Minimization of dispersion and non-linear effects in WDM based long-haul high capacity optical communication systems

Zahid Zaman, Yousaf Khan, Ammar Muhammad Khan
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Abstract

Chromatic dispersion and nonlinear impairments pose challenges in high-capacity optical transmission systems, leading to signal distortions, channel interference and diminished the transmission performances. This paper explores the utilization of dispersion compensating fibers (DCF) using different schemes to mitigate the dispersion that accumulates along the length of a fiber in a 16 × 10 Gbps high-capacity long haul WDM system over a range of 500 km. When different wavelengths of light pulses are transmitted through an optical fiber, they experience varying speeds due to the refractive index’s wavelength dependency. As a result, the light pulses become temporally spread out as they travel through the fiber, and this dispersion persists throughout the fiber’s length. Considering non-linear effects such as self-phase modulation (SPM) and cross-phase modulation (XPM), this paper analyze and compare the three compensation schemes of DCF in a 16 channel WDM system. Moreover the impact of non-linearities based on fiber length are also analyzed and compared. The results are evaluated by comparing metrics such as Q-factor, bit error rate (BER) and eye height. The analysis concludes that the symmetrical compensation scheme of DCF outperforms the pre- and post-compensation scheme. This finding suggests that the symmetrical compensation method offers a promising solution for high-capacity access networks, providing high spectral efficiency, cost-effectiveness, and improved flexibility.
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基于波分复用技术的长途大容量光通信系统中色散和非线性效应的最小化
色散和非线性损伤给大容量光传输系统带来了挑战,导致信号失真、信道干扰和传输性能下降。本文探讨了如何利用色散补偿光纤(DCF),采用不同的方案来减轻光纤长度上累积的色散,该光纤用于 16 × 10 Gbps 大容量长距离波分复用系统,传输距离为 500 千米。当不同波长的光脉冲通过光纤传输时,由于折射率与波长有关,它们的速度会发生变化。因此,光脉冲在光纤中传输时会在时间上发生分散,这种分散现象会持续整个光纤长度。考虑到自相位调制(SPM)和跨相位调制(XPM)等非线性效应,本文分析并比较了 16 信道波分复用系统中 DCF 的三种补偿方案。此外,还分析和比较了基于光纤长度的非线性影响。结果通过比较 Q 因子、误码率 (BER) 和眼高等指标进行评估。分析得出的结论是,DCF 的对称补偿方案优于前后补偿方案。这一结果表明,对称补偿方法为大容量接入网络提供了一种前景广阔的解决方案,具有频谱效率高、成本效益高和灵活性强等优点。
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