Studies of Flatness of LiFi Channel for IEEE 802.11bb

2020 IEEE Wireless Communications and Networking Conference (WCNC) Pub Date : 2020-05-01 DOI:10.1109/WCNC45663.2020.9120811

A. A. Purwita, H. Haas

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引用次数: 6

Abstract

A task group named IEEE 802.11 Light Communications Amendment-Task Group “bb” (TGbb) was established in July 2018. By bringing light-fidelity (LiFi) technology into the WiFi ecosystem, LiFi can take advantage of the globally recognized WiFi brand, while also improving its capability due to the fact that LiFi does not interfere with WiFi. Early discussions in the task group focused on the physical (PHY) layer. There are two major proposals for the PHY layer. The first one is to use the existing IEEE 802.11 chipsets with LiFi analog front-ends. This is done by means of the frequency up and down-conversions and adding a DC bias. The second proposal is to redefine a whole PHY layer and optimize it by means of adopting adaptive bit loading in order to combat the low-pass filter characteristics of the non-line-of-sight wireless optical channels. Each approach has advantages in terms of the low-entry barrier to the mass market and better performance, respectively. The root question in determining the common mode PHY between the two approaches is how frequent LiFi encounters flat channels. That is, if the channel is flat, then the gain of the adaptive bit loading is not significant. Therefore, this paper aims to investigate the flatness of many samples from the reference channel models defined in the TGbb. We find that the majority of the channels are flat if the signal bandwidth is 20 MHz.

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IEEE 802.11bb的LiFi通道平坦度研究

2018年7月成立了IEEE 802.11光通信修正案-任务组“bb”(TGbb)。通过将光保真(LiFi)技术引入WiFi生态系统，LiFi可以利用全球公认的WiFi品牌，同时由于LiFi不会干扰WiFi，因此可以提高其功能。任务组的早期讨论集中在物理层(PHY)上。物理层有两个主要的提议。第一种是使用现有的IEEE 802.11芯片组和LiFi模拟前端。这是通过频率上下转换和增加直流偏置来实现的。第二种方案是重新定义整个物理层并采用自适应位加载对其进行优化，以对抗非视距无线光信道的低通滤波特性。每种方法在进入大众市场的低门槛和更好的性能方面都有各自的优势。确定两种方法之间共模物理量的根本问题是LiFi遇到平坦信道的频率。也就是说，如果信道是平坦的，那么自适应比特加载的增益是不显著的。因此，本文旨在研究TGbb中定义的参考通道模型中许多样本的平坦度。我们发现，如果信号带宽为20mhz，大多数信道是平坦的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2020 IEEE Wireless Communications and Networking Conference (WCNC)

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