We analyze the dispersion-managed optical transmission system for the non-return-to-zero (NRZ) pulse format. First, we investigate the physical image of dispersion management by computing small-signal-based transfer functions, and summarize the dependence of transmission performance on system parameters. Next, the Q-map is computed numerically to design long-distance large-capacity dispersion-managed transmission systems for a single channel in a more detailed manner. It is shown that the third-order dispersion of fibers negatively influences transmission performance, and third-order dispersion compensation is proved to be an effective method for extending the transmission distance of high bit-rate systems. Utilizing these results, guidelines can be derived for the optimal design of long-distance large-capacity NRZ transmission systems.
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Xiaomin WANG, Kazuro KIKUCHI, Yuichi TAKUSHIMA, "Analysis of Dispersion-Managed Optical Fiber Transmission System Using Non-Return-to-Zero Pulse Format and Performance Restriction from Third-Order Dispersion" in IEICE TRANSACTIONS on Electronics,
vol. E82-C, no. 8, pp. 1407-1413, August 1999, doi: .
Abstract: We analyze the dispersion-managed optical transmission system for the non-return-to-zero (NRZ) pulse format. First, we investigate the physical image of dispersion management by computing small-signal-based transfer functions, and summarize the dependence of transmission performance on system parameters. Next, the Q-map is computed numerically to design long-distance large-capacity dispersion-managed transmission systems for a single channel in a more detailed manner. It is shown that the third-order dispersion of fibers negatively influences transmission performance, and third-order dispersion compensation is proved to be an effective method for extending the transmission distance of high bit-rate systems. Utilizing these results, guidelines can be derived for the optimal design of long-distance large-capacity NRZ transmission systems.
URL: https://global.ieice.org/en_transactions/electronics/10.1587/e82-c_8_1407/_p
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@ARTICLE{e82-c_8_1407,
author={Xiaomin WANG, Kazuro KIKUCHI, Yuichi TAKUSHIMA, },
journal={IEICE TRANSACTIONS on Electronics},
title={Analysis of Dispersion-Managed Optical Fiber Transmission System Using Non-Return-to-Zero Pulse Format and Performance Restriction from Third-Order Dispersion},
year={1999},
volume={E82-C},
number={8},
pages={1407-1413},
abstract={We analyze the dispersion-managed optical transmission system for the non-return-to-zero (NRZ) pulse format. First, we investigate the physical image of dispersion management by computing small-signal-based transfer functions, and summarize the dependence of transmission performance on system parameters. Next, the Q-map is computed numerically to design long-distance large-capacity dispersion-managed transmission systems for a single channel in a more detailed manner. It is shown that the third-order dispersion of fibers negatively influences transmission performance, and third-order dispersion compensation is proved to be an effective method for extending the transmission distance of high bit-rate systems. Utilizing these results, guidelines can be derived for the optimal design of long-distance large-capacity NRZ transmission systems.},
keywords={},
doi={},
ISSN={},
month={August},}
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TY - JOUR
TI - Analysis of Dispersion-Managed Optical Fiber Transmission System Using Non-Return-to-Zero Pulse Format and Performance Restriction from Third-Order Dispersion
T2 - IEICE TRANSACTIONS on Electronics
SP - 1407
EP - 1413
AU - Xiaomin WANG
AU - Kazuro KIKUCHI
AU - Yuichi TAKUSHIMA
PY - 1999
DO -
JO - IEICE TRANSACTIONS on Electronics
SN -
VL - E82-C
IS - 8
JA - IEICE TRANSACTIONS on Electronics
Y1 - August 1999
AB - We analyze the dispersion-managed optical transmission system for the non-return-to-zero (NRZ) pulse format. First, we investigate the physical image of dispersion management by computing small-signal-based transfer functions, and summarize the dependence of transmission performance on system parameters. Next, the Q-map is computed numerically to design long-distance large-capacity dispersion-managed transmission systems for a single channel in a more detailed manner. It is shown that the third-order dispersion of fibers negatively influences transmission performance, and third-order dispersion compensation is proved to be an effective method for extending the transmission distance of high bit-rate systems. Utilizing these results, guidelines can be derived for the optimal design of long-distance large-capacity NRZ transmission systems.
ER -