Opto-Electronic Engineering
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Special Issue:optical wireless communication
Invited expert: Professor Ke Xizheng (Xi'an University of Technology), Professor Wang Tianshu (Changchun University of Science and Technology), Professor Wang Huiqin (Wang Huiqin)

With the emergence and rapid development of internet of things, big data and artificial intelligence, human society is going to enter the age of intelligence. In the age of intelligence, the volume of subscriber digital terminal and a variety of business data will increase rapidly, which puts forward new requirements on the capacity, velocity and delay of communication technology. Optical wireless communication (OWC) combines the advantages of optical fiber communication and traditional wireless communications such as microwave communication. It has the advantages of large-capacity transmission, no frequency license, low cost, convenient installation, safe and confidential communication, etc. It has become an emerging broadband wireless access method and is a good way to approach the last one-mile problem in communications.

The Special Issue of Optical Wireless Communication publishes 15 papers in Opto-electronic Engineering. It mainly introduces the development and future of OWC technology from the aspects of visible light communication, modulation and coding, optical signal transmission and orbital angular momentum (OAM), etc.

By reviewing the frontier technologies and hot spot in the development of OWC, introducing a new theory, new method and new technology, discussing the developing trend of future OWC technology, this Special Issue shows a good way for OWC research, and provides references for designing and developing OWC systems and technologies, so as to promote the upgrading of OWC technology and meet the requirements of access network technology in the age of intelligence.
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  Review  |  O436.3
Online Time:Mar 18, 2020
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Chi Nan, Chen Hui. Progress and prospect of high-speed visible light communication[J]. Opto-Electronic Engineering, 2020, 47(3): 190687. 
  Article  |  TN929.1
Online Time:Mar 18, 2020
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Zhang Ying, Gao Yue, Ke Xizheng. Analysis of spatial correlation of precoding indoor MIMO visible light communication system[J]. Opto-Electronic Engineering, 2020, 47(3): 190666. 
  Review  |  TN929.1;TN364
Online Time:Mar 18, 2020
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Wang Yuhao, Cao Fan, Deng Zhenyu, et al. LED nonlinearity compensation and bandwidth expansion techniques in visible light communication[J]. Opto-Electronic Engineering, 2020, 47(3): 190671. 
  Review  |  TN929.12
Online Time:Mar 18, 2020
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Mao Yicong, Wang Huiqin, Zhang Yue, et al. Research status and development of optical spatial modulation technology[J]. Opto-Electronic Engineering, 2020, 47(3): 190712. 
  Review  |  TN929.1
Online Time:Mar 18, 2020
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Wu Yi, Liu Hongzhan, Hao Yuan, et al. Development and prospect of fountain codes in optical wireless communication[J]. Opto-Electronic Engineering, 2020, 47(3): 190623. 
  Article  |  TN929.1;E963
Online Time:Mar 18, 2020
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Wang Ke, Xu Zhiyong, Li Xuesong, et al. Analysis of space diversity method in modulating retro-reflector optical communication[J]. Opto-Electronic Engineering, 2020, 47(3): 190701. 
  Article  |  TN929.1
Online Time:Mar 18, 2020
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Guo Qian, Song Peng, Zhang Zhouqiang, et al. Research on the key technology of turbulence suppression for atmospheric optical laser communication based on OFDM[J]. Opto-Electronic Engineering, 2020, 47(3): 190619. 
  Article  |  TN248;TN929.12
Online Time:Mar 18, 2020
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Lin Peng, Wang Tianshu, Ma Wanzhuo, et al. Propagation characteristics of 2.07 μm fiber laser in weak turbulence condition[J]. Opto-Electronic Engineering, 2020, 47(3): 190588. 
  Article  |  TN929.12
Online Time:Mar 18, 2020
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Li Songlang, Mao Zhongyang, Liu Chuanhui, et al. Analysis of the effect of cloud thickness on the performance of blue-green laser communication[J]. Opto-Electronic Engineering, 2020, 47(3): 190389. 
  Article  |  O437;TN929.1
Online Time:Mar 18, 2020
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Lv Hong, Ren Chengcheng, Liu Xudong, et al. Field distribution characteristics of vortex beams passing through the non-Gaussian random rough surface[J]. Opto-Electronic Engineering, 2020, 47(3): 190477. 
  Review  |  O436.3
Online Time:Mar 18, 2020
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Guo Zhongyi, Gong Chaofan, Liu Hongjun, et al. Research advances of orbital angular momentum based optical communication technology[J]. Opto-Electronic Engineering, 2020, 47(3): 190593. 
  Review  |  TN929.1
Online Time:Mar 18, 2020
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Yin Xiaoli, Cui Xiaozhou, Chang Huan, et al. Research progress of orbital angular momentum modes detecting technology based on machine learning[J]. Opto-Electronic Engineering, 2020, 47(3): 190584. 
  Article  |  TN29; TN929.1
Online Time:Mar 18, 2020
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Chen Bo, Wang Mingjun, Gao Yongsheng. An ultra-wideband microwave photonic channelized receiver with zero-IF architecture[J]. Opto-Electronic Engineering, 2020, 47(3): 190650. 
  Article  |  V279+.2;TN929.1
Online Time:Mar 18, 2020
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Zhao Taifei, Gao Peng, Shi Haiquan, et al. An algorithm for the bee colony drone to use wireless ultraviolet for cooperative obstacle avoidance[J]. Opto-Electronic Engineering, 2020, 47(3): 190505. 
  Article  |  TB872;TN929.1
Online Time:Mar 18, 2020
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Lu Qian, Ren Bin, Bian Jingying. Research on acquisition and tracking technology for the four-quadrant detector[J]. Opto-Electronic Engineering, 2020, 47(3): 190559.