AmbShield: Enhancing Physical Layer Security with Ambient Backscatter Devices against Eavesdroppers

TL;DR

AmbShield introduces ambient backscatter devices to enhance physical layer security by passively jamming eavesdroppers and boosting legitimate signals without extra power or complex deployment, using a unified analytical framework.

Contribution

This work proposes AmbShield, a novel PLS scheme leveraging ambient backscatter devices for passive security enhancement with minimal deployment overhead.

Findings

Significant reduction in secrecy outage probability demonstrated.

Effective security gains under imperfect synchronization and CSI estimation.

Analytical framework provides clear design guidelines.

Abstract

Passive eavesdropping compromises confidentiality in wireless networks, especially in resource-constrained environments where heavyweight cryptography is impractical. Physical layer security (PLS) exploits channel randomness and spatial selectivity to confine information to an intended receiver with modest overhead. However, typical PLS techniques, such as using beamforming, artificial noise, and reconfigurable intelligent surfaces, often involve added active power or specialized deployment, and, in many designs, rely on precise time synchronization and perfect CSI estimation, which limits their practicality. To this end, we propose AmbShield, an AmBD-assisted PLS scheme that leverages naturally distributed AmBDs to simultaneously strengthen the legitimate channel and degrade eavesdroppers' without requiring extra transmit power and with minimal deployment overhead. In AmbShield, AmBDs are exploited as friendly jammers that randomly backscatter to create interference at eavesdroppers, and as passive relays that backscatter the desired signal to enhance the capacity of legitimate devices. We further develop a unified analytical framework that analyzes the exact probability density function (PDF) and cumulative distribution function (CDF) of legitimate and eavesdropper signal-to-interference-noise ratio (SINR), and a closed-form secrecy outage probability (SOP). The analysis provides clear design guidelines on various practical system parameters to minimize SOP. Extensive experiments that include Monte Carlo simulations, theoretical derivations, and high-SNR asymptotic analysis demonstrate the security gains of AmbShield across diverse system parameters under imperfect synchronization and CSI estimation.