Authors: Stefan Rass

Abstract:

Quantum cryptography offers a way of key agreement, which is unbreakable by any external adversary. Authentication is of crucial importance, as perfect secrecy is worthless if the identity of the addressee cannot be ensured before sending important information. Message authentication has been studied thoroughly, but no approach seems to be able to explicitly counter meet-in-the-middle impersonation attacks. The goal of this paper is the development of an authentication scheme being resistant against active adversaries controlling the communication channel. The scheme is built on top of a key-establishment protocol and is unconditionally secure if built upon quantum cryptographic key exchange. In general, the security is the same as for the key-agreement protocol lying underneath.

Keywords: Meet-in-the-middle attack, quantum key distribution, quantum networks, unconditionally secure authentication.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1083137

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References:

[1] C. Bennet. Quantum cryptography: Uncertainty in the service of privacy. Science, 257(7):752-753, 1992.
[2] C. Bennet and G. Brassard. Quantum cryptography: Public key distribution and coin tossing. In Proc. IEEE Int. Conference on Computers, Systems, and Signal Processing, page 175, Bangalore, 1984.
[3] W. Diffie and M. Hellman. New directions in cryptography. IEEE Transactions on Information Theory, IT-22(6):644-654, 1976.
[4] U. Feige, A. Fiat, and A. Shamir. Zero-knowledge proofs of identity. J. Cryptology, 1(2):77-94, 1988.
[5] S. Ghernaouti-H'elie and M. Sfaxi. Upgrading PPP security by quantum key distribution. In NetCon 2005 conference, 2005.
[6] S. Ghernaouti-H'elie, M. Sfaxi, G. Ribordy, and O. Gay. Using quantum key distribution within IPSEC to secure MAN communications. In MAN 2005 conference, 2005.
[7] L. C. Guillou and J.-J. Quisquater. A practical zero-knowledge protocol fitted to security microprocessors minimizing