结合偏振复用和铁磁非互易技术实现带内全双工无线通信系统超高隔离（英文）

作     者：Amir Afshani Ke Wu 

作者机构：Poly-Grames Research Center Department of Electrical Engineering école Polytechnique de Montréal 

出 版 物：《Engineering》 (工程(英文))

年 卷 期：2024年第9期

页      面：179-187页

核心收录：

学科分类：080904[工学-电磁场与微波技术] 0810[工学-信息与通信工程] 0809[工学-电子科学与技术（可授工学、理学学位）] 08[工学] 080402[工学-测试计量技术及仪器] 0804[工学-仪器科学与技术] 081001[工学-通信与信息系统] 

基　　金：supported by a Natural Sciences and Engineering Research Council (NSERC)-sponsored Industrial Research Chair program, an NSERC Discovery Grant in part by the Fonds de recherche du Québec Nature et technologies (FRQNT) Doctoral Fellowship of Amir Afshani funded by the Government of Québec Province 

摘      要：The in-band full-duplex(IBFD) wireless system is a promising candidate for 6G and beyond, as it can double data throughput and enormously lower transmission latency by supporting simultaneous in-band transmission and reception of signals. Enabling IBFD systems requires a substantial mitigation of a transmitter(Tx) s strong self-interference(SI) signal into the receiver(Rx) channel. However, current state-ofthe-art approaches to tackle this challenge are inefficient in terms of performance, cost, and complexity,hindering the commercialization of IBFD techniques. In this work, we devise and demonstrate an innovative approach to realize IBFD systems that exhibit superior performance with a low-cost and lesscomplex architecture in an all-passive module. Our scheme is based on meticulously combining polarization-division multiplexing(PDM) with ferromagnetic nonreciprocity to achieve ultra-high isolation between Tx and Rx channels. Such an unprecedented conception has become feasible thanks to a concurrent dual-mode circulator-a new component introduced for the first time-as a key feature of our module, and a dual-mode waveguide that transforms two orthogonally polarized waves into two orthogonal waveguide modes. In addition, we propose a unique passive tunable secondary SI cancellation(SIC) mechanism, which is embedded within the proposed module and boosts the isolation over a relatively broad bandwidth. We report, solely in the analog domain, experimental isolation levels of 50, 70,and 80 d B over 340, 101, and 33 MHz bandwidth at the center frequency of interest, respectively, with excellent tuning capability. Furthermore, the module is tested in two real IBFD scenarios to assess its performance in connection with Tx-to-Rx leakage and modulation error in the presence of a Tx s strong interference signal.