Dual 1310–1550-nm window ultra low error rate operation of 2.5 Gbit/s SONET transmission systems

H. Izadpanah; A. Elrefaie; J. L. Gimlett; Chinlon Lin; B. Wedding; B. Wedding; D. Schlump; D. Schlump; R. Heidemann; R. Heidemann

doi:10.1364/OFC.1992.ThD6

Digest of Conference on Optical Fiber Communication
1992 OSA Technical Digest Series (Optica Publishing Group, 1992),
paper ThD6
•https://doi.org/10.1364/OFC.1992.ThD6

Dual 1310–1550-nm window ultra low error rate operation of 2.5 Gbit/s SONET transmission systems

H. Izadpanah, A. Elrefaie, J. L. Gimlett, Chinlon Lin, B. Wedding, D. Schlump, and R. Heidemann

Optical Fiber Communication Conference 1992

San Jose, California United States
ISBN: 1-55752-222-7

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System Components and Demonstrations (ThD)

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H. Izadpanah, A. Elrefaie, J. L. Gimlett, C. Lin, B. Wedding, D. Schlump, and R. Heidemann, "Dual 1310–1550-nm window ultra low error rate operation of 2.5 Gbit/s SONET transmission systems," in Digest of Conference on Optical Fiber Communication, Vol. 5 of 1992 OSA Technical Digest Series (Optica Publishing Group, 1992), paper ThD6.

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Abstract

High-speed transmission systems using directly modulated DFB semiconductor lasers over single-mode fibers are limited by the combined effects of laser chirp and chromatic dispersion.^1,2 The penalty can be severe when a 1550-nm source is used for transmission over conventional of 1310-nm zero dispersion single-mode fiber (SMF). Previously,³ we have demonstrated dispersionless transmission of gain switched chirped laser pulses at 1310 nm in a dispersion shifted single-mode fiber (DS-SMF) by pulse compression. In this chirped pulse transmission scheme originally proposed in 1984,¹ the negative dispersion of the fiber in the system operating wavelength region is used to compensate for the red-shift chirp during the pulse, resulting in pulse compression and subsequent rebroadening in the fiber.

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