WIP: Achieving Self-Interference-Free Operation on SDR Platform with Critical TDD Turnaround Time

2022 IEEE 23rd International Symposium on a World of Wireless, Mobile and Multimedia Networks (WoWMoM) Pub Date : 2022-04-15 DOI:10.1109/WoWMoM54355.2022.00051

Thijs Havinga, Xianjun Jiao, Muhammad Aslam, Wei Liu, I. Moerman

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引用次数: 1

Abstract

Software Defined Radio (SDR) platforms are valuable for research and development activities or high-end systems that demand real-time adaptable wireless protocols. While low latency can be achieved using the dedicated digital processing unit of a state-of-the-art SDR platform, its Radio Frequency (RF) front-end often poses a limitation in terms of turnaround time (TT), the time needed for switching from the receiving to the transmitting mode (or vice versa). Zero Intermediate Frequency (ZIF) transceivers are favorable for SDR, but suffer from self-interference even if the device is not currently transmitting. The strict MAC-layer requirements of Time Division Duplex (TDD) protocols like Wi-Fi cannot be achieved using configurable ZIF transceivers without having to compromise receiver sensitivity. Using a novel approach, we show that the TT using the AD9361 RF front-end can be as low as 640 ns, while the self-interference is at the same level as achieved by the conventional TDD mode, which has a TT of at least 55 μs. As compared to Frequency Division Duplex (FDD) mode, a decrease of receiver noise floor by about 13 dB in the 2.4 GHz band and by about 4.5 dB in the 5 GHz band is achieved.

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WIP:在临界TDD周转时间的SDR平台上实现自干扰无操作

软件定义无线电(SDR)平台对于需要实时自适应无线协议的高端系统的研究和开发活动非常有价值。虽然使用最先进的SDR平台的专用数字处理单元可以实现低延迟，但其射频(RF)前端通常在周转时间(TT)方面存在限制，即从接收模式切换到发射模式所需的时间(反之亦然)。零中频(ZIF)收发器有利于SDR，但即使设备当前不发射，也会受到自干扰。像Wi-Fi这样的时分双工(TDD)协议的严格mac层要求不能使用可配置的ZIF收发器而不损害接收器的灵敏度。采用一种新颖的方法，我们证明了使用AD9361射频前端的TT可以低至640 ns，而自干扰与传统TDD模式相同，其TT至少为55 μs。与频分双工(FDD)模式相比，在2.4 GHz频段接收器本底噪声降低约13 dB，在5 GHz频段接收器本底噪声降低约4.5 dB。

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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2022 IEEE 23rd International Symposium on a World of Wireless, Mobile and Multimedia Networks (WoWMoM)

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