Litcius/Paper detail

Learning classical readout quantum PUFs based on single-qubit gates

Niklas Pirnay, Anna Pappa, Jean‐Pierre Seifert

2022Quantum Machine Intelligence13 citationsDOIOpen Access PDF

Abstract

Abstract Physical unclonable functions (PUFs) have been proposed as a way to identify and authenticate electronic devices. Recently, several ideas have been presented to that aim to achieve the same for quantum devices. Some of these constructions apply single-qubit gates in order to provide a secure fingerprint of the quantum device. In this work, we formalize the class of classical readout quantum PUFs (CR-QPUFs) using the statistical query (SQ) model and explicitly show insufficient security for CR-QPUFs based on single-qubit rotation gates, when the adversary has SQ access to the CR-QPUF. We demonstrate how a malicious party can learn the CR-QPUF characteristics and forge the signature of a quantum device through a modelling attack using a simple regression of low-degree polynomials. The proposed modelling attack was successfully implemented in a real-world scenario on real IBM Q quantum machines. We thoroughly discuss the prospects and problems of CR-QPUFs where quantum device imperfections are used as a secure fingerprint.

Topics & Concepts

QubitComputer scienceQuantum computerQuantumSignature (topology)Class (philosophy)Theoretical computer scienceQuantum gateComputer engineeringTopology (electrical circuits)PhysicsMathematicsQuantum mechanicsArtificial intelligenceGeometryCombinatoricsPhysical Unclonable Functions (PUFs) and Hardware SecurityAdvanced Memory and Neural ComputingIntegrated Circuits and Semiconductor Failure Analysis