In less than 20 years, the transmission of information by optical fibers has advanced from a mere theoretical proposal to a pervasive commercial reality. The rapid progress that has led to important applications (figure 1) has been marked by innovative breakthroughs as well as steady advances in all areas of lightwave technology. The demonstration of the laser in 1960 sparked intense interest in light as a medium for transmitting information. At that time, scientists began extensive research on optical devices, techniques and subsystems for processing signals, and on a variety of transmission media such as line‐of‐sight atmospheric paths and beam waveguides with periodic focusing elements. During the early 1960s, work on optical fibers as waveguides was mainly theoretical, as the available glass fibers exhibited transmission losses around 1000 decibels per kilometer—about two orders of magnitude too large for use in telecommunications.

Topics
Acoustic noise measurement, Composite materials, Optical devices, Optical fibers, Educational aids, Telecommunications
1.
For a general review, see
T.
Li
,
IEEE J. Sel. Areas Comm.
SAC‐1
,
356
(
1983
).
Google Scholar
 
2.
S. E.
Miller
,
Science
170
,
685
(
1970
).
Google Scholar
Crossref
Search ADS
PubMed
 
3.
T. Li, ed., Optical Fiber Communications, Vol. 1, Fiber Fabrication, Academic, New York (1985).
4.
D.
Marcuse
,
C.
Lin
,
IEEE J. Quantum Electron.
QE‐17
,
869
(
1981
).
Google Scholar
 
5.
T. D. Croft, J. E. Ritter, H. Bhagavatula, in Tech. Digest Conf. Optical Fiber Comm., OSA, Washington, D.C. (1985), paper WD2.
6.
A. Suzuki, K. Minemura, H. Nomura, in Conf. Proc. (Post Deadline Papers) Tenth Europ. Conf. Optical Comm., VDE‐Verlag, Berlin (1984), paper PD5.
7.
P. W. Shumate, J. L. Gimlett, M. Stern, M. B. Romeiser, N. K. Cheung, in Tech. Digest (Post Deadline Papers), Conf. Optical Fiber Comm., OSA, Washington, D.C. (1985), paper PDO3.
8.
J. C. Campbell, A. G. Dentai, W. S. Holden, B. L. Kasper, in Tech. Digest Int. Elect. Dev. Meeting, IEEE, New York (1983), paper 18.2.
9.
R. A. Linke, in. Tech. Digest Conf. Optical Fiber Comm., OSA, Washington, D.C. (1985), paper WB3.
10.
A. H. Gnauck, B. L. Kasper, R. A. Linke, R. W. Dawson, T. L. Koch, T. J. Bridges, E. G. Burkhardt, R. T. Yen, D. P. Wilt, J. C. Campbell, K. C. Nelson, L. G. Cohen, in Tech. Digest (Post Deadline Papers) Conf. Optical Fiber Comm., OSA, Washington, D.C. (1985), paper PD02;
S. L. Korotky, G. Eisenstein, A. H. Gnauck, B. L. Kasper, J. J. Veselka, R. C. Alferness, L. L. Buhl, C. A. Burrus, T. C. D. Huo, L. W. Stulz, K. C. Nelson, L. G. Cohen, R. W. Dawson, J. C. Campbell, paper PD01.
11.
T. G. Hodgkinson, D. W. Smith, R. Wyatt, D. J. Malyon, in Tech. Digest Conf. Optical Fiber Comm., OSA, Washington, D.C. (1985), paper MH1.
12.
M.
Shikada
,
K.
Emura
,
S.
Fujita
,
M.
Kitamura
,
M.
Arai
,
M.
Kondo
,
K.
Minemura
,
Electron. Lett.
20
,
164
(
1984
).
Google Scholar
Crossref
Search ADS
 
13.
R.
Wyatt
,
D. W.
Smith
,
T. G.
Hodgkinson
,
R. A.
Harmon
,
W. J.
Devlin
,
Electron. Lett.
20
,
912
(
1984
).
Google Scholar
Crossref
Search ADS
 
14.
See the special issue on undersea lightwave communications,
IEEE/OSA J. Lightwave Tech.
LT‐2
(December
1984
).
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1985
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