Design and Simulation of Physical Layer Security for Next Generation Intelligent Optical Networks

Wirel. Pers. Commun. Pub Date : 2021-06-03 DOI:10.21203/RS.3.RS-455158/V1

Valarmathi Marudhai, S. Prince, Shayna Kumari

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Abstract

With the latest technological advancements and attractive features of next generation intelligent optical networks such as high bandwidth, low power consumption, and low transmission loss, etc., they have been considered as most viable solution to satisfy promptly growing bandwidth demands. However, main optical network components bring forth a set of security challenges and reliability issues, accompanied by new vulnerabilities within the network. This paper proposes a new design for an optical encryption and decryption method for enhancing optical network security using p-i-n photodiode which generates Pseudo Random Binary Sequence (PRBS) as a shot noise fluctuations and wavelength converter based design using Semiconductor Optical Amplifier (SOA) based XOR gate which utilizes Cross-Phase Modulation (XPM). The system performance based on Bit Error Rate (BER) and Q factor are analyzed at different data rates for different link lengths up to 100 km using OptiSystem. It is observed that error free transmission with a BER of 10-12 is achieved a data rate of 10Gbps for a link length of only 30 Km for the system with PIN photodiode’s shot noise being used for PRBS sequence generation. However, wavelength conversion based system enables transmission of signal at 10Gbps signal up to a link length of 90Km.

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下一代智能光网络物理层安全设计与仿真

随着新一代智能光网络的最新技术进步和高带宽、低功耗、低传输损耗等吸引人的特点，它们已被认为是满足快速增长的带宽需求的最可行的解决方案。但是，光网络主要组件带来了一系列的安全挑战和可靠性问题，同时也带来了网络内部新的漏洞。本文提出了一种利用p-i-n光电二极管产生伪随机二值序列(PRBS)作为脉冲噪声波动来提高光网络安全性的光加密和解密方法，以及基于半导体光放大器(SOA)的交叉相位调制(XPM)的异或门的波长变换器设计。基于误码率(BER)和Q因子的系统性能分析在不同的数据速率下，不同的链路长度100公里使用OptiSystem。我们观察到，使用PIN光电二极管的散粒噪声生成PRBS序列的系统，在链路长度仅为30 Km的情况下，实现了误码率为10-12的无差错传输，数据速率为10Gbps。然而，基于波长转换的系统能够以10Gbps的信号传输信号，链路长度可达90Km。

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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Wirel. Pers. Commun.

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