论文信息 - Formal Verification of Quantum Protocols

Formal Verification of Quantum Protocols

We propose to analyse quantum protocols by applying formal verification techniques developed in classical computing for the analysis of communicating concurrent systems. One area of successful application of these techniques is that of classical security protocols, exemplified by Lowe's discovery and fix of a flaw in the well-known Needham-Schroeder authentication protocol. Secure quantum cryptographic protocols are also notoriously difficult to design. Quantum cryptography is therefore an interesting target for formal verification, and provides our first example; we expect the approach to be transferable to more general quantum information processing scenarios. The example we use is the quantum key distribution protocol proposed by Bennett and Brassard, commonly referred to as BB84. We present a model of the protocol in the process calculus CCS and the results of some initial analyses using the Concurrency Workbench of the New Century (CWB-NC).

Rajagopal Nagarajan | Simon Gay University of Warwick | University of Glasgow

[1] Dominic Mayers,et al. Unconditional security in quantum cryptography , 1998, JACM.

[2] Hoi-Kwong Lo,et al. Is Quantum Bit Commitment Really Possible? , 1996, ArXiv.

[3] Michael Goldsmith,et al. Modelling and analysis of security protocols , 2001 .

[4] C. A. R. Hoare,et al. Communicating Sequential Processes (Reprint) , 1983, Commun. ACM.

[5] Ekert,et al. Quantum cryptography based on Bell's theorem. , 1991, Physical review letters.

[6] Lo,et al. Unconditional security of quantum key distribution over arbitrarily long distances , 1999, Science.

[7] Dominic Mayers. Unconditionally secure quantum bit commitment is impossible , 1997 .

[8] Gavin Lowe,et al. Breaking and Fixing the Needham-Schroeder Public-Key Protocol Using FDR , 1996, Softw. Concepts Tools.

[9] Hoi-Kwong Lo,et al. From Quantum Cheating to Quantum Security , 2000, quant-ph/0111100.

[10] Robin Milner,et al. Communication and concurrency , 1989, PHI Series in computer science.