,000 range. Previously they were limited aided manufacturing-CAD and CAM- to a few large manufacturers of aircraft, have already increased speed and efficiency autos, and textiles who wrote their own CAD for many manufacturers. They are improving and CAM programs and ran them on the quality of products while decreasing the mainframe computers that often cost a A worker sets up a computer- time to take them from idea to market. And million dollars or more. controlled profiling machine they are giving manufacturers the flexibility The roots of CAD and CAM reach back that cuts complex parts out of to respond to an ever-changing market. to two Air Force programs in 1949. CAD aluminum, steel, and titanium. The program of Essentially, CAD covers the use of hardware-the machines-began with instructions for making a part computers on the design side of a product efforts to build an air defense system by is usually generated on a while CAM refers to their use on the manu- linking radar to computers, whose data were separate CAM system, then facturing side. On the design side, engineers displayed on video screens. At the same transferred to the machine's use computer graphics to design the new time, the forerunner of CAM software- computer, which can store programs for dozens of parts. part or product. Other engineers use analyti- programs to run the hardware-began with cal programs to determine whether the part, the creation of punched tapes to operate as it is designed, will hold up under the numerically controlled (NC) machines. These stress of actual use. Drafters use computer- machines cut, drill, and perform other tasks ized devices to add detail to the design and according to instructions fed into their produce the final drawings. On the manufac- control units on a punched paper tape. Tapes turing side, computers help engineers write for the first generation of commercial NC machines were laboriously punched by hand. After the creation of a computer 18 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE The screen of a CAD/CAM system illustrates the complex tool path that a milling machine must follow to create the curving surface of an impeller blade for a jet engine. programming language called APT, for that store several programs for producing Automatically Programmed Tools, tapes different parts. were generated on mainframe computers. Computer-aided design has sparked its Modern CAM really began in 1969 with own revolution within the broader move- the appearance on the market of a less ment toward factory computerization. Like complex language, called Compact II, for the telescope and the microscope, CAD programming NC machines. Before then, systems have opened up new worlds of companies produced their NC tapes by understanding to the engineers who design, hand, made them with APT on a mainframe analyze, and test today's sophisticated computer, or sent the work to be done on a products. CAD is applied to nearly every time-sharing basis on an out-of-house large or complex engineering project under- mainframe. Compact II was initially a time- taken today, from designing modern jumbo sharing service. But later the program was jets to planning energy-efficient buildings. It sold to run on a minicomputer, further was, for example, extensively used in reducing the cost of the service. With such a designing Stars & Stripes, the racing yacht CAM system, an engineer could quickly that won the America's Cup competition write a program to produce a part, press a held in Australia in 1987. And CAD is button, and the computer would punch out absolutely essential for designing the tiny the correct instructions on an NC tape. The circuits in microprocessors and other inte- tape was taken to the NC machine to make grated-circuit chips that run most electronic the part. devices. Today, even easier languages have been The second wave of the CAD revolution introduced for programming NC machines. rose in 1981 with the introduction of single- In some systems, the tapes have been user CAD workstations. Workstation eliminated by hooking the programming computers are powered by microprocessors computer directly to the machine tool. And and generally have more computing power many NC machines have small computers COMPUTER-AIDED DESIGN AND MANUFACTURING 19 and graphics capability than personal market. They not only copied the circuit computers, which are also based on micro- pattern but also told the engineer whether processors. However, a workstation costs the patterns were too close together or about one-tenth as much as a minicomputer. violated any other design rules. In the early Today, the price of some workstations is 1980s, even more intelligent programs were under $10,000, and their power equals that of developed. Called "performance models," most minis. they could tell a design engineer what would Modern CAD did not spring full grown happen when electric signals flowed through into existence. It began as a drawing aid for the circuit and point out flaws in the design. Today, no self-respecting engineer would PIN spacing: 0.25 inches GRID: Snep 0.25 0.25 Select Count:1 HELP SETUP design a circuit without performance MINDOWS FILE BASIC ADVANCED Display every 1 modeling. PTF3 THE BTPA One of the first modern CAD systems for mechanical design arrived in 1971 on the heels of electronic CAD. It was really a BACK drafting aid that consisted of a drawing table, computer, screen, and plotting arm that digitized its movements: that is, translated them into digital electronic signals. By Scrxfer Select Group moving the plotter to different points on the Nove table and telling the computer what to draw Comment between them, a draftsman could copy a Propert design into the computer while watching it Delete Undo Redo materialize on the screen. After correcting the design, the draftsman pressed a button, and the plotting arm automatically redrew the -7.053.0.920,Edit design on a clean piece of paper. Called -Rectangle ALL SELect OBJect -7.853,-8.981,Edit Interact I, this mechanical CAD system ran on a minicomputer with four terminals and cost around $375,000. A microprocessor is designed drafters and developed along two parallel The early mechanical CAD systems with the aid of an electronic paths. One led through electronic design, could draw points, lines, circles, arcs, and CAD system. Using this and the other through mechanical design. symbols in two dimensions but with no program, an engineer can quickly design an electronic In the electronics industry, the great mathematical idea of what they were doing. circuit by placing and problem facing engineers in the late 1960s By 1973 more intelligent programs were connecting symbols of was the design of increasingly smaller and developed that could not only create three- components on the screen. more complex integrated circuits on tiny dimensional figures on the computer screen The computer automatically silicon chips. NC machines had been devel- but understood the geometry and mathemat- adds the details to the oped for cutting the stencil-like masks used ics associated with them. These were wire- final design. in etching circuit patterns onto chips. But frame models like the 3-D figures engineers instructions for the machines were still traditionally drew. calculated and punched into the tapes by More important than creating 3-D design hand. In 1970 one of the first commercial models, though, was the intelligence of such electronic CAD systems, called Design a CAD program. Using a mathematical Assistant, appeared on the market. It consist- model of the design in its data base, it could ed of a minicomputer, screen, sketch pad, answer questions from the engineer: How and keyboard plus software. The engineer long is that line? What is the area of this drew the circuit on the pad, watching the plane? Where is the center of gravity? And if, design appear on the screen. After correcting for example, the engineer tried to put a 2- mistakes, the engineer pressed a button, and inch piece in a space 1.75 inches wide, the An engineer uses a instructions for cutting the design were CAD program would reply that the piece workstation and a mechanical punched into an NC tape. This early CAD was 0.25 inch too long. It was smart enough CAD program to design system sold for about $150,000. But just two to calculate and draw a new line through a a new wheel hub assembly. years later, improved versions were selling model if the engineer so requested. It could for half that price. also calculate a section, in effect slicing the In the mid-1970s, new electronic CAD model in two SO the engineer could see how programs for "design rule check" came to the 20 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE parts fit together inside the design. And it office to another, where it may take 50 to 100 could turn the model to be viewed from hours to enter the data into another comput- different angles. This was not just a drafting er system. On the manufacturing side, device but a true CAD system that helped an computers are only slowly being applied to engineer design a part. tasks that they could perform faster and The newer mechanical CAD programs more effectively. In addition, many factories were also intelligent enough to perform could greatly increase their productivity by simple analyses on the design, to see how it joining isolated computerized systems into would hold up under the stress of actual use. integrated networks. Such computer- They could also prepare a design for more integrated manufacturing, or CIM, has complex analysis by dividing the model into begun in a few factories, and some of the the hundreds or thousands of geometrical results have been spectacular. For example, shapes that formed it. The data were then the highly integrated use of computerized sent to analytical engineers who tested the systems at one company that manufactures design on powerful mainframe computers. motor-starter components helps it produce This preparation, which the CAD program and ship the parts in less than 24 hours, a job did in seconds, would have taken engineers that used to take about 15 days. hundreds of hours to do by hand. Another challenge in computerizing the In the late 1970s, computer models of manufacturing process lies in integrating solid objects came onto the market. These were even better for analysis than 3-D wire- Von Mises frame models. Nevertheless, since there are Stress Top so many variables in designing a mechanical lbi/in**2 48248 part, mechanical CAD systems today are 46740 45233 only beginning to reach the level of perfor- 43725 42217 mance modeling that electronic CAD 40709 39202 systems achieved nearly a decade ago. 37694 36186 34678 However, programs are being developed 33171 31663 that allow engineers to analyze mechanical 30155 28647 systems for a large number of variables. For 27140 25632 example, engineers soon could be able to 24124 22616 model the performance of a mechanical 21109 19601 system as complex as a commercial power 18093 16585 plant. 