Digital backpropagation based on binary logarithmic step size distribution for fibre non‐linearity compensation

The Journal of Engineering Pub Date : 2023-12-01 DOI:10.1049/tje2.12340

Albert Dede, E. Akowuah, S. Haxha

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Abstract

Capacity crunch has become critical in recent years as commercial communication systems approach their theoretical data rate limits. This work presents a low‐complexity digital backpropagation (DBP) implementation approach based on step size distribution that uses a binary logarithmic step size method to achieve high data rate optical transmission. The proposed scheme shows performance improvements (∆Q) of 2.36, 1.19, and 0.71 dB over linear compensation, constant step size (CSS) DBP, and logarithmic step size DBP techniques in a 2400 km 112 Gbit/s DP‐16 quadrature amplitude modulation (QAM) system, respectively. At 13 dBm, a high performance (Q) of 10.9 dB (BER = 2.25 × 10−4) is achieved, above the 3.80 × 10−3 hard‐decision forward error correction (HD‐FEC) limit, using the proposed scheme. Also, the allowable transmission distance is extended by 960 km at the HD‐FEC limit over the linear compensation technique. The optimization achieves a 38% saving in the number of DBP calculation steps compared to the CSS DBP, which considerably reduces the computational cost since a few steps are required for effective non‐linearity compensation.

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基于二进制对数步长分布的数字反向传播，用于光纤非线性补偿

近年来，随着商业通信系统接近其理论数据传输速率的极限，容量紧缩已变得至关重要。本研究提出了一种基于步长分布的低复杂度数字反向传播（DBP）实现方法，该方法采用二进制对数步长法实现高数据速率光传输。在 2400 公里 112 Gbit/s DP-16 正交幅度调制 (QAM) 系统中，与线性补偿、恒定步长 (CSS) DBP 和对数步长 DBP 技术相比，所提方案的性能（ΔQ）分别提高了 2.36、1.19 和 0.71 dB。在 13 dBm 的条件下，使用所提出的方案可实现 10.9 dB 的高性能 (Q)（误码率 = 2.25 × 10-4），高于 3.80 × 10-3 的硬判定前向纠错 (HD-FEC) 限制。此外，与线性补偿技术相比，HD-FEC 限制下的允许传输距离延长了 960 千米。与 CSS DBP 相比，该优化方案节省了 38% 的 DBP 计算步骤，大大降低了计算成本，因为只需几个步骤就能实现有效的非线性补偿。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Journal of Engineering

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