Low-power Distance Bounding

TL;DR

This paper introduces a low-power distance bounding system using a novel physical layer that combines FMCW and backscatter communication, enabling secure, energy-efficient proximity verification for access control and payment systems.

Contribution

It proposes a new physical layer scheme that decouples distance estimation from processing delay, allowing low-power provers and enhancing security against various frauds.

Findings

System achieves low power consumption suitable for passive devices

Provides strong security guarantees against distance, mafia, and terrorist frauds

Validated through simulations and experiments for short-range applications

Abstract

A distance bounding system guarantees an upper bound on the physical distance between a verifier and a prover. However, in contrast to a conventional wireless communication system, distance bounding systems introduce tight requirements on the processing delay at the prover and require high distance measurement precision making their practical realization challenging. Prior proposals of distance bounding systems focused primarily on building provers with minimal processing delays but did not consider the power limitations of provers and verifiers. However, in a wide range of applications (e.g., physical access control), provers are expected to be fully or semi-passive introducing additional constraints on the design and implementation of distance bounding systems. In this work, we propose a new physical layer scheme for distance bounding and leverage this scheme to implement a distance bounding system with a low-power prover. Our physical layer combines frequency modulated continuous wave (FMCW) and backscatter communication. The use of backscatter communication enables low power consumption at the prover which is critical for a number of distance bounding applications. By using the FMCW-based physical layer, we further decouple the physical distance estimation from the processing delay at the prover, thereby enabling the realization of the majority of distance bounding protocols developed in prior art. We evaluate our system under various attack scenarios and show that it offers strong security guarantees against distance, mafia and terrorist frauds. Additionally, we validate the communication and distance measurement characteristics of our system through simulations and experiments and show that it is well suited for short-range physical access control and payment applications.