Performance parameters estimation of high speed Silicon/Germanium/InGaAsP avalanche photodiodes wide bandwidth capability in ultra high speed optical communication system

Q3 Engineering

Journal of Optical Communications Pub Date : 2024-06-11 DOI:10.1515/joc-2024-0099

Anitha Gopalan, Arumugam Krishnan Arulmozhi, Manimaraboopathy Maruthu Pandian, Priscilla Mohanadoss, Nithya Dorairajan, M. Balaji, Aziz Mahoumd Taher

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Abstract

Abstract This paper has clarified the performance parameters estimation of high speed silicon/germanium/InGaAsP avalanche photodiodes wide bandwidth capability in ultrahigh speed optical communication system. The basic structure configuration of avalanche photodiode is clarified. The basic depletion region configuration schematic view is demonstrated. As well as the maximum electric field is indicated for impact ionization through avalanche photodiode in the presence of load. Various avalanche photo-detectors multiplication factor is clarified versus reverse bias voltage at room temperature. Different avalanche photo-detectors dark current is measured against avalanche photo-detectors volume at room temperature. Various avalanche photo-detectors effective doping concentration is demonstrated against ambient temperature variations. Si/Ge/InGaAsP avalanche photo-detectors excess noise factor is demonstrated versus the ionization ratio at room temperature (T = 300 K) and different ambient temperature (T = 350 K and T = 400 K). Various avalanche photo-detectors excess noise factor is measured clearly versus the multiplication factor at room temperature. Si/Ge/InGaAsP avalanche photo-detectors excess noise factor is demonstrated versus reverse bias voltage at room temperature. Si/Ge/InGaAsP avalanche photo-detectors noise equivalent power is clarified versus multiplication factor at room temperature. Various avalanche photo-detectors noise equivalent power is studied versus temperature variations. Si/Ge/InGaAsP avalanche photo-detectors sensitivity is measured in relation to the temperature variations. Different avalanche photo-detectors sensitivity is demonstrated in relation to reverse bias voltage variations at room temperature.

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超高速光通信系统中高速硅/锗/砷化镓雪崩光电二极管宽带能力的性能参数评估

摘要本文阐明了超高速光通信系统中高速硅/锗/砷化镓雪崩光电二极管宽带能力的性能参数估算。阐明了雪崩光电二极管的基本结构构造。演示了基本耗尽区配置示意图。此外，还指出了在负载存在的情况下，通过雪崩光电二极管进行冲击电离的最大电场。阐明了室温下各种雪崩光电二极管的倍增因子与反向偏置电压的关系。在室温下测量不同雪崩光电二极管的暗电流与雪崩光电二极管体积的关系。各种雪崩光电探测器的有效掺杂浓度随环境温度变化而变化。在室温（T = 300 K）和不同环境温度（T = 350 K 和 T = 400 K）下，硅/Ge/InGaAsP 雪崩光电探测器的过量噪声系数与电离率的关系得到了证实。在室温下，各种雪崩光电探测器的过量噪声因数与倍增因数的关系被清晰地测量出来。在室温下，硅/Ge/InGaAsP 雪崩光电探测器的过量噪声系数与反向偏置电压的关系得到了证实。在室温下，Si/Ge/InGaAsP 雪崩光电探测器的噪声等效功率与倍增因子的关系清晰明了。研究了各种雪崩光电探测器的噪声等效功率与温度变化的关系。测量了硅/Ge/InGaAsP 雪崩光电探测器的灵敏度与温度变化的关系。在室温下，不同雪崩光电探测器的灵敏度与反向偏置电压的变化有关。

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来源期刊

Journal of Optical Communications Engineering-Electrical and Electronic Engineering

CiteScore

2.90

自引率

0.00%

发文量

期刊介绍： This is the journal for all scientists working in optical communications. Journal of Optical Communications was the first international publication covering all fields of optical communications with guided waves. It is the aim of the journal to serve all scientists engaged in optical communications as a comprehensive journal tailored to their needs and as a forum for their publications. The journal focuses on the main fields in optical communications