WAVELENGTH SELECTION FOR OPTICAL WIRELESS COMMUNICATIONS SYSTEMS

机译：光学无线通信系统的波长选择

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Eye safety, link performance, and technology infrastructure issues related to Optical Wireless (OW), also known as Free Space Optics (FSO), communication systems are examined relative to wavelength dependence. It is found that 1550 nm systems have compelling advantages over 800 nm systems in the areas of laser eye safety, reduced solar background radiation, and existing technology infrastructure. 1550 nm has somewhat better receiver sensitivity for PIN detectors, while 800 nm has somewhat better sensitivity for APDs. Overall, the factor of 50 greater eye-safe laser power at 1550 nm provides up to 17 dB additional margin for higher data rates or penetrating fog at longer ranges. The availability of high power, low cost semiconductor lasers at 1550 nm allows these advantages to be exploited in commercially available systems.

机译：与波长无线相关的眼科安全性，链路性能以及与光学无线（OW）（也称为自由空间光学（FSO））有关的通信系统的技术基础设施问题进行了检查。发现在激光眼安全，减少的太阳本底辐射和现有技术基础设施方面，1550 nm系统比800 nm系统具有明显优势。 1550 nm对于PIN检测器具有更好的接收灵敏度，而800 nm对APD则具有更好的灵敏度。总体而言，在1550 nm处，对眼睛安全的激光功率提高50倍，可为更高的数据速率或更长距离的穿透雾提供高达17 dB的额外余量。 1550 nm的高功率，低成本半导体激光器的可用性使这些优势可在商用系统中得到利用。

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来源
《Conference on Optical Wireless Communications Ⅳ Aug 21-22, 2001, Denver, USA》|2001年|p.27-35|共9页
会议地点 Denver CO(US)
作者
David A. Rockwell; G. Stephen Mecherle;
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作者单位

fSONA Communications 1600 Rosecrans Ave. Bldg. 6B Suite 200 Manhattan Beach, CA 90266;

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会议组织
原文格式 PDF
正文语种 eng
中图分类无线电电子学、电信技术;
关键词
laser communication; lasercom; free space optics; optical wireless; wavelength; 1550 nm; mie scattering; last mile bottleneck; optical access; metro access;

机译：激光通讯Lasercom;自由空间光学；光学无线；波长; 1550纳米;米氏散射最后一英里的瓶颈；光接入；地铁通道;

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机译：无线系统的深度学习框架：在光学无线通信中的应用
4. Wavelength selection for optical wireless communications systems [C] . David A. Rockwell, G. Stephen Mecherle Society of Photo-Optical Instrumentation Engineers Conference on Optical Wireless Communications . 2001

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5. All-optical wavelength conversion for optical communication systems. [D] . Chan, Lai Yin Simon. 1999

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6. Orthogonal Frequency Division Multiplexing Techniques Comparison for Underwater Optical Wireless Communication Systems [O] . Jie Lian, Yan Gao, Peng Wu, 2019

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7. Wavelength-Adaptation Underwater Optical Wireless Sensor Network Using Visible Light Communications [O] . Xin Lin 2020

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8. Wavelength Selection for Free Space Optical Communications [R] . Wilson, K. 1999

机译：自由空间光通信的波长选择

WAVELENGTH SELECTION FOR OPTICAL WIRELESS COMMUNICATIONS SYSTEMS

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