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IEEE Journal of Lightwave Technology
Volume 18 Number 5, May 2000

Table of Contents for this issue

Complete paper in PDF format

Combining Self-Phase Modulation and Optimum Modulation Conditions to Improve the Performance of 10-Gb/s Transmission Systems Using MQW Mach-Zehnder Modulators

J. C. Cartledge Senior Member, IEEE, Member, OSA

Page 647.

Abstract:

For 10-Gb/s transmission over nondispersion shifted fiber, the combined use of self-phase modulation (SPM) and joint optimization of the bias and modulation voltages to increase the dispersion limited transmission distance is considered for multiple quantum well Mach-Zehnder modulators. For the dual drive (push-pull) modulation format, the dependence of the receiver sensitivity on fiber length and average transmitted optical power is determined for both conventional and phase-shift modulators with either symmetric or asymmetric Y-branch waveguides. When SPM is negligible and the optical extinction ratio is maximized, the modulator design must be considered carefully in order to increase the transmission distance. By combining SPM and optimum modulation conditions, the dependence of the system performance on the modulator design is reduced substantially. For an average transmitted optical power of 12.5 dBm, the receiver sensitivity for transmission over 140 km of fiber varies by only 0.3 dB for the different modulator designs. This compares with a variation of 3.1 dB for maximum extinction ratio modulation.

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