HOW DOES THRESHOLD DETECTION LIMIT ATMOSPHERIC-TURBULENCE IN NUMBER STATE OPTICAL CHANNELS

被引:1
作者
FARES, DA
机构
[1] Department of Circuits & Systems, Military Technical College (M.T.C.), Cairo
来源
MICROWAVE AND OPTICAL TECHNOLOGY LETTERS | 1994年 / 7卷 / 08期
关键词
ATMOSPHERIC TURBULENCE; TURBULENT OPTICAL COMMUNICATIONS; NUMBER STATE CHANNELS; THRESHOLD DETECTION; AND PULSE POSITION MODULATION;
D O I
10.1002/mop.4650070812
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
In this article, analysis for the recently considered photon number state optical channel [1-3] is presented. Under atmospheric turbulence conditions, the channel performance is highly affected and deteriorated. Therefore, coding-in particular Reed-Solomon block codes [4]-becomes a must. In this presentation, the optimal threshold performance conditions are calculated and are shown to prove their strong control on the channel turbulence, yielding reliable communication. Other channel measures such as channel transparency, information efficiency, and transmission rate are investigated. (C) 1994 John Wiley & Sons, Inc.
引用
收藏
页码:375 / 378
页数:4
相关论文
共 47 条
[31]   Capacity Analysis of Amplify-and-Forward Free-Space Optical Communication Systems Over Atmospheric Turbulence Channels [J].
Duong Huu Ai ;
Duong Tuan Quang ;
Nguyen Ngoc Nam ;
Ha Duyen Trung ;
Do Trong Tuan ;
Nguyen Xuan Dung .
2017 SEVENTH INTERNATIONAL CONFERENCE ON INFORMATION SCIENCE AND TECHNOLOGY (ICIST2017), 2017, :103-108
[32]   Twin-field quantum key distribution over free-space optical channels in the presence of atmospheric turbulence [J].
Huang, Yuqing ;
Sun, Zhongqi ;
Dou, Tianqi ;
Wang, Jipeng ;
Li, Zhenhua ;
Zhou, Fen ;
Han, Yanxin ;
Ma, Haiqiang .
MODERN PHYSICS LETTERS B, 2022, 36 (06)
[33]   A Cumulant-Based Adaptive Detection Technique for Optical Wireless Communication Over Strong Turbulence Channels [J].
Wang, Jin ;
Huang, Dexiu ;
Yuan, Xiuhua .
CHINA COMMUNICATIONS, 2008, 5 (01) :22-27
[34]   A Cumulant-Based Adaptive Detection Technique for Optical Wireless Communication Over Strong Turbulence Channels [J].
Jin Wang Dexiu Huang Xiuhua Yuan Wuhan National laboratory for optoelectronics Huazhong University of Science Technology Wuhan China .
中国通信, 2008, 5 (01) :22-27
[35]   Error performance analysis for FSO systems with diversity reception and optical preamplification over gamma-gamma atmospheric turbulence channels [J].
Zhao, Wenjuan ;
Han, Yiping ;
Yi, Xiang .
JOURNAL OF MODERN OPTICS, 2013, 60 (13) :1060-1068
[36]   Secured relay-assisted atmospheric optical code-division multiple-access systems over turbulence channels [J].
Pham, Hien T. T. ;
Trinh, Phuc V. ;
Dang, Ngoc T. ;
Pham, Anh T. .
IET OPTOELECTRONICS, 2015, 9 (05) :241-248
[37]   Performance of All-Optical Amplify-and-Forward WDM/FSO Relaying Systems over Atmospheric Dispersive Turbulence Channels [J].
Trinh, Phuc V. ;
Dang, Ngoc T. ;
Thang, Truong C. ;
Pham, Anh T. .
IEICE TRANSACTIONS ON COMMUNICATIONS, 2016, E99B (06) :1255-1264
[38]   Performance analysis of 1-km free-space optical communication system over real atmospheric turbulence channels [J].
Liu, Dachang ;
Wang, Zixiong ;
Liu, Jianguo ;
Tan, Jun ;
Yu, Lijuan ;
Mei, Haiping ;
Zhou, Yusong ;
Zhu, Ninghua .
OPTICAL ENGINEERING, 2017, 56 (10)
[39]   Mode-dependent crosstalk and detection probability of orbital angular momentum of optical vortex beam through atmospheric turbulence [J].
Zhang, Lihong ;
Shen, Feng ;
Lan, Bin ;
Tang, Ao .
JOURNAL OF OPTICS, 2020, 22 (07)
[40]   Bit Error Rate Performance for Modulating Retro-Reflector Free Space Optical Communication System Based on Adaptive Threshold under Atmospheric Turbulence [J].
Li Xiaoyan ;
Zhang Peng ;
Tong Shoufeng .
CHINESE JOURNAL OF LASERS-ZHONGGUO JIGUANG, 2018, 45 (06)
12345