Generalized Multicast Multibeam Precoding for Satellite Communications

TL;DR

This paper introduces a novel two-stage and robust precoding method for multibeam satellite systems that addresses interference, traffic, and feedback challenges, improving throughput and reliability in complex satellite communication scenarios.

Contribution

It proposes a new precoding design tailored for multibeam satellite systems, including robust and distributed approaches, enhancing performance under realistic constraints.

Findings

Effective interference mitigation and signal enhancement demonstrated.

Robust precoding maintains performance with channel uncertainties.

High throughput achieved with low inter-gateway communication.

Abstract

This paper deals with the problem of precoding in multibeam satellite systems. In contrast to general multiuser multiple-input-multiple-output (MIMO) cellular schemes, multibeam satellite architectures suffer from different challenges. First, satellite communications standards embed more than one user in each frame in order to increase the channel coding gain. This leads to the different so-called multigroup multicast model, whose optimization requires computationally complex operations. Second, when the data traffic is generated by several Earth stations (gateways), the precoding matrix must be distributively computed and attain additional payload restrictions. Third, since the feedback channel is adverse (large delay and quantization errors), the precoding must be able to deal with such uncertainties. In order to solve the aforementioned problems, we propose a two-stage precoding design in order to both limit the multibeam interference and to enhance the intra-beam minimum user signal power (i.e. the one that dictates the rate allocation per beam). A robust version of the proposed precoder based on a first perturbation model is presented. This mechanism behaves well when the channel state information is corrupted. Furthermore, we propose a per beam user grouping mechanism together with its robust version in order to increase the precoding gain. Finally, a method for dealing with the multiple gateway architecture is presented, which offers high throughputs with a low inter-gateway communication. The conceived designs are evaluated in a close-to-real beam pattern and the latest broadband communication standard for satellite communications.