Channel Orthogonalization in Panel-Based LIS

TL;DR

This paper proposes a novel channel orthogonalization method for panel-based large intelligent surfaces (P-LIS) that enhances spatial resource utilization by enforcing orthogonality through a combined active and low-power RRTx mode, optimizing power efficiency.

Contribution

It introduces a new orthogonalization scheme in P-LIS using RRTx processing and derives a closed-form solution for power minimization, advancing LIS technology for 6G.

Findings

Effective orthogonality achieved in P-LIS channels.

Closed-form solution for RRTx power minimization.

Enhanced spatial resource utilization in LIS systems.

Abstract

Large intelligent surface (LIS) has gained momentum as a potential 6G-enabling technology that expands the benefits of massive multiple-input multiple-output (MIMO). On the other hand, orthogonal space-division multiplexing (OSDM) may give a promising direction for efficient exploitation of the spatial resources, analogous as what is achieved with orthogonal frequency-division multiplexing (OFDM) in the frequency domain. To this end, we study how to enforce channel orthogonality in a panel-based LIS (P-LIS) scenario. Our proposed method consists of having a subset of active LIS-panels coherently serving a set of users, and another subset of LIS-panels operating in a novel low-power mode by implementing a receive and re-transmit (RRTx) process. This results in an inter-symbol interference (ISI) channel, where we characterize the RRTx processing required to achieve simultaneous orthogonality in time and space. We then employ the remaining degrees of freedom (DoFs) from the orthogonality constraint to minimize the RRTx processing power, where we derive a closed-form global minimizer, allowing for efficient implementation of the proposed scheme.