Full-duplex communications for wireless links with asymmetric capacity requirements

2017 51st Asilomar Conference on Signals, Systems, and Computers Pub Date : 2017-10-01 DOI:10.1109/ACSSC.2017.8335646

Orion Afisiadis, A. Austin, Alexios Balatsoukas-Stimming, A. Burg

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Abstract

Asymmetric capacity requirements between the uplink and down-link channels are common in many communication standards and are usually satisfied by using time-division or frequency-division duplexing with asymmetric resource allocation. In-band full-duplex communication can reduce the overhead associated with the aforementioned duplexing methods, but, unfortunately, practical full-duplex systems suffer from residual self-interference. However, in asymmetric links the impact of residual self-interference can be partially mitigated by reducing the transmit powers with the goal of maximising the down-link capacity. Compared to time-division half-duplex systems, it is found that power-adjusted full-duplex operation can improve the down-link capacity of an asymmetric IEEE 802.11 system by 20% at a link distance of 10 m, even with pessimistic assumptions on the achievable amount of self-interference suppression. For highly asymmetric traffic, the operation range where a full-duplex system outperforms a corresponding time-division half-duplex system can extend up to 2 km, covering a typical urban LTE macro-cell.

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具有非对称容量要求的无线链路的全双工通信

在许多通信标准中，上下行信道的容量要求都是不对称的，通常采用不对称资源分配的时分或频分双工来满足这种要求。带内全双工通信可以减少与上述双工方法相关的开销，但不幸的是，实际的全双工系统受到残余自干扰的影响。然而，在非对称链路中，残余自干扰的影响可以通过降低发射功率以最大化下行链路容量来部分减轻。与时分半双工系统相比，即使对可实现的自干扰抑制量进行悲观假设，功率调整全双工操作也可以使非对称IEEE 802.11系统在链路距离为10 m时的下行链路容量提高20%。对于高度不对称的业务，全双工系统优于相应的时分半双工系统的操作范围可以扩展到2公里，覆盖典型的城市LTE宏小区。

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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2017 51st Asilomar Conference on Signals, Systems, and Computers

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