A simple treatment for different dispersive pulse-broadening mechanisms in optical fibers is given. The modal dispersion coefficients for a high-OH multimode step-index optical fiber were measured at the wavelengths 532, 355, and 266 nm with the use of a pulsed Nd:YAG laser. An empirical relationship expressing the modal dispersion coefficients as a function of wavelength for the range 532 to 266 nm was calculated.
CherinA. H., An Introduction to Optical Fibers (McGraw-Hill, New York, 1983).
7.
FOTP-51 Pulse Distortion Measurement of Multimode Glass Optical Fiber Information Transmission Capacity, EIA Standard EIA/ TIA-455-51A (Electronic Industries Association, Washington D.C., 1991).
8.
WhitehurstC.DickinsonM.KingT., J. Mod. Opt.35, 371 (1988).
9.
RainerF.DeatonT., Appl. Opt.21, 1722 (1982).
10.
AlaruriS.McFarlandD.BrewingtonA.ThomasM.SalleeN., “Development of a Fiber Optic Probe for Thermographic Phosphor Measurements in Turbine Engines,”Submitted for publication in the proceedings of the 30th AIAA Joint Propulsion Conference.
11.
WolframS., Mathematica, Version 2.2 (Wolfram Research, Champaign, Illinois, 1993).
MarcuseD., Principles of Optical Fiber Measurements (Academic Press, New York, 1981).
14.
FOTP-169 Chromatic Dispersion Measurement of Optical Fibers by the Phase-Shift Method, EIA Standard EIA-455-169 (Electronic Industries Association, Washington D.C., 1988.).
15.
FOTP-168 Chromatic Dispersion Measurement of Multimode Graded-Index and Single-Mode Optical Fibers by Spectral Group Delay Measurement in the Time Domain, EIA Standard EIA-455168 (Electronic Industries Association, Washington D.C., 1987.).