15078 13570 12062 CAD programs of the late 1970s also 10554 9047 began linking to CAM systems on the 7539 6031 manufacturing side of factories, eliminating 4523 3016 the need for many paper design drawings 1508 0 and reducing the time manufacturing engineers need to write instruction programs for the NC machines that make the parts. computers throughout the company, not just An engineer uses a Previously, engineers had to study the paper at an individual factory. Such a CIM network mechanical CAD program to drawings in order to calculate tool move- might include finance, market forecasting, analyze stress on the lifting arm in the design of an ments. These CAD systems, however, could material ordering, customer service, and automobile jack assembly. simulate the movement of a cutting tool stocking, as well as CAD and CAM. Current The program creates a solid around the design model in order to deter- debate swirls around how to integrate the model of the device, top. It mine the necessary tool movements. These computers-whether to design one big uses a mesh to divide the were not only determined more quickly network or to integrate computers only lifting arm into small "finite elements" that are analyzed using CAD models, they were also more where and when it becomes necessary. Too for stress individually, center. accurate. much integration could flood and slow the The program then uses color In the future, engineers will seek ways to network with needless data. coding to indicate varying use CAD and CAM more effectively. Today Computers have found an indispensable levels of stress throughout the CAD programs are linked to CAM systems role to play in manufacturing through CAD, component, telling the in only a small number of factories. On the engineer where to strengthen CAM, and other automated systems. No one the design, bottom. design side of factories, separate CAD really disagrees. How big a role they will systems often exist independently in design, play, and when, are the real questions for the drafting, and engineering departments. future. Drawings are still often carried from one COMPUTER-AIDED DESIGN AND MANUFACTURING 21 CAT Scan Right: A patient lies quietly Ever since 1895, when as a CAT scan's x-ray tube shoots from hundreds of German physicist Konrad points around her head. Sensors opposite the tube Roentgen took the first record the strength of beams roentgenogram, x-ray pictures passing through the patient. With this data, the CAT scan have been clouded by shad- computer generates an image OWS of bones, teeth, and tissue showing the structure in that cross section of her head. piled together on one piece of film. But the marriage of modern computers to this old technology has given birth to a machine that produces clear, detailed images of things inside the body. The machine is called a CAT scan, for computerized axial tomography scanner. The wedding of computers to other diagnostic missed altogether by regular x-rays or other techniques has subsequently led to ultra- diagnostic techniques. A normal series of 30 sound imaging, magnetic resonance imaging scans is performed in about 20 minutes and (MRI), and other new procedures that peer usually without injections. CAT scans have inside the body without resorting to surgery. reduced the need for some diagnostic Indeed, many doctors believe that more techniques that require uncomfortable progress has been made in medical diagnos- injections and a stay in the hospital. tics since the CAT scan was introduced than The procedure has also revealed to in all previous medical history. researchers brain abnormalities in some CAT has so far had the widest impact of persons suffering from schizophrenia, A young man's vertebrae, the new imaging technologies. It has saved alcoholism, manic-depressive illness, and broken in a motorcycle untold numbers of lives by quickly finding Alzheimer's disease. CAT scans locate brain accident, appear almost tumors, infections, bleeding, and blood clots tumors precisely for radiation treatment and lifelike in a three-dimensional that would have been found too late or are used to build three-dimensional models image created from dozens of CAT scans. CAT scans are for reconstructive surgery. CAT is especially particularly good for showing good at finding internal injuries because it the fine detail of bone easily distinguishes between blood and structure. 22 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE A cross on this three- dimensional image generated from a series of CAT scans marks the location of a tumor near the center of the patient's head. Color coding shows sensitive areas, such as the eyes, spinal cord, and lungs, that should be protected from unnecessary radiation when the tumor is treated. tissue. Some hospitals now have a CAT CAT-often shortened to CT, for scanner in the emergency room, and the U.S. computed tomography-doesn't make a flat Army is developing a rugged, lightweight picture on photographic film, like a normal one that can be transported by truck or x-ray. Instead, it constructs a television image helicopter to medical stations in combat zones. CAT SCAN 23 An enhanced MRI scan shows a tumor growing in the spinal cord of a 4-year-old girl, who lost her ability to walk. A doctor quickly removed the tumor, and the girl eventually recovered the use of her legs. based on density measurements of a "slice" showing density patterns that reveal the fine of the patient. The process is something like structure of the slice. seeing a slice of salami without cutting the The practical CAT scanner emerged meat. from the confluence of several new technolo- To measure density, the CAT scan's gies. The most important developments were x-ray tube shoots a thin beam edge-to-edge low-cost minicomputers and, later, parallel- through a slice while circling the patient. array computers that could perform many Detectors circling opposite the tube measure calculations at the same time. These high- the strength of the emerging beam-and speed computers and the mathematically therefore the density of the slice-from complex programs to operate them made it hundreds of points around the patient. With possible to run millions of calculations for this information, the CAT scan computer each slice. In 1979 the Nobel Prize in physiol- calculates the density for each of more than ogy or medicine was awarded to British 250,000 tiny bits of tissue in the slice. It then research engineer Godfrey Hounsfield for displays these values in a television picture pioneering the CAT scan and to U.S. physi- cist Allan Cormack for work on the mathe- matics behind it. The first CAT scanners were 24 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE installed in Great Britain in 1971 and in the United States two years later. Today they are used in more than half of U.S. hospitals and in hundreds of clinics. Very small x-ray detectors and ultrasen- sitive signal amplifiers have greatly increased the speed of CAT scanning. An early scan took about 4½ minutes. Today it takes less than 2 seconds as a scanner's 1,000 detectors each record 2,000 separate measurements. The machine's sensitivity has improved, too. Now, for example, CAT can detect a liver tumor of almost the same density as normal tissue. The difference would not show up on a regular x-ray. Tomorrow's scanner will produce even more detailed images as scan slices become progressively thinner and scan times decrease even more. The patient will move continuously through the scanner, like a car on an assembly line, completing a 40- slice series in about a minute. And it may soon become routine for a treating doctor to beam the scan image via satellite to a consulting specialist thousands of miles away. Small, powerful computers have been applied to other diagnostic imaging tech- niques since the CAT scan. Each uses a different means of probing the patient, but the image is constructed by computer. Low- level radioactive isotopes are injected into the continued development of CAT, ultrasound Doctors discuss features blood during positron emission tomography imaging, and especially MRI should further revealed by MRI images. (PET) and single-photon emission computed reduce the need for exploratory surgery or MRI employs radio waves and magnetic fields to produce tomography (SPECT). With digital subtrac- invasive imaging techniques such as those images in which bones are tion angiography (DSA), a computer sub- involving injection of contrast agents that invisible. It is therefore very tracts an earlier x-ray image from another may occasionally cause allergic reactions. In useful for looking at soft one taken after a contrast substance has been fact, in 10 or 15 years, MRI may be able to tissue inside the skull and injected into the blood, leaving the clear perform an entire diagnostic chemical spinal column. contrast outline of blood vessels on the analysis of a patient, without breaking the second image. Ultrasound devices bounce skin. high-frequency sound waves off internal surfaces to indicate their position and motion. The most promising computer-assisted technique, though, uses magnetic fields and radio waves to coax information from the nuclei of atoms in body chemicals. This nuclear magnetic resonance imaging, or MRI, is particularly good for examining the brain and spinal cord, whose surrounding bone is invisible to it. CAT culminates the development of Roentgen's technology. And although traditional x-ray pictures still account for 80 percent of medical diagnostic imaging, they may one day be completely replaced by computer-generated video images. The CAT SCAN 25 Advanced Composite Materials The unusual design of the bricks stronger. Today steel rods are used to Starship business plane- reinforce concrete highways, bridges, and buildings. Resin reinforced by glass fibers is slender wings, vertical wing probably the most widely used composite tips, down-hanging rudder, today. and winglets on the nose- Advanced composites, however, are in a class alone. Most were originally developed masks the real revolution to provide lighter, stronger, more tempera- behind this aircraft. Its body ture-resistant materials for military aircraft Right: A strong, ultralight leg and wings are made entirely prosthesis of graphite/epoxy of advanced composite composite helps an athlete compete in world-class materials far lighter and bicycle races. stronger than the aluminum Giro most aircraft are made of today. As a result, the plane needs less maintenance than conventional aircraft and flies as far on a gallon of fuel as planes much smaller. Advanced composites like those in the Starship were unheard of 25 years ago. Yet they have already spread throughout the transportation industry and into everyday objects where higher performance provides an advantage. They add lightness and strength to racing boats and cars, golf clubs, and electric guitars. Composites are simply a matrix of one and spacecraft. Skyrocketing fuel prices in material reinforced by fibers or particles of the 1970s made the new materials attractive another. Humans have been making com- to civil aviation, where their lower weight posites since the ancients discovered that has helped cut the cost of operating airliners. putting straw into mud bricks makes the The broadening market and more efficient processing techniques have reduced the cost of composites to a level where they can now 26 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE Graphite/epoxy and other advanced composite materials are used to construct the entire body and wings of the Starship business plane and account for more than 70 percent of its overall structural weight. 