An Unsupervised Deep Unfolding Framework for robust Symbol Level Precoding
Abstract
Symbol Level Precoding (SLP) has attracted significant research interest due to its ability to exploit interference for energy-efficient transmission. This paper proposes an unsupervised deep-neural network (DNN) based SLP framework. Instead of naively training a DNN architecture for SLP without considering the specifics of the optimization objective of the SLP domain, our proposal unfolds a power minimization SLP formulation based on the interior point method (IPM) proximal `log' barrier function. Furthermore, we extend our proposal to a robust precoding design under channel state information (CSI) uncertainty. The results show that our proposed learning framework provides near-optimal performance while reducing the computational cost from O(n7.5) to O(n3) for the symmetrical system case where n = number of transmit antennas = number of users. This significant complexity reduction is also reflected in a proportional decrease in the proposed approach's execution time compared to the SLP optimization-based solution.
Keywords
Cite
@article{arxiv.2111.08129,
title = {An Unsupervised Deep Unfolding Framework for robust Symbol Level Precoding},
author = {Abdullahi Mohammad and Christos Masouros and Yiannis Andreopoulos},
journal= {arXiv preprint arXiv:2111.08129},
year = {2021}
}
Comments
13 pages, 8 figures, Journal