Repeater-Aided Over-the-Air Phase Synchronization in Distributed MIMO
This work addresses a critical bottleneck for deploying distributed MIMO in challenging environments, expanding its applicability beyond existing methods.
The paper tackles the problem of phase synchronization in distributed MIMO systems when direct communication between access points is too weak, proposing a novel over-the-air calibration scheme using repeater nodes to enable coherent joint transmission.
Phase synchronization of access points (APs) in a distributed multiple-input multiple-output (D-MIMO) system is critical to leverage the performance benefits of D-MIMO. Existing over-the-air phase synchronization methods assume that APs can communicate directly to perform necessary measurements. However, this assumption might not hold in scenarios where inter-AP signaling is too weak for effective communication. To address this, in this paper, we propose a novel over-the-air calibration scheme that uses repeater nodes to facilitate phase synchronization when direct AP signaling is infeasible. We give the steps of the algorithm for phase calibration in closed form, and show how it enables coherent joint transmission (CJT) by the APs. The framework expands the applicability of D-MIMO systems to challenging environments, where existing over-the-air synchronization techniques fall short.