Directional Modulation via Symbol-Level Precoding: A Way to Enhance Security

TL;DR

This paper introduces a signal processing approach using directional modulation and symbol-level precoding to improve wireless security against multi-antenna eavesdroppers, without requiring knowledge of the eavesdropper's channel.

Contribution

It proposes novel security-enhancing precoders for multi-user MIMO systems that increase eavesdropper error rates without relying on channel state information of the eavesdropper.

Findings

Precoders outperform benchmark schemes in power efficiency.

Designed algorithms effectively increase eavesdropper error rates.

Simulation results confirm improved security and efficiency.

Abstract

Wireless communication provides a wide coverage at the cost of exposing information to unintended users. As an information-theoretic paradigm, secrecy rate derives bounds for secure transmission when the channel to the eavesdropper is known. However, such bounds are shown to be restrictive in practice and may require exploitation of specialized coding schemes. In this paper, we employ the concept of directional modulation and follow a signal processing approach to enhance the security of multi-user MIMO communication systems when a multi-antenna eavesdropper is present. Enhancing the security is accomplished by increasing the symbol error rate at the eavesdropper. Unlike the information-theoretic secrecy rate paradigm, we assume that the legitimate transmitter is not aware of its channel to the eavesdropper, which is a more realistic assumption. We examine the applicability of MIMO receiving algorithms at the eavesdropper. Using the channel knowledge and the intended symbols for the users, we design security enhancing symbol-level precoders for different transmitter and eavesdropper antenna configurations. We transform each design problem to a linearly constrained quadratic program and propose two solutions, namely the iterative algorithm and one based on non-negative least squares, at each scenario for a computationally-efficient modulation. Simulation results verify the analysis and show that the designed precoders outperform the benchmark scheme in terms of both power efficiency and security enhancement.