Nonlinear Equalizer Based on Absolute Operation for IM/DD System Using DML

Yukui Yu; Myeong Ryeol Choi; Tianwai Bo; Yi Che; Daeho Kim; Hoon Kim

doi:10.1109/LPT.2020.2978222

Nonlinear Equalizer Based on Absolute Operation for IM/DD System Using DML

Yukui Yu, Myeong Ryeol Choi, Tianwai Bo, Yi Che, Daeho Kim, Hoon Kim^*

^*Corresponding author for this work

Korea Advanced Institute of Science and Technology

Research output: Contribution to journal › Article › peer-review

31 Citations (Scopus)

Abstract

The performance of high-speed intensity-modulation (IM)/direct-detection (DD) system implemented by using O-band directly modulated laser (DML) could be limited by the waveform distortions induced by nonlinear modulation dynamics of DML. The conventional polynomial nonlinear equalizer (PNLE) can be used at the receiver to compensate for such waveform distortions. However, this nonlinear equalizer suffers from high implementation complexity. In this letter, we propose nonlinear equalizers based on the absolute operation for IM/DD system using DML. We replace the square operation in PNLE with the absolute operation to lower the implementation complexity. The effectiveness of the proposed equalizers is evaluated over 100-Gb/s 4-ary pulse amplitude modulation transmission system implemented by using 1.31- μ m DMLs. The results show that the proposed equalizers perform similar to the PNLEs, but lower the implementation complexity.

Original language	English
Article number	9024123
Pages (from-to)	426-429
Number of pages	4
Journal	IEEE Photonics Technology Letters
Volume	32
Issue number	7
DOIs	https://doi.org/10.1109/LPT.2020.2978222
Publication status	Published - 1 Apr 2020
Externally published	Yes

Keywords

Nonlinear equalization
direct detection
intensity modulation
optical communication

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10.1109/LPT.2020.2978222

Cite this

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title = "Nonlinear Equalizer Based on Absolute Operation for IM/DD System Using DML",

abstract = "The performance of high-speed intensity-modulation (IM)/direct-detection (DD) system implemented by using O-band directly modulated laser (DML) could be limited by the waveform distortions induced by nonlinear modulation dynamics of DML. The conventional polynomial nonlinear equalizer (PNLE) can be used at the receiver to compensate for such waveform distortions. However, this nonlinear equalizer suffers from high implementation complexity. In this letter, we propose nonlinear equalizers based on the absolute operation for IM/DD system using DML. We replace the square operation in PNLE with the absolute operation to lower the implementation complexity. The effectiveness of the proposed equalizers is evaluated over 100-Gb/s 4-ary pulse amplitude modulation transmission system implemented by using 1.31- μ m DMLs. The results show that the proposed equalizers perform similar to the PNLEs, but lower the implementation complexity.",

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author = "Yukui Yu and Choi, {Myeong Ryeol} and Tianwai Bo and Yi Che and Daeho Kim and Hoon Kim",

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AU - Yu, Yukui

AU - Choi, Myeong Ryeol

AU - Bo, Tianwai

AU - Che, Yi

AU - Kim, Daeho

AU - Kim, Hoon

PY - 2020/4/1

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N2 - The performance of high-speed intensity-modulation (IM)/direct-detection (DD) system implemented by using O-band directly modulated laser (DML) could be limited by the waveform distortions induced by nonlinear modulation dynamics of DML. The conventional polynomial nonlinear equalizer (PNLE) can be used at the receiver to compensate for such waveform distortions. However, this nonlinear equalizer suffers from high implementation complexity. In this letter, we propose nonlinear equalizers based on the absolute operation for IM/DD system using DML. We replace the square operation in PNLE with the absolute operation to lower the implementation complexity. The effectiveness of the proposed equalizers is evaluated over 100-Gb/s 4-ary pulse amplitude modulation transmission system implemented by using 1.31- μ m DMLs. The results show that the proposed equalizers perform similar to the PNLEs, but lower the implementation complexity.

AB - The performance of high-speed intensity-modulation (IM)/direct-detection (DD) system implemented by using O-band directly modulated laser (DML) could be limited by the waveform distortions induced by nonlinear modulation dynamics of DML. The conventional polynomial nonlinear equalizer (PNLE) can be used at the receiver to compensate for such waveform distortions. However, this nonlinear equalizer suffers from high implementation complexity. In this letter, we propose nonlinear equalizers based on the absolute operation for IM/DD system using DML. We replace the square operation in PNLE with the absolute operation to lower the implementation complexity. The effectiveness of the proposed equalizers is evaluated over 100-Gb/s 4-ary pulse amplitude modulation transmission system implemented by using 1.31- μ m DMLs. The results show that the proposed equalizers perform similar to the PNLEs, but lower the implementation complexity.

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Nonlinear Equalizer Based on Absolute Operation for IM/DD System Using DML

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Keywords

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