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Science 14 August 1998:
Vol. 281. no. 5379, pp. 962 - 967
DOI: 10.1126/science.281.5379.962
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Review

Effects of Random Perturbations in Plastic Optical Fibers

A. F. Garito, J. Wang, R. Gao

REVIEW

The most important feature of an optical fiber waveguide is its bandwidth, which defines its information-carrying capacity. A major limitation on the bandwidth of multimode glass and plastic optical fibers is modal dispersion, in which different optical modes propagate at different velocities and the dispersion grows linearly with length. However, in plastic optical fibers, experimental and theoretical results indicate that the modes are not independent but are highly coupled, which leads to a characteristic square-root length dependence and an unanticipated large enhancement of the bandwidth to gigahertz levels. The ever increasing demands for low-cost, high-bandwidth communications media for voice, video, and data transmission in short- and medium-distance applications are generating a new assessment of multimode optical fibers to serve as high-speed fiber links.

The authors are in the Department of Physics and Astronomy, University of Pennsylvania, Philadelphia, PA 19104, USA.

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THIS ARTICLE HAS BEEN CITED BY OTHER ARTICLES:
A continuous model for mode mixing in graded-index multimode fibres with random imperfections.
E. Perrey-Debain, I. D. Abrahams, and J. D Love (2008)
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Dispersive Multiplexing in Multimode Optical Fiber.
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