Litcius/Paper detail

Real-World Evaluation of Full-Duplex Millimeter Wave Communication Systems

Ian P. Roberts, Yu Zhang, Tawfik Osman, Ahmed Alkhateeb

2024IEEE Transactions on Wireless Communications11 citationsDOI

Abstract

Noteworthy strides continue to be made in the development of full-duplex millimeter wave (mmWave) communication systems, but most of this progress has been built on theoretical models and validated through simulation. In this work, we conduct a long overdue real-world evaluation of full-duplex mmWave systems using off-the-shelf 60 GHz phased arrays. We collect over 200,000 measurements of self-interference by electronically sweeping the transmit and receive beams of an experimental base station across a dense spatial profile, shedding light on the effects of the environment, array positioning, and beam steering direction. Then, we call attention to five key challenges faced by practical full-duplex mmWave systems and, with these in mind, propose a general framework for beamforming-based full-duplex solutions. Guided by this framework, we introduce a novel solution called STEER+, a more robust version of recent work called STEER, and experimentally evaluate both in a real-world setting with actual downlink and uplink users. Rather than purely minimize self-interference as with STEER, STEER+ makes use of additional measurements to maximize spectral efficiency, which proves to make it much less sensitive to one’s choice of design parameters. Experimentally, we demonstrate that STEER+ can reliably reduce self-interference to near or below the noise floor while maintaining high SNR on the downlink and uplink, thus enabling full-duplex operation purely via beamforming.

Topics & Concepts

BeamformingTelecommunications linkComputer scienceBase stationDuplex (building)Interference (communication)Extremely high frequencyCommunications systemElectronic engineeringSpectral efficiencyTelecommunicationsEngineeringDNABiologyGeneticsChannel (broadcasting)Full-Duplex Wireless CommunicationsMillimeter-Wave Propagation and ModelingMicrowave Engineering and Waveguides