18 be used in many other products, especially materials with higher strength-to-weight and sporting goods. stiffness-to-weight ratios than aluminum. The matrix of an advanced composite is The most promising was boron, which is often an organic material, such as epoxy stronger than steel but weighs less than resin, but can also be metal or ceramic. High- aluminum. The challenge, however, was to strength fibers, such as graphite or Kevlar, put it into a usable form. The best, easiest, are frequently used as reinforcements. But most cost-effective method turned out to be many combinations of matrix and reinforce- making it into a fiber that could be embed- ment are created for particular uses. Knowl- ded in a matrix of epoxy. Epoxy holds the edge about their interactions-how fibers or fibers in place, distributes the load among particles function within a matrix-is the key them, and protects them from the environ- to designing these high-performance ment. To make an aircraft part, strips of materials. And it has ushered in an era of epoxy tape with fibers running through it are designing new materials to meet new needs. laid in a mold in directions that will reinforce Advanced composites came directly out of Air Force efforts in the early 1960s to find ADVANCED COMPOSITE MATERIALS 27 In 1971 a U.S. company started making graphite fibers by a continuous process that took less than eight hours. These fibers cost only $125 per pound, and their price dropped steadily over the next decade. The first production graphite-composite parts went into F-15 aircraft delivered to the Air Force in 1974. And today's Starship business plane is made primarily of graphite/epoxy. The first commercial graphite-composite products, though, were sporting goods. In 1972 a California company began making golf club shafts of graphite/epoxy, which is stronger and lighter than the steel in conven- tional shafts. The new shafts appeared in Japanese golf clubs the following year. Graphite composite increased stiffness and reduced shaft weight by about 40 percent, allowing golfers to swing the club faster and drive the ball farther than they could with heavier clubs. Composite tennis rackets appeared next, followed by fishing rods, race-car chassis, and other sports equipment. Auto manufacturers are investigating graphite composite to replace steel in passenger cars, but its price is still generally too high to make it economical for mass- produced vehicles. However, since 1988 a graphite composite has been used to rein- force aluminum drive shafts on some light Layers of woven Kevlar sections where strength is critical. High heat trucks. fibers strengthen composite and pressure transform the epoxy into a Another high-strength fiber, Kevlar, is downhill snow skis while reducing weight and damping solid, lightweight part. Such composites widely used in composites where high vibration. Advanced were introduced to operational aircraft in tail tensile strength-resistance to being pulled composite materials are sections of the F-14, which was delivered to apart-is important but the stiffness of used in many sporting goods, the Navy in 1972. graphite fibers is unnecessary. Kevlar is a whose high performance Boron fiber is expensive. So parallel trade name for an aromatic polyamide, or P- provides a competitive advantage. work in England and Japan focused on aramid, fiber that is derived from petroleum. graphite as a less expensive high-strength It is lighter than fiberglass but five times fiber. Graphite is a form of carbon, and its stronger than steel on a pound-for-pound fibers are made by transforming organic basis. It appeared commercially as a replace- fibers such as rayon, acrylic, or pitch. ment for steel cord in radial tires in 1972. A The first high-strength graphite fibers high-strength form of Kevlar is used in resin- produced in the late 1960s were made by a matrix composites for aircraft bodies, sailboat time-consuming, labor-intensive process and hulls, snow skis, and artificial limbs. cost around $400 per pound. It began with an P-aramid fibers were discovered in 1965, acrylic fiber that was wound on steel racks to but the breakthrough came five years later in stretch the fiber and align its long molecules learning how best to convert the substance into stronger, parallel orientation. The fiber into much stronger fibers. P-aramid would was heated at low temperature to stabilize not melt like other plastics nor would it the orientation, then cut into strands and dissolve easily in any normal solvent used in slowly baked in a furnace with inert making synthetic fibers. The substance, it gas-usually nitrogen-to burn away turned out, needs an especially strong impurities. The remaining graphite fibers solvent-100 percent sulfuric acid-to were treated with chemicals to help them dissolve it. Normal sulfuric acid solvent bond to a resin matrix. contains about 3.5 percent water, but this is enough to keep P-aramid from dissolving in it. 28 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE In addition, P-aramid molecules would metallic nor organic-also have great not align themselves in strong, parallel strength and light weight, but brittleness orientation during a normal fiber-producing often limits their use. Reinforcements, process. Usually a solution containing a fiber however, can toughen them. Since the mid- substance is forced through a plate, called a 1980s, aluminum oxide reinforced with spinneret, with hundreds of tiny holes. The silicon-carbide whiskers has been used in emerging fibers are pulled directly into a cutting tools. Similar composites are being bath that leaches out the solvent, then developed as armor to protect helicopters, stretched to align the molecules before being armored personnel carriers, tanks, soldiers, wound around a spindle. This did not work and police. These composites are up to five with P-aramid. The problem was solved, times tougher than unreinforced ceramics, however, by stretching the fibers-and lighter than steel, and less expensive than aligning their molecules-in an air gap just other advanced materials now used for as they emerge from the spinneret. Then they armor. are pulled into a cold-water bath that leaches Ceramic composites are also being out sulfuric acid, gels the fibers, and fixes studied for use in car and jet engines, where molecular orientation. Finally the fibers are their light weight and heat resistance would dried and wound onto a spindle. substantially boost fuel economy. They may High-strength fibers and particles are find wider use in low-temperature applica- also embedded in metal matrices for use at tions where their ability to withstand hostile high temperatures that would melt organic environments gives them an advantage over A strong, light ceramic- matrices such as epoxy. Metal-matrix other materials. For example, ceramic-matrix composite tool cuts a thin composites, however, have a rather slim composites might be used in valves and chip from a fast-turning bar of tough nickel alloy. range of current applications in diesel and jet reactor vessels handling corrosive chemicals The durability of this engines, spacecraft structures, and high- or in structures, such as satellites, that must ceramic composite at high performance sports equipment. endure the harshness of space. temperatures allows it to The first commercial use of a metal- Carbon is similar to a ceramic, and withstand the heat produced matrix composite was in high-performance composites made of graphite fibers embed- in high-speed cutting. diesel engines by a Japanese automaker in ded in a matrix of graphite are extremely 1982. The composite, made of aluminum heat resistant. This carbon/carbon composite with various reinforcements, forms a is used in the nose and leading edges of the reinforcing ring around the crown of the space shuttle to protect against the searing pistons. It resists wear as well as steel but is heat of atmospheric reentry. And, because of much lighter. Many automakers are investi- its light weight and durability, it is being gating metal-matrix composites for use in used increasingly for wheel brake linings in pistons and other moving engine parts. military and commercial aircraft. Lightweight composite parts would use less Special composite materials are being energy and would reduce the total weight of developed for the experimental National the engine. Aero-Space Plane, which is designed to take The first actual use of a metal-matrix off and land on runways, cruise at hyperson- composite, though, was probably the ic speeds of Mach 6 (six times the speed of The National Aero-Space boron/aluminum structural tubing used in sound) or greater in the upper atmosphere, Plane flies far above the earth in an artist's the space shuttle, which first orbited the and reach Mach 25 while climbing into orbit. drawing. New advanced earth in 1981. Aluminum-oxide/aluminum The plane's skin, frame, and engines will composite materials are is now being used in handlebars of need to be extremely light, strong, and heat being developed for its skin, lightweight racing bicycles. And although resistant. The skin, in particular, will have to engines, and other silicon-carbide/aluminum is relatively withstand repeated exposure to extreme heat components that will allow expensive, it still costs less than half as much and cold and must be far thinner than the the space plane to climb into orbit or cruise in the as the beryllium it is replacing in an instru- composite tiles that protect the space shuttle. atmosphere at more than six ment housing for the inertial navigation The plane is scheduled to fly in the late times the speed of sound. system of a Navy ballistic missile. 