Enhanced channel estimation for double RIS-aided MIMO systems using coupled tensor decomposition

TL;DR

This paper introduces a novel coupled tensor decomposition approach for interference-free channel estimation in double-RIS MIMO systems, improving accuracy and reducing constraints compared to existing methods.

Contribution

It proposes a coupled tensor-based estimation framework with new algorithms (C-KRAFT and C-ALS) for more accurate channel estimation in double-RIS MIMO systems.

Findings

Enhanced channel estimation accuracy demonstrated in simulations.

Less restrictive identifiability constraints compared to prior methods.

Effective separation of reflection links using tensor decomposition.

Abstract

In this paper, we consider a double-RIS (D-RIS)-aided flat-fading MIMO system and propose an interference-free channel training and estimation protocol, where the two single-reflection links and the one double-reflection link are estimated separately. Specifically, by using the proposed training protocol, the signal measurements of a particular reflection link can be extracted interference-free from the measurements of the superposition of the three links. We show that some channels are associated with two different components of the received signal. Exploiting the common channels involved in the single and double reflection links while recasting the received signals as tensors, we formulate the coupled tensor-based least square Khatri-Rao factorization (C-KRAFT) algorithm which is a closed-form solution and an enhanced iterative solution with less restrictions on the identifiability constraints, the coupled-alternating least square (C-ALS) algorithm. The C-KRAFT and C-ALS based channel estimation schemes are used to obtain the channel matrices in both single and double reflection links. We show that the proposed coupled tensor decomposition-based channel estimation schemes offer more accurate channel estimates under less restrictive identifiability constraints compared to competing channel estimation methods. Simulation results are provided showing the effectiveness of the proposed algorithms.