BER-Based Physical Layer Security with Finite Codelength: Combining Strong Converse and Error Amplification

TL;DR

This paper introduces a BER-based physical layer security method for finite blocklengths by combining strong converse principles with cryptographic error amplification, analyzing tradeoffs and optimizing power for fading channels.

Contribution

It develops an analytical framework linking blocklength, transmission rates, and BER for secure communication, extending security analysis to various channel types including fading channels.

Findings

Analytical tradeoff relations for finite blocklength and BER in DMCs.

Security gap analysis for Gaussian channels and other DMCs.

Power optimization to minimize outage probability under BER constraints.

Abstract

A bit error rate (BER)-based physical layer security approach is proposed for finite blocklength. For secure communication in the sense of high BER, the information-theoretic strong converse is combined with cryptographic error amplification achieved by substitution permutation networks (SPNs) based on confusion and diffusion. For discrete memoryless channels (DMCs), an analytical framework is provided showing the tradeoffs among finite blocklength, maximum/minimum possible transmission rates, and BER requirements for the legitimate receiver and the eavesdropper. Also, the security gap is analytically studied for Gaussian channels and the concept is extended to other DMCs including binary symmetric channels (BSCs) and binary erasure channels (BECs). For fading channels, the transmit power is optimized to minimize the outage probability of the legitimate receiver subject to a BER threshold for the eavesdropper.