1990s. But before it does, a new generation of Composites with ceramic matrices are advanced composites will have to be born. theoretically superior to metal-matrix composites for high-temperature applica- tions. Ceramics-materials that are neither ADVANCED COMPOSITE MATERIALS 29 Jumbo Jet People react much the same the introduction of jumbos in the early 1970s when a jumbo jet lumbers up reduced the immediate need to expand many airports or build new ones. In fact, no to the boarding gate: eyes major U.S. airport has been built since 1974. widen, jaws slowly drop, and The 747, DC-10, and L-1011 jumbo jets speech fails until the looming joined the commercial air fleet in 1970, 1971, and 1972, respectively, forming a necessary giant rolls to a stop just link in a chain of events that introduced long- outside the window. distance air travel to the masses. Since then the combination of rising fuel prices, lower To most passengers, a jumbo jet is huge air fares, and economical long-range jumbos outside, spacious inside, and a lot more has helped triple the annual revenue passen- comfortable to fly than lesser planes. To the ger miles (one RPM equals one paying airline industry, the jumbos, with their huge passenger carried one mile) logged by the capacities of 300 to 450 passengers or more, U.S. airline industry. In 1988, 420 billion are economy of scale. It is more economical, RPMs were logged, and the figure is project- for example, for an airline to fly 400 passen- ed to surpass 760 billion by the year 2000. gers in a single jumbo jet than 100 each in The origin of the jumbo jet lies in the four smaller planes. Jumbos also carry competition for the giant Air Force C-5A passengers much farther without costly cargo plane, which began operational flights refueling stops. Earlier jets with a range of in 1969. The challenge of building the jumbos about 4,500 miles, for example, had to refuel was to fit those design advances plus other in Hawaii during a flight to Tokyo from San state-of-the-art technologies into a huge Francisco. Some of today's jumbos, flying machine that was not only safer than earlier 6,500 miles or more nonstop, make the same airplanes but less expensive to operate. The trip uninterrupted from San Francisco, 747, for instance, reduced the per-mile cost of Chicago, or even New York. carrying a passenger 20 to 30 percent. Jumbo jets also help relieve air traffic The jumbos also introduced an era of congestion at airports, which can handle safer aircraft designed with a strong empha- The introduction of jumbo jets only a limited number of takeoffs and sis on several redundant, or backup, systems. in the early 1970s helped landings per hour whether the plane holds 4 The failure of a single system would not relieve air traffic congestion at airports. or 400 passengers. In the mid-1960s, when cripple the airplane. For instance, designers the first jumbo jets were designed, air travel of the 747 put four main landing-gear legs on was growing at a rate that would double the the plane instead of the usual two and added number of passengers every five years. But a middle spar to the wings. If the front spar were damaged in a collision, the middle and rear ones could hold the wing together for 30 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE landing. Designers of the L-1011 built in four They help the big planes fly farther, consume The size of jumbo jets sets separate hydraulic systems to operate the less fuel per passenger mile, and climb into them apart from earlier airliners, and so does their critical pitch control system-elevators and the sky with a murmur compared with the increased emphasis on safety. stabilizers-which moves the nose up or scream of earlier jet aircraft. Advanced metal The four main landing-gear down. Three are powered by the plane's three alloys, new cooling systems, and the high- legs on the 747 instead of engines and the fourth by an auxiliary power bypass design help the engines deliver the usual two are an example unit. The DC-10 was designed with five almost twice the thrust per pound of engine of the multiple backup generators-each of which can keep the weight, while using 20 to 25 percent less fuel systems that add a wide margin of safety to jumbo plane flying-plus an emergency backup per pound of thrust than conventional jets. battery system. Three of the generators are turbojet engines. powered by the aircraft's three engines, one The core of a high-bypass engine by an auxiliary power unit, and the other by operates like a pure turbojet, in which an extendable windmill. whirling compressor blades pull air into the The jumbo jets owe much of their engine's combustion chamber, where the air success to the high-bypass engine, which and fuel are burned. This creates a hot, was introduced to military aviation on the C- rapidly expanding gas that thrusts the engine 5A and to the commercial sector on the 747. JUMBO JET 31 forward. The gas also spins a turbine, whose temperatures. Creep causes cracking along shaft runs back through the hollow engine the boundaries between alloy crystals, which core to turn the compressor blades. form when the blade is cast. In earlier blades, The high-bypass engine, however, takes the crystals solidified in random alignments. advantage of the fact that for a given power Directional solidification, however, forces the level, a large volume of slowly moving air alloy to solidify in long crystals that grow will generate more thrust than a small from one end of the blade to the other. This volume of fast moving air. In the high-bypass eliminates crystal boundaries across the engine, the turbine also turns a wide fan at blade and so reduces creep and cracking. the front, which pushes a large mass of air Directional solidification begins by The high-bypass engine gets past the combustion chamber. The ratio of air pouring molten alloy into a mold that sits its name from the huge fan bypassing the combustion chamber to air inside a hot furnace. At the bottom of the that thrusts air past the combustion chamber, the flowing through it was 5:1 on the first mold is a water-cooled chill plate, where the section where the technician is commercial high-bypass engines and 8:1 on alloy starts cooling and crystals begin working. In the conical back military versions. The fat cowling covering forming. The mold is slowly lowered out of end of the engine, expanding the large fan clearly distinguishes the high- the furnace, causing the first crystals to gas from the combustion bypass engine from the slender, less efficient continue growing up in parallel columns chamber spins turbines on a shaft that turns the fan. turbojet. toward the top of the mold. Turbine blades The new engines are much quieter, too. made this way could operate at temperatures All the thrust of a turbojet comes from its Right: Nickel-alloy turbine exhaust, which shoots out at twice the speed blades cast as single crystals of sound with an ear-splitting roar. But a have greater strength and durability and higher high-bypass engine mixes quieter low- temperature capability than velocity air with the high-velocity exhaust to blades made of earlier slow its speed and reduce its noise. The noise materials. The wavelike level of the first DC-10's, for example, was patterns, enhanced for this about half that of earlier four-engine airliners. photo by chemical processing, are caused by minute chemical High-bypass engines are also more differences between parts of efficient than earlier turbojets in part because the crystal that solidify earlier they operate at higher combustion tempera- in the casting process and tures. Turbines in the new engines tolerate those that solidify later. burner-exit gas temperatures up to 2,800 degrees F, about 500 degrees greater than the earlier engines. Much of this higher tolerance results from new air cooling systems that allow turbine blades to operate in gas streams at temperatures higher than their material melting point. The blades are cooled by compressed air that is channeled around the combustion chamber and directed onto the whirling disk holding the blades. A up to 100 degrees F hotter than conventional pressure differential causes the air to flow blades. into the base of each hollow blade, where a The heat tolerance of turbine blades has network of passages carries the air through- since been raised another 100 degrees by out the blade to cool it from inside. As air making each blade out of just one crystal. escapes through strategically spaced holes, it With a single crystal and no boundaries, flows over the external surface in a protective engineers could remove from the alloy film that insulates the blade from hot gas. several boundary-strengthening ingredients Gas temperatures are 200 or more degrees that, essentially, had prevented the blades hotter than the melting point of the blades. from tolerating higher heat. The trick was to Large fans on the high-bypass Some of the increased engine perfor- select a single crystal that would grow both engines of these DC-10s push mance also came from an advanced process, vertically and horizontally to fill the entire air out the back of the silver engine cowlings while called directional solidification, for casting mold. The problem was solved by putting a combustion chambers shoot the nickel-alloy turbine blades. Whirling corkscrew bottleneck between the chill plate expanding gas through the blades under high centrifugal force tend to and the mold. As with directional solidifica- gray cones. creep, or elongate, at turbine operating tion, several crystals start to grow from the chill plate. But the bottleneck is small enough that only the crystal with the best horizontal 32 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE saudia ALL NIPPON AIRWAYS B EFF HZ-AHA saudia SAUDI ARABIAN AIRLINES and vertical growth properties can worm jumbos carry many fewer. In addition, the L-1011s, here under through the corkscrew into the mold. The three jumbo families will be joined by a construction, have four fourth, the A330/340, in the early 1990s. separate hydraulic systems for first single-crystal turbine blades went into added safety. They operate engines for the midsize 767 jetliner in 1982 Supersonic transports, such as the the elevators and stabilizers and subsequently into new jumbo-jet Concorde, generate an unacceptable sonic on the wings, which control engines. boom that limits their use over populated the pitch of the jumbo's nose. Many of the engineering advances areas. The next really advanced commercial developed for jumbo jets have been incorpo- aircraft therefore may be one that travels at rated in smaller aircraft. High-bypass hypersonic speeds at and above Mach 6 engines are now found on nearly all new (six times the speed of sound). A proposed commercial airliners of every size. The hypersonic plane, the National Aero-Space jumbos, in turn, are benefiting from new Plane, is expected to travel at speeds and technologies developed for commercial altitudes where its sonic boom would create aircraft in general: composite structural less of a problem. It will probably burn liquid materials, automated landing and flight hydrogen in a propulsion system that uses jet systems, and "all glass" cockpits in which engines while in the atmosphere and rockets instrument readings are displayed on color while in space. It remains to be seen, though, television monitors. whether hypersonic planes will become Over the next 10 to 15 years, the current economical for long-haul commercial family of jumbos will continue to expand in transport. In the meantime, the jumbos and size, range, and capability. Future jumbos their descendants will undoubtedly remain may weigh 1 million pounds, compared with the workhorses of the airlines into the 870,000 pounds today. They will carry over twenty-first century. 600 passengers more than 8,000 miles nonstop. Currently, only short-range jumbos carry that many passengers and long-range JUMBO jet 33 Lasers Before lasers were invented, in phase-crest next to crest, trough next to scientists dreamed of harness- trough. Coherency intensifies the waves' combined power, much as football fans ing the unique properties of intensify their combined sound by chanting light to study the swift motion in unison. In addition, the waves are almost of molecules, atoms, and perfectly parallel and so travel in nearly the same direction. This directionality keeps the electrons. The military wanted waves concentrated in a narrow beam that light's awesome power to widens only gradually over great distance. annihilate enemy tanks, Incoherent light waves from the sun, light bulbs, and other nonlaser sources travel out planes, and missiles. Once of phase at different frequencies in a beam the practical laser was built, that quickly spreads and disappears from however, the "glamorous sight. Laser waves are no more powerful than blowtorch" began doing jobs waves of other light. But, because of their no one had dreamed of. Today unique properties, they are easily focused to lasers play music, read price a point that can vaporize diamond and steel. Where continuous power of this magnitude tags, carry phone calls, cut is needed, the carbon dioxide laser has been cloth, perform surgery, and the workhorse since it was introduced test the quality of air. And commercially in 1967. It drills holes in hard ceramics, cuts through composite materials, although the military is still and heat-treats metals to harden them. A waiting for a light-ray CO2 laser beam focuses to a fine point for the weapon, lasers have become delicate work of cutting cloth or drilling holes in rubber baby-bottle nipples. Doctors standard research tools for use the CO2 laser as a surgical knife; the laser scientists and engineers in cauterizes blood vessels as it cuts, eliminat- laboratories around the world. ing much bleeding. Because light from a CO2 A carbon dioxide (CO2) laser laser is infrared and thus invisible, a red, cuts heavy-duty circular saw The word laser stands for light amplifica- low-energy helium-neon laser is often used blades from 1/4-inch steel tion by stimulated emission of radiation, and to aim it. sheet. The powerful CO2 laser, the workhorse of industry, has laser light is unlike any other. Light waves Laser light is useful, too, in other areas of been applied to a wide from a laser all have the same frequency, medicine. Its single-frequency nature lets a assortment of tasks, ranging creating a beam with one characteristic color. from tough metal work to The light is also coherent, its waves traveling delicate surgery. 34 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE A researcher aims the beam from a YAG (yttrium- aluminum garnet) laser at a sample of gallium arsenide in an experiment to measure impurities in the semiconducting material. laser zap one kind of tissue while causing patterns act like a complex system of micro- little harm to another. This is because some scopic mirrors. They reflect back the object's materials absorb more light energy at one image if the original laser light is shined on particular frequency than at others. The the film at the original angle. The patterns are colorless central portion of the eye, for so intricate that they reflect a slightly differ- example, absorbs little of the argon laser's ent image in slightly different directions. This green light, which is readily absorbed by lets you see the object from different angles blood-containing tissue at the back of the and gives the image its three-dimensional eye. Doctors, therefore, use the low-powered quality. argon laser to spot weld detached retinas and Holograms are difficult to counterfeit seal the leaking blood vessels that often blind and so are used as tamper-proof seals on diabetics. Lasers also vaporize brain tumors, boxes of videocassettes and auto parts as perform delicate inner-ear surgery, and well as on credit cards and passports. remove warts and gynecological cysts. Laser Double-exposure holograms are used widely light goes inside the body through fiber-optic for quality control in, for example, the endoscopes to burn fatty deposits out of aircraft tire industry. Disruptions in the clogged arteries, pulverize kidney stones, delicate wave pattern on a double exposure stanch bleeding stomach ulcers, and open of a tire reveal defective bulges only blocked fallopian tubes. 6 millionths of an inch high. Since 1980 Coherent light is necessary for construct- holograms have been used to direct the beam ing the three-dimensional pictures called in many laser scanners that read price bar Rows of microscopic bumps holograms. They are made by shining one codes at checkout counters. Holograms on a on this video disc carry digital part of a laser beam directly onto photo- whirling disc bend a red helium-neon laser information that is read by a laser and translated by graphic film while bouncing the other part beam in different directions, allowing it to computer into visual images. off an object and then onto the film. Waves scan for the bar code up to 1,800 times per from the two beams interfere with each other second. The light pattern reflecting back to in complex patterns that are recorded on the film. When the film is developed, these LASERS 35 sensors from any successful scan will The semiconductor laser quickly became transmit the code. the key to compact disc (CD) recordings, The directionality of laser light makes it which store large amounts of information very useful for aligning new buildings, and can be played at home. CDs were tunnels, and pipes as well as leveling and invented in the Netherlands, and the first grading land. And the ability to switch them audio CDs were introduced in Japan in 1982. rapidly on and off lets lasers produce the tiny Information for a disc is translated into the pulses needed for timing measurements of 1's and O's of digital code and then stamped long distances. Lasers can generate pulses of onto the upper side of the disc in a series of less than 0.1 billionth of a second-far long pits. To read the information, a pin- shorter than those made by mechanical or point laser beam scans the bumps on the electrical switches. By timing pulses bounced underside. Flat surfaces between the bumps off reflectors placed on the moon by U.S. reflect a strong return beam; bumps scatter astronauts and Soviet unmanned landers, the light and weaken the beam. Sensors laser instruments measure the earth-to-moon detect differences between strong and weak distance with less than 1 centimeter of error. beams, interpreting them as digital code. Scientists use even shorter laser pulses to Music, video, and computer data can all be observe the lightning movement of atoms, stored in digital form on compact discs. molecules, and chemical reactions. The Other types of laser are especially useful pulses can, in effect, take "snapshots" for probing the environment. Government quickly enough to prevent blurring. One agencies and private organizations around laser system generates a pulse of just the world use ground-based and airborne 6 quadrillionths of a second, fast enough to lasers to measure air pollution, monitor the take step-by-step shots of a chemical reaction weather, and study climate. Laser instru- lasting only 100 quadrillionths of a second. ments have been used to study holes in the Lasers are also good for measuring very ozone layers over the North and South poles, slow movements. Geologists use them to particulates and gases over the Amazon rain measure the almost imperceptible creep forests, and dust drifting across the Atlantic along the San Andreas Fault in California. from the Sahara. A two-laser device on one side of the fault Laser radar, or lidar (light detection and A fraction of a second after shoots red and blue beams at a reflector ranging), detects airborne particles of dust, the flash of an ultraviolet farther up the fault on the other side. One laser beam, a "smoke" plume moisture, and chemicals by measuring the beam could be used to measure the distance. erupts from the corneal strength of laser light reflected back to the surface of the eye, shoots But by comparing two beams of different instrument. These fine particulates are upward, and turns into a frequencies, geologists calculate how much invisible to normal radar. Weather scientists microscopic mushroom cloud the atmosphere has slowed the beams on a use lidar plus knowledge of the Doppler shift during a surgery experiment. given day. With this information, they Laser beams of other to study wind speeds. Light reflected off frequencies pass harmlessly compensate for measurements taken under particles moving with the wind changes through the cornea to perform different atmospheric conditions. Shooting at frequency, which gets higher if the particles surgery inside the eye. a reflector 5 kilometers away, the instrument are moving toward the observer and lower if can detect a shift in the earth of only they are moving away. A similar frequency 2 millimeters. shift causes a train whistle to sound higher The ability to develop lasers with special while a train approaches and lower as it talents opened the door to their use in speeds away. communications in the 1970s. The break- Another system, called differential through came with development of a absorption lidar, uses laser beams at two semiconductor laser that operates at room frequencies to detect the presence of a gas in temperature, is smaller than a grain of sand, the atmosphere and measure whatever is and produces a light frequency that travels there. The first beam uses lidar to measure well through glass optical fiber. This laser the light reflected back by particulates. The made it practical to use fiber-optic cables for second beam, at a wavelength absorbed by a long-distance telephone lines that carry gas such as ozone, scans the same area. Some thousands of calls at once. The installation of of its light is absorbed by the gas but some is fiber-optic telephone cables since then has reflected back by particulates. The amount of expanded long-distance telephone service gas in the air and its location are revealed by and reduced its cost. comparing the return echoes of the two beams. 36 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE A laser beam shoots moonward from an observatory, left, in a test to learn whether a laser could hit a small target on the moon. Laser beams from this and another observatory appear as two tiny dots of light, above, sparkling on the dark side of the earth in a photo taken from the moon by a television camera In the future, laser research will aim at schemes because they can be operated by on the Surveyor 7 lunar reducing the size and cost of lasers while computer and used by robots. And, because probe. This test led to the use of lasers for measuring the expanding their versatility. Technology is light beams are quickly redirected with earth-to-moon distance. being developed for arrays of tiny semicon- mirrors and fiber-optic cables, lasers can be ductor lasers-which are limited in assigned new jobs without costly retooling. size-that develop enough power for devices The fastest growing field for lasers, such as printers and facsimile machines. The though, is undoubtedly medicine. Lasers are search for a powerful laser that can be tuned being investigated for reshaping the cornea to many frequencies has sparked interest in to correct eye problems. They are being the free-electron laser. This laser generates tested for activating toxic anticancer drugs light by sending electrons through a periodi- that accumulate in tumors but pass through cally alternating magnetic field. Its periodici- the rest of the body. And lasers are being ty or its strength can be altered to change the used experimentally for drilling new blood frequency of the light beam. channels in weakened hearts and for other At the same time, existing lasers are techniques aimed at reducing heart disease, being applied to many new tasks. Lasers will the leading cause of death in the United find use in industries seeking greater speed States. and efficiency. They fit well into automation LASERS 37 Fiber-Optic Communication Right: Ultrapure glass fibers The information revolution encased in protective ribbons are the mainstay of fiber- of the 1960s created such an optic communication systems. avalanche of data that futurists saw it soon over- whelming the telephone lines and radio waves that carry information around the globe. That vision-and the invention of lasers-spurred research into the tremendous potential of light, which can carry thousands of times more information than either electric signals or radio waves. The work led in 1970 to a very transparent glass thread called TAT-8 and laid in 1988, is the first whose appearance quickly transoceanic fiber-optic cable. TAT-7, the copper cable laid in 1983, carries less than a opened the door to fiber-optic fourth as many calls and is twice as thick. communication, a technology The huge capacity of optical fibers translates able to channel the flood of into lower construction cost per telephone circuit. The first trans-Atlantic copper cable, information into the twenty- for example, cost more than $1 million per first century. circuit to install in 1956; 32 years later, TAT-8 cost less than $10,000 per circuit. Today's optical fiber is thinner than a Waves of light carry more information human hair. Yet it carries so much informa- because they have higher frequencies- tion that four fibers-two in each direction- measured in wave cycles per second, or in a trans-Atlantic telephone cable are hertz-than either radio waves or the electric handling up to 40,000 calls at once. The cable, waves on copper telephone wires. High- frequency waves can be switched on and off faster than low-frequency waves, SO they can 38 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE The green light of a an argon laser flows through several miles of experimental optical fiber wound around a spool. Similar hair-thin optical fibers are the heart of cables that carry 40,000 or more simultaneous telephone calls on beams of laser light under oceans and across continents. be divided into more pulses per second. The megahertz, 100 million times higher than a pulses and gaps between them represent the typical AM radio signal and 100 billion times 1's and 0's of digital information. The higher than an electric telephone signal. infrared laser light used in optical telephone Fiber-optic communication became cables has a frequency of about 100 million practical with the development of fibers that carry light pulses a substantial distance FIBER-OPTIC COMMUNICATION 39 Below: Fiber-optic cables before needing a repeater. Their cores are expensive than lasers. Although their signals carry many more communica- made of silica glass, one of the most transpar- deteriorate over long distances, LEDs are tion signals than do copper cables of similar size. Fiber ent solid substances known. Impurities in efficient for short links between, for example, cable laid in the trans-Atlantic early glass fibers weakened pulses SO much a compact-disc player and stereo amplifier or link is less than half the size that light lost 99 percent of its energy after computers in a local network. of copper cable used in an just 20 meters. But a new chemical process, Optical fibers can handle many times earlier link but carries more pioneered in the 1970s, now produces cores more information if they carry light pulses of than four times as many telephone calls. of such high transparency that fibers in TAT- several frequencies at the same time. The 8 need only 101 repeaters to boost signals bandwidth of light (its range of frequencies) across the Atlantic. TAT-7, the copper cable, is about 10 billion megahertz from infrared to needs 662. ultraviolet and can be divided into millions The debut of a practical fiber coincided of signal channels, each at a slightly different with the development of other technologies frequency. Radio waves cover a relatively needed for fiber-optic communication. In tiny bandwidth, leaving little room for 1970 a room-temperature, semiconductor multiple channels. The bandwidth is even laser was built that could transmit well- smaller for electric channels. defined pulses through long-distance optical Most optical fibers today carry light of fiber. Photodetectors were developed that only one frequency, although they are could handle the torrent of pulses pouring capable of transmitting several more. So far, The C.S. (Cable Ship) Long out the other end and convert them into it has proved economical to use multifre- Lines laid more than 3,600 electric signals. For short-distance systems, quency systems only in special cases of miles of the TAT-8 fiber-optic cable, from the United States tiny light-emitting diodes (LEDs) were growing demand where limited numbers of to a point off the coast of devised that use less power and are less fibers have already been installed. For Europe. From there, British example, fiber pairs that were carrying and French ships laid branch 24,000 voice circuits between Chicago and cables to their respective Philadelphia have been upgraded to transmit countries. In all, nearly 4,200 miles of cable were laid. 40 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE two frequencies, so they now carry 48,000 circuits. Fiber-optic communication has other advantages over radio and electric channels. Light signals do not produce the external halo of electromagnetic waves that surround electric telephone lines and cause "cross talk" between them. Optical fibers are also relatively secure from unwanted eavesdrop- pers, who can easily intercept radio waves or tap electric telephone signals without being detected. Optical fibers have been quietly weaving into communication networks since the first commercial system opened in Chicago in 1977. Since then more than 1.5 million miles of optical fiber have been installed across the United States; copper cables are no longer laid for main lines between U.S. cities. An undersea fiber-optic cable that U.S. and Japanese cable ships laid across the Pacific was activated in 1989. Optical fibers have also been adapted for sensing movement in gyroscopes, linking industrial lasers to cutting and drilling tools, and threading light into the human body for examinations and laser surgery. A future engineering challenge lies in building a computer that uses light instead of electricity. Theoretically, an optical computer would be 1,000 times faster than the best United States, Great Britain, Japan, France, A technician in Philadelphia modern supercomputers. Another challenge Canada, and West Germany have been checks a device that uses closer to home is in stringing fibers to running optical fibers to homes on an microprocessors to pinpoint a malfunction among signal individual users from the optical main lines experimental basis since 1980. Once econom- regenerators along the that now exist. At present, copper wires ic and regulatory obstacles are overcome, the heavily used fiber-optics line connect homes to central telephone pace of replacing copper wires with optical between New York City and exchanges, where electric signals are convert- fibers to individual homes in the United Washington, D.C. ed into light pulses that are channeled into States should pick up. Economical optical the main lines. Telephone authorities in the switches and converters for such "end-to- end" systems still need to be developed. But early in the twenty-first century, many Left: Optical fibers can be people could be enjoying hundreds of threaded into the ureter, the television shows, movies, newspapers, and tube leading from the bladder to the kidney, to bring in books brought into their homes through a laser light that dislodges single, hair-thin optical fiber. kidney stones. The photo here shows a laser chipping a kidney stone into fragments small enough to pass through the ureter naturally. FIBER-OPTIC COMMUNICATION 41 Genetically Engineered Products The first fruits of genetic in late 1987. It quickly dissolves blood clots engineering-the products that cause heart attack and prevents their recurrence. It is already standard treatment made by organisms implanted for heart attack victims at hundreds of U.S. with a foreign gene-have hospitals. contributed handsomely to These and other genetically engineered products now available are created through human welfare in the few the efforts of biologists and engineers. It is short years since they biologists who "engineer" new organisms by appeared. splicing a gene from one organism into another. Traditional engineers provide an Insulin, needed by millions of diabet- indispensable bridge from biology lab to the ics, has been produced commercially by public. They design and build the mechani- genetically engineered bacteria since 1982. cal systems that allow the new organisms to The product is identical to human insulin grow in large quantities and that process the and so does not cause the allergic reactions valuable substances the organisms produce. sometimes produced by insulin derived from In addition, they develop complex laboratory animals. Nor is its supply subject to the ups instruments that simplify and speed the and downs of the livestock market. work of genetic engineering. Human growth hormone (HGH), A genetically engineered product begins Technicians inspect the needed for normal physical development, with biologists who find a gene that pro- control unit at the bottom of has been available as a genetically engi- duces a valuable substance such as HGH. a large-scale evaporator used in the final steps of purifying neered product since 1985. Previously, many Using enzymes that dissolve bonds to human insulin produced by of the more than 10,000 U.S. children low in neighboring genes, they cut the valuable genetically engineered HGH could not get treatment with the gene out of the DNA, the genetic material of bacteria. natural substance, which is extracted in tiny a cell. Then they insert this gene into another amounts from the pituitary glands of organism-such as the common bacterium cadavers at autopsy. And in 1985, distribu- Escherichia coli-that will multiply itself and tion of HGH from this source was stopped the foreign gene along with it. after evidence suggested it might be contam- Once the genetically engineered "bug" inated with a virus causing a rare, fatal has been created, engineers design a system disease. Today, however, there is plenty of in which its product can be produced and pure biosynthetic HGH. processed in large quantities at a reasonable Tissue-plasminogen activator, or t-PA, cost. The production of human insulin, the appeared as a genetically engineered product first commercial product of genetic engineer- ing, is a good example. It was developed in the United States and appeared commercial- ly under the trade name Humulin, first in the 42 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE A spiraling chain of DNA, the genetic blueprint of life, shimmers in this computer- generated molecular model. Certain DNA segments make up the genes that produce insulin, human growth hormone, and other important substances. United Kingdom and later in the United carbon dioxide that flowed out were decon- States. taminated. A special double seal was The insulin molecule is composed of two invented to prevent the escape of microbes parts called A and B chains. The original from around the shaft of the paddle-like Humulin process used two versions of E. coli agitator that stirred the culture. And the to produce the chains. One version contained tanks were designed to function under a gene producing A chains and the other negative pressure-the opposite of conven- contained the B-chain gene. Each version tional tanks-to suck back any bacteria that was grown, or fermented, in a large separate otherwise might escape. Engineers also tank. The chains they produced were developed a new pasteurization system hot extracted from the bacteria and purified. enough to kill the bacteria as they were Afterward, A and B chains were combined in withdrawn from the tanks, but cool enough a third vessel. The complete molecules were not to damage the A or B chains. then purified and crystallized into a usable The big challenge in producing form of human insulin. Humulin, however, was in scaling up The Humulin process demanded special production from expensive 10-liter batches in engineering to handle the uncertainty the laboratory to less expensive batches of surrounding the first large-scale use of 40,000 liters in the factory. The scaleup was genetically engineered microbes. Scientists in particularly difficult because these bacteria the late 1970s did not know whether such store the A or B chains within themselves, bugs might survive in nature and contami- unlike microbes that produce antibiotics and nate the environment. So the bacteria were secrete them. Engineers devised a way to grown in closed stainless steel tanks with the extract the chains by pressurizing the cells in inflow of nutrients and oxygen carefully a tank and then shooting them out into controlled by computer. Water vapor and normal atmosphere, where the pressure change caused the cells to explode like balloons and release their contents. The GENETICALLY ENGINEERED PRODUCTS 43 chains were separated from cell debris in degrade pesticides, or to turn organic waste several steps ending with high-performance material into useful products. They may one liquid chromatography. This laboratory day use genetically altered bacteria to loosen technique is performed by pouring a mixture underground oil so it can be pumped to the through a pencil-sized column of material surface or to leach precious minerals from that sifts out certain molecules. But for large- ore. scale Humulin production, columns 10 feet Perhaps the biggest contribution of tall and 12 to 16 inches in diameter had to be traditional engineering to this field has been designed. Today, Humulin is produced by a the development of instruments that speed the process of genetic engineering and expand its possibilities. Two devices-the protein sequencer and the DNA synthesizer- have already had tremendous impact on the detective work of genetic engineering. For instance, one biologist working with a DNA synthesizer can do the amount of work in one afternoon that would have taken 25 biologists five years to complete in the early 1970s. The discovery of a valuable gene often begins with identifying the sequence of amino acids in the protein it produces. There are only 20 different amino acids. But the chainlike protein molecules have hundreds of amino acids linked in specific order. An instrument that can decipher this sequence appeared on the market in 1969. It is essen- tially a computer-controlled plumbing device that uses solvents to cut one amino acid at a time from the end of a protein molecule. The first insulin produced by similar, but more efficient process involving a Knowing the amino acid order, biologists can bacteria implanted with new type of genetically engineered bacteria identify the gene that made the protein. human insulin genes was and only one fermentation tank. Another device, which entered the processed into crystals. The insulin must be separated Traditional engineers are not directly market in 1982, can actually build small from the bacteria and involved in some other aspects of genetic genes or gene fragments out of DNA-the purified in relatively large engineering, such as the genetic alteration of genetic material found in cells. A DNA quantities in order to be plants and animals or the potential treatment synthesizer hooks together subunits, called useful to many diabetics. of humans with genetic disorders. They are, bases, in the proper order for a particular however, becoming more involved with gene or gene fragment. These synthetic genes processing the products that are produced by and fragments can then be used for several genetically altered plants and microorgan- purposes, including genetic engineering. For isms. Biologists are modifying organisms to example, the genes that produce Humulin produce everything from pharmaceuticals to are really synthetic genes created by a DNA food processing agents to specialty chemi- synthesizer. cals. In fact, the greatest use of genetic The dream machine of genetic engineer- engineering in the future may be in the ing, though, is a device that can rapidly production of products that are now created sequence DNA, much as proteins are by chemical processes, which often involve sequenced. Human DNA contains more than high temperatures and pressures as well as 3 billion bases, and today's DNA sequencers toxic by-products. Biological synthesis, on can analyze only about 9,000 bases per day. Potentially useful genes are the other hand, usually takes place at room The challenge for today's engineers is to often identified by analyzing temperature under normal pressure and develop in the next four or five years the proteins they produce. A protein sequencer is used to produces biodegradable waste. machines that are at least 10 times faster than determine the order of amino In the meantime, people have already present sequencers. acids making up a chainlike begun to investigate the use of genetically The amount of genetic information protein molecule, thereby altered microbes to clean up toxic waste, already being generated by DNA sequencers uncovering the identity of the is overwhelming. To check a new sequence gene that made it. against the massive, growing data bank of 44 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE 2-8-84 Tracy 10-5-83 TRUCK 2-28-83 known sequences will require faster comput- Work is under way to determine the For nine years, a deficiency in er systems. One under development uses a entire sequence of human DNA, called the human growth hormone (HGH) genome, and map the location of all 100,000 stunted the growth of this series of 500 or more microprocessors that California girl. But in her can each be programmed to recognize one of or so genes. This data would reveal more tenth year, injections of HGH the four types of DNA base. Essentially, the about human biology and disease than has produced by genetically series is programmed to reflect the order of been learned in the past 200 years. Scientists altered bacteria stimulated bases in the new DNA sequence. As known and engineers would dearly love to map the a 5-inch burst of growth, sequences from the data bank flow past the entire human genome. With the right tools, catching her nearly up to the normal height of a girl her series, each microprocessor "lights up" when they may soon do it. Completing the project age. its particular base passes by. When all light would be, some believe, the biological up together, they signal the location of an equivalent of putting a man or woman on identical sequence in the data stream. Using the moon. this recognition system, the computer can search the DNA data bank for similar patterns thousands of times faster than existing computers. GENETICALLY ENGINEERED PRODUCTS 45 Further Reading Moon Landing Computer-Aided Design and Bilstein, Roger E. Stages to Saturn: A Technical Manufacturing History of the Apollo/Saturn Launch Vehicles. Loeffelholz, Suzanne. "CAD/CAM Comes Washington, D.C.: NASA, 1980. of Age." Financial World, October 18, 1988, Brooks, Courtney G., James M. Grimwood, pp. 38-40. and Loyd S. Swenson, Jr. Chariots for Pond, James B., and Robert E. Harvey. Apollo: A History of Manned Lunar Space- "Dream Factories Leap-Frog the Opposi- craft. Washington, D.C.: NASA, 1979. tion." Iron Age, November 15, 1985, pp. 26- Hallion, Richard P., and Tom D. Crouch, eds. 36. Apollo: Ten Years Since Tranquility Base. Mitchell, Larry D. "Computer-Aided Design Washington, D.C.: Smithsonian Institution and Manufacturing." McGraw-Hill Press, 1979. Encyclopedia of Science & Technology. New Pellegrino, Charles R., and Joshua Stoff. York: McGraw-Hill, 1987. Chariots for Apollo: The Untold Story behind the Race to the Moon. New York: CAT Scan Atheneum, 1985. Andreasen, Nancy C. "Brain Imaging: Applications in Psychiatry." Science, Application Satellites March 18, 1988, pp. 1381-1388. Badgley, Peter C. "Remote Sensing." Randal, Judith E. "NMR: The Best Thing McGraw-Hill Encyclopedia of Science & Since X-Rays?" Technology Review, January Technology. New York: McGraw-Hill, 1987. 1988, pp. 59-65. Canby, Thomas Y. "Satellites That Serve Us." Sochurek, Howard. Medicine's New Vision. National Geographic, September 1983, Easton, Pa.: Mack Publishing, 1988. pp. 281-334. Sochurek, Howard. "Medicine's New Heckman, Joanne. "Ready, Set, GOES: Vision." National Geographic, January 1987, Weather Eyes for the 21st Century." Space pp. 2-40. World, July 1987, pp. 23-26. Rasool, S.I. "Applications Satellites." Advanced Composite Materials McGraw-Hill Encyclopedia of Science & Chou, Tsu-Wei, Roy L. McCullough, and R. Technology. New York: McGraw-Hill, 1987. Byron Pipes. "Composites." Scientific American, October 1986, pp. 192-203. Microprocessor Office of Technology Assessment, U.S. "EDN Microprocessor Issue." EDN, October Congress. Advanced Materials by Design. 27, 1988. Washington, D.C.: U.S. Government Garetz, Mark. "Evolution of the Microproces- Printing Office, 1988. sor: An Informal History." Byte, Septem- Rapson, Robert L. "Advanced Composites" ber 1985, pp. 209-215. (under "Composite Material"). McGraw- Grossblatt, Robert. "A Decade of Change: Hill Encyclopedia of Science & Technology. The Microprocessor." Radio-Electronics, New York: McGraw-Hill, 1987. April 1986, pp. 61-65. Steinberg, Morris A. "Materials for Kerr, Douglas A. "It's 16 Bits, But Is That Aerospace." Scientific American, October Wide or What?" Creative Computing, June 1986, pp. 67-72. 1985, pp. 40-45. 46 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE Jumbo Jet Genetically Engineered Products Aeronautical Staff of Aero Publishers. DC-10 "DNA: Inherited Wealth." The Economist, Jetliner. Fallbrook, Calif.: Aero Publishers, April 30, 1988, Biotechnology Survey, 1973. pp. 3-18. Ingells, Douglas J. The L-1011 Tristar and the Eskow, Dennis. "Here Come the Assembly- Lockheed Story. Fallbrook, Calif.: Aero Line Genes." Popular Mechanics, March Publishers, 1973. 1983. pp. 92-96. Ingells, Douglas J. 747: Story of the Boeing Hood, Leroy. "Biotechnology and Medicine Super Jet. Fallbrook, Calif.: Aero Publish- of the Future." JAMA, March 25, 1988, ers, 1970. pp. 1837-1844. Stewart, Stanley. Flying the Big Jets. New Weaver, Robert F. "Beyond Supermouse: York: Arco Publishing, 1985. Changing Life's Genetic Blueprint." National Geographic, December 1984, Lasers pp. 818-847. Ausubel, Jesse H., and H. Dale Langford, eds. Lasers: Invention to Application. Washington, D.C.: National Academy Press, 1987. "Lasers Then and Now" (special issue). Physics Today, October 1988. Lavrakas, Paul. "Laser: The Healing Light of Medicine." Consumers' Research, October 1985, pp. 11-15. Townes, Charles H. "Harnessing Light." Science 84, November 1984, pp. 153-155. Fiber-Optic Communication Hubbard, W.M. "Optical Communications." McGraw-Hill Encyclopedia of Science & Technology. New York: McGraw-Hill, 1987. Koepp, Stephen. "Calling London, on a Beam of Light." Time, January 19, 1987, p. 52. Lucky, Robert W. "Message by Light Wave." Science 85, November 1985, pp. 112-113. Slutsker, Gary. "Good-Bye Cable TV, Hello Fiber Optics." Forbes, September 19, 1988, pp. 174-179. FURTHER READING 47 Acknowledgments Hugh McIntosh researched and wrote the Advanced Composite Materials 10 stories. H. Dale Langford and Douglas L. Martin Burg, Composite Market Reports; Wolford edited the text, and Pamela Reznick Tobey M. Cordell, Wright Research and designed the booklet. We would like to thank Development Center; James A. Fitzgerald, the scores of persons who contributed their Du Pont; Bernard H. Kear, Rutgers Universi- expertise, including the following who ty; Steven E. Russell, Hercules Aerospace; provided invaluable advice in the prepara- Jacques E. Schoutens, Metal Matrix Compos- tion of the manuscripts: ites Information Analysis Center; John D. Venables, Martin Marietta; Klaus M. Zwilsky, Moon Landing Robert A. Duffy, Charles National Research Council. S. Draper Laboratory; William F. Ezell, Rocketdyne; Joseph G. Gavin, Jr., Grumman; Jumbo Jet Leon R. Anderson, Pratt & David G. Hoag, Charles S. Draper Laborato- Whitney; Alexander H. Flax, NAE; Maurice ry; Samuel C. Phillips, U.S. Air Force; Henry L. Gell, Pratt & Whitney; Willis M. Hawkins, O. Pohl, NASA; James B. Skaggs, Primrose. Lockheed; Joseph S. Sutter, Boeing. Application Satellites David S. Lasers Carroll O. Alley, University of Johnson, National Research Council; John L. Maryland; Ellet H. Drake, American Society McLucas, QuesTech; Robert M. White, NAE. for Laser Medicine and Surgery; David R. Hertling, Georgia Institute of Technology; Microprocessor David R. Hertling, Richard Q. Hofacker, Jr., AT&T Bell Labora- Georgia Institute of Technology; Howard tories; Thomas R. Lettieri, National Institute High, Intel; Robert E. Kahn, Corporation of Standards and Technology; C. Kumar N. for National Research Initiatives; John M. Patel, AT&T Bell Laboratories; Charles T. Richardson, National Research Council; Troy, Photonics Spectra. Jacob T. Schwartz, Defense Advanced Research Projects Agency. Fiber-Optic Communication David R. Hertling, Georgia Institute of Technology; Computer-Aided Design and Richard Q. Hofacker, Jr., AT&T Bell Labora- Manufacturing Michael J. Cronin, tories. Automatix; Gerald P. Dinneen, NAE; Charles W. Hoover, Jr., Polytechnic University; E. Jan Genetically Engineered Products Hurst, Computer Graphics Historical Project; John E. Burris, National Research Council; Richard H. F. Jackson, National Institute of David W. Dennen, Eli Lilly; Barbara Filner, Standards and Technology; Richard L. Kegg, Howard Hughes Medical Institute; Clifford J. Cincinnati Milacron; Carl Machover, Nation- Gabriel, National Research Council; Alan R. al Computer Graphics Association; Joel Goldhammer, Industrial Biotechnology Moses, Massachusetts Institute of Technolo- Association; Leroy Hood, California Institute gy; Fontaine K. Richardson, Eastech Manage- of Technology; Robert Jones, Applied ment. Biosystems; James E. Tavares, National Research Council. CAT Scan Stanley Baum, University of Pennsylvania; B. J. Bowen, General Electric Medical Systems. 48 ENGINEERING AND THE ADVANCEMENT OF HUMAN WELFARE National Academy of Engineering Council Frederic A. L. Holloway H. Norman Abramson Edward G. Jefferson Lew Allen, Jr. William S. Lee Holt Ashley William E. Leonhard George Bugliarello Harold Liebowitz Gerald P. Dinneen (Foreign Secretary) Peter W. Likins Thomas E. Everhart Clarence H. Linder Alexander H. Flax (Home Secretary) John L. McLucas Ralph E. Gomory Ruben F. Mettler Mary L. Good Richard M. Morrow Paul E. Gray Bruce S. Old George N. Hatsopoulos Courtland D. Perkins Edward R. Kane (Treasurer) William H. Pickering Ralph Landau (Vice President) Cornelius J. Pings John L. McLucas Allen E. Puckett Herbert H. Richardson Simon Ramo Morris Tanenbaum Arthur E. Raymond John F. Welch, Jr. (Chairman) Ian M. Ross Robert M. White (President) Robert C. Seamans, Jr. Chauncey Starr Advisory Committee on the H. Guyford Stever 25th Anniversary Celebration Julius A. Stratton Stephen D.Bechtel, Jr. (Chairman) C. Guy Suits John A. Armstrong Richard F. Tucker Harold Brown Eric A. Walker Walker L. Cisler Ernst Weber Floyd L. Culler Albert R.C. Westwood W. Kenneth Davis F. Karl Willenbrock Thomas E. Everhart Thornton A. Wilson N. Bruce Hannay PHOTO CREDITS Cover Column 1, top to bottom: courtesy of NASA (photos 1 and 2); courtesy of Intel Corporation; courtesy of McDonnell Douglas Systems Integration Company, Manufacturing and Engineering Systems; © Howard Sochurek. Column 2, top to bottom: courtesy of E.I. du Pont de Nemours & Co. (Inc.); William Kennedy, The Image Bank; © Robert Rathe, FOLIO; courtesy of AT&T; courtesy of Eli Lilly and Company. Moon Landing Courtesy of NASA (all), 4,5, 6, 7, 8,9. Application Satellites NOAA, 10; courtesy of NASA, 11(left, right); © Greg Pease, FOLIO, 12; Reproduced by permission of Earth Observation Satellite Company, Lanham, Maryland, USA, 13(top); courtesy of Rockwell International Corporation, 13(bottom). Microprocessor Courtesy of Intel Corporation, 14, 17; © John Maher, UNIPHOTO, 15; courtesy of Apple Computer, Inc., 16(left); courtesy of Boeing Commercial Airplanes, 16(right). Computer-Aided Design and Manufacturing Courtesy of Cincinnati Milacron, 18; courtesy of McDonnell Douglas Systems Integration Company, Manufacturing & Engineering Systems, 19; courtesy of Mentor Graphics Corporation, 20(top); courtesy of Hewlett-Packard Company, 20(bottom); courtesy of Aries Technology, Inc., 21(top, center, bottom). CAT Scan © Howard Sochurek, 22(left), 23, 24; Matthew Borkoski, FOLIO, 22(right); © Charles Gupton, UNIPHOTO, 25. Advanced Composite Materials Courtesy of DAW Industries, Inc., 26; courtesy of Beech Aircraft Corporation, 27; courtesy of E.I. du Pont de Nemours & Co. (Inc.), 28; courtesy of Kennametal Inc., 29(top); courtesy of Wright-Patterson Air Force Base, Aeronautical Systems Division, 29(bottom). Jumbo Jets Courtesy of United Airlines, 30; William Kennedy, The Image Bank, 31; courtesy of Pratt & Whitney, 32(top left, center right); © Rene Sheret, FOLIO, 32(bottom left); courtesy of Lockheed Aeronautical Systems Company, 33. Lasers Courtesy of Coherent Incorporated, Palo Alto, California, 34; courtesy of AT&T, 35(top); © Robert Rathe, FOLIO, 35(bottom); courtesy of Dr. Carmen A. Puliafito and the Archives of Opthalmology, © 1987 American Medical Association, 36(top, center, bottom); courtesy of the University of Maryland-NASA, 37(left); J.R. Eyerman, 37(right). Fiber-Optic Communication Courtesy of AT&T, 38, 39, 40(top, bottom), 41(top right); courtesy of Candela Laser Corporation, 41(bottom left). Genetically Engineered Products Courtesy of Eli Lilly and Company, 42, 44(top); courtesy of Molecular Science Research Center at Battelle's Pacific Northwest Division, 43; courtesy of Beckman Instruments, Inc., 44(top); Ted Spiegel, BLACKSTAR, 45. National Academy of Engineering NON-PROFIT ORG. U.S. POSTAGE 2101 Constitution Avenue, N.W. PAID Washington, D.C. 20418 WASHINGTON, D.C. PERMIT 7750