No Analog Combiner TTD-based Hybrid Precoding for Multi-User Sub-THz Communications

TL;DR

This paper proposes a practical hybrid precoding architecture for multi-user sub-THz communications that avoids analog combiners, optimizing subarray allocation and TTD device constraints to enhance performance.

Contribution

It introduces a non-overlapping subarray architecture and an optimization framework for real-world TTD-based hybrid precoding in multi-user sub-THz systems.

Findings

Significant performance gains with the proposed architecture.

Effective subarray allocation for fairness among users.

Enhanced subarray gain considering TTD device constraints.

Abstract

We address the design and optimization of real-world-suitable hybrid precoders for multi-user wideband sub-terahertz (sub-THz) communications. We note that the conventional fully connected true-time delay (TTD)-based architecture is impractical because there is no room for the required large number of analog signal combiners in the circuit board. Additionally, analog signal combiners incur significant signal power loss. These limitations are often overlooked in sub-THz research. To overcome these issues, we study a non-overlapping subarray architecture that eliminates the need for analog combiners. We extend the conventional single-user assumption by formulating an optimization problem to maximize the minimum data rate for simultaneously served users. This complex optimization problem is divided into two sub-problems. The first sub-problem aims to ensure a fair subarray allocation for all users and is solved via a continuous domain relaxation technique. The second sub-problem deals with practical TTD device constraints on range and resolution to maximize the subarray gain and is resolved by shifting to the phase domain. Our simulation results highlight significant performance gain for our real-world-ready TTD-based hybrid precoders.