STEER: Beam Selection for Full-Duplex Millimeter Wave Communication Systems

TL;DR

STEER is a beam selection method for full-duplex mmWave systems that enhances beamforming gain while significantly reducing self-interference without requiring changes to existing standards.

Contribution

It introduces a novel beam selection approach that jointly optimizes transmit and receive beams using minimal self-interference measurements, compatible with current cellular standards.

Findings

Reduces self-interference by over 20 dB

Improves SINR by more than 10 dB

Outperforms conventional beam selection in full-duplex operation

Abstract

Modern millimeter wave (mmWave) communication systems rely on beam alignment to deliver sufficient beamforming gain to close the link between devices. We present a novel beam selection methodology for multi-panel, full-duplex mmWave systems, which we call STEER, that delivers high beamforming gain while significantly reducing the full-duplex self-interference coupled between the transmit and receive beams. STEER does not necessitate changes to conventional beam alignment methodologies nor additional over-the-air feedback, making it compatible with existing cellular standards. Instead, STEER uses conventional beam alignment to identify the general directions beams should be steered, and then it makes use of a minimal number of self-interference measurements to jointly select transmit and receive beams that deliver high gain in these directions while coupling low self-interference. We implement STEER on an industry-grade 28 GHz phased array platform and use further simulation to show that full-duplex operation with beams selected by STEER can notably outperform both half-duplex and full-duplex operation with beams chosen via conventional beam selection. For instance, STEER can reliably reduce self-interference by more than 20 dB and improve SINR by more than 10 dB, compared to conventional beam selection. Our experimental results highlight that beam alignment can be used not only to deliver high beamforming gain in full-duplex mmWave systems but also to mitigate self-interference to levels near or below the noise floor, rendering additional self-interference cancellation unnecessary with STEER.