Dynamic Interference Mitigation for Generalized Partially Connected Quasi-static MIMO Interference Channel

TL;DR

This paper introduces a novel interference mitigation scheme for partially connected MIMO interference channels, significantly increasing degrees of freedom and system performance by exploiting partial connectivity.

Contribution

It proposes a new interference mitigation method that leverages partial connectivity to extend interference alignment feasibility in MIMO networks.

Findings

Significant increase in system DoF in symmetric partially connected MIMO networks.

The proposed scheme outperforms baseline methods in simulations.

Achieves notable performance gains in randomly connected interference networks.

Abstract

Recent works on MIMO interference channels have shown that interference alignment can significantly increase the achievable degrees of freedom (DoF) of the network. However, most of these works have assumed a fully connected interference graph. In this paper, we investigate how the partial connectivity can be exploited to enhance system performance in MIMO interference networks. We propose a novel interference mitigation scheme which introduces constraints for the signal subspaces of the precoders and decorrelators to mitigate "many" interference nulling constraints at a cost of "little" freedoms in precoder and decorrelator design so as to extend the feasibility region of the interference alignment scheme. Our analysis shows that the proposed algorithm can significantly increase system DoF in symmetric partially connected MIMO interference networks. We also compare the performance of the proposed scheme with various baselines and show via simulations that the proposed algorithms could achieve significant gain in the system performance of randomly connected interference networks.