A 4-Element 800MHz-BW 29mW True-Time-Delay Spatial Signal Processor Enabling Fast Beam-Training with Data Communications

TL;DR

This paper presents a reconfigurable true-time-delay array for millimeter-wave wireless networks that enables fast beam training and precise wideband beamforming, demonstrated with high delay bandwidth and low power consumption.

Contribution

It introduces a compact, digitally reconfigurable TTD array with high delay-bandwidth product, enabling rapid beam training and accurate wideband beamforming in millimeter-wave systems.

Findings

Achieves 800MHz bandwidth with 3.8ns maximum delay.

Demonstrates nearly 12dB uniform beamforming gain.

Consumes 29mW power at 1V supply.

Abstract

Spatial signal processors (SSP) for emerging millimeter-wave wireless networks are critically dependent on link discovery. To avoid loss in communication, mobile devices need to locate narrow directional beams with millisecond latency. In this work, we demonstrate a true-time-delay (TTD) array with digitally reconfigurable delay elements enabling both fast beam-training at the receiver with wideband data communications. In beam-training mode, large delay-bandwidth products are implemented to accelerate beam training using frequency-dependent probing beams. In data communications mode, precise beam alignment is achieved to mitigate spatial effects during beam-forming for wideband signals. The 4-element switched-capacitor based time-interleaved array uses a compact closed-loop integrator for signal combining with the delay compensation implemented in the clock domain to achieve high precision and large delay range. Prototyped in TSMC 65nm CMOS, the TTD SSP successfully demonstrates unique frequency-to-angle mapping with 3.8ns maximum delay and 800MHz bandwidth in the beam-training mode. In the data communications mode, nearly 12dB uniform beamforming gain is achieved from 80MHz to 800MHz. The TTD SSP consumes 29mW at 1V supply achieving 122MB/s with 16-QAM at 9.8% EVM.