用于可见光通信的太阳能板接收器系统实现

2015 IEEE International Conference on Electronics, Circuits, and Systems (ICECS) Pub Date : 2015-12-01 DOI:10.1109/ICECS.2015.7440361

B. Malik, Xun Zhang

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引用次数: 20

摘要

可见光通信(VLC)是一项快速发展的技术。该技术有几个优点:(1)通信在空间中受到控制和保护，因为光不会穿过墙壁;(2)与无线电波不同，可见光不与电子元件相互作用，这使得该通信技术适用于电磁波敏感环境;(3)可见光提供更宽的带宽，通信可以达到非常高的速率(即千兆比特)。在本文中，我们研究了结合功率收发技术的VLC系统的功耗问题。针对太阳能板输出信号变形后的输入信号，在太阳能板VLC接收机中设计了信号调理单元。太阳能电池板充当光电探测器，并通过将光信号转换为电子信号为接收器电路供电。我们的太阳能电池板经调节后的频率响应为50千赫。结果表明，在数据速率为8kbit/s、传输距离为50 cm的情况下，

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Solar panel receiver system implementation for visible light communication

Visible Light Communication (VLC) is a rapidly growing technology. This technology has several advantages: (1) communication is controlled and secured in the space, as light does not go through walls, (2) unlike radio waves, visible light does not interact with the electronic components which makes this communication technology suitable for electromagnetic wave-sensitive environments, and (3) visible light offers wider bandwidth and communication can have reach very high rates (i.e. gigabit). In this paper, we investigate power consumption issues for VLC systems in combination with power transreceiver technologies. We propose a Signal Conditioning Unit in solar panel-based VLC receiver to regular the input signal which was deformed from output of solar panel. A solar panel acts as photo-detector and also powers the receiver circuit by converting the light signal into electronic signal. The frequency response of our solar panel is 50 kHz after conditioning. The results show that for a data rate of 8kbit/s with a transmission distance of 50 cm.

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2015 IEEE International Conference on Electronics, Circuits, and Systems (ICECS)

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