Relative Phase Equivariant Deep Neural Systems for Physical Layer Communications

Arwin Gansekoele; Sandjai Bhulai; Mark Hoogendoorn; Rob van der Mei

Relative Phase Equivariant Deep Neural Systems for Physical Layer Communications

Arwin Gansekoele, Sandjai Bhulai, Mark Hoogendoorn, Rob van der Mei

Published: 15 Apr 2025, Last Modified: 15 Apr 2025Accepted by TMLREveryoneRevisionsBibTeXCC BY 4.0

Abstract: In the era of telecommunications, the increasing demand for complex and specialized communication systems has led to a focus on improving physical layer communications. Artificial intelligence (AI) has emerged as a promising solution avenue for doing so. Deep neural receivers have already shown significant promise in improving the performance of communications systems. However, a major challenge lies in developing deep neural receivers that match the energy efficiency and speed of traditional receivers. This work investigates the incorporation of inductive biases in the physical layer using group-equivariant deep learning to improve the parameter efficiency of deep neural receivers. We do so by constructing a deep neural receiver that is equivariant with respect to the phase of arrival. We show that the inclusion of relative phase equivariance significantly reduces the error rate of deep neural receivers at similar model sizes. Thus, we show the potential of group-equivariant deep learning in the domain of physical layer communications.

Submission Length: Long submission (more than 12 pages of main content)

Code: https://github.com/awgansekoele/relative-phase-equivariant-deep-neural-systems.git

Assigned Action Editor: Marco Mondelli

Submission Number: 3939

Loading