Abstract
Miniaturization has made it possible for electronics to penetrate society more widely and deeply than ever before. Pocket calculators, electronic watches, miniature colour television receivers and the like are only some of the examples of the miniaturization of electronics of which the general public first became aware. Even before they came along, miniaturized electronic systems had made a significant impact in military, industrial, and commercial areas. Miniaturization helped in the exploration of space, in communications, in the control of machinery and processes, and in the handling and processing of data. The miniaturization of electronics is sometimes regarded as a somewhat late development that derives from the integrated circuit; yet miniaturization on the grounds of size, weight, and power requirements was under way long before the integrated circuit was invented and even before the transistor became commercially available. Valve (vacuum-tube) manufacturers were remarkably successful in producing miniature and subminiature valves, some of them smaller than a present-day power transistor; and the screen printing of resistive and other passive components, and the concept of electronic modules, helped to bring about smaller electronic systems. Yet the big acceleration towards microelectronics did indeed begin with the invention of the integrated circuit, when at first small and later large circuits were formed on a single chip of silicon. The net result was systems far larger and far more complex than could even have been dreamed of before.
This is a preview of subscription content, log in via an institution to check access.
Preview
Unable to display preview. Download preview PDF.
References
J. M. Early, Proc. IRE 50: 1006–1010, 1962.
E. W. Herold, J. Franklin Inst. 259 (No. 2): 87–106, February 1955.
G. L. Pearson and W. H. Brattain, Proc. IRE 43: 1794–1806, 1955.
E. E. Loebner, IEEE Trans. ED-23: 675–699, 1976.
E. Braun and S. MacDonald, Revolution in Miniature, Cambridge University Press, London, 1978.
E. E. Loebner, Physics in Technology 5: 147–148, 1974.
C. Weiner, IEEE Spectrum 10 (No. 1): 24–33, January 1973.
R. L. Petritz, Proc. IRE 50: 1025–1038, 1962.
W. B. Harris, Fortune, 135–138, 286–290, May 1957.
P. C. Mabon, Mission Communications: The Story of Bell Laboratories, Bell Laboratories, New Jersey, 1975.
Special Report, ‘The transistor: Two decades of progress,’ Electronics 41: 19 February 1968.
C. Freeman, The Economics of Industrial Innovation, Penguin, London, 1974.
W. O. Swinyard, Proc. IRE 50: 793–798, 1962.
S. F. Danko, Proc. IRE 50: 937–945, 1962.
J. S. Kilby, IEEE Trans. ED-23: 648–654, 1976.
H. Johnson, U.S. Patent 2 816 228, 10 December 1957.
M. F. Wolff, IEEE Spectrum 13 (No. 8): 45–53, August 1976.
J. S. Kilby, U.S. Patent 3 138 743, 23 June 1964.
J. G. Linvill and C. L. Hogan, Science 195: 1107–1113, 1977.
W. B. Harris, Fortune, 136–143, 216–226, April 1957.
S. Ramo, Proc. IRE 50: 1237–1241, 1962.
Electronics 36: 67–72, 4 January 1963.
Electronics 35: 52, 5 January 1962.
D. Kahng, IEEE Trans. ED-23: 655–657, 1976.
J. M. Cohen, Electronics 41: 120–123; 19 February 1968.
J. Eimbinder, Electronics 37: 46–49, 30 November 1964.
G. W. Dummer, Proc. IEEE 52: 1412–1425, 1964.
Private communication, Nippon Electric Co. Ltd., 1979.
R. N. Noyce, Scientific American 237: 63–69, September 1977.
G. E. Moore, Inst. Physics, Conf. Series No. 40, Solid State Devices, 1–6, 1977.
Copyright information
© 1984 W. A. Atherton
About this chapter
Cite this chapter
Atherton, W.A. (1984). Miniaturization of Electronics. In: From Compass to Computer. Palgrave, London. https://doi.org/10.1007/978-1-349-17365-5_10
Download citation
DOI: https://doi.org/10.1007/978-1-349-17365-5_10
Publisher Name: Palgrave, London
Print ISBN: 978-0-333-35268-7
Online ISBN: 978-1-349-17365-5
eBook Packages: EngineeringEngineering (R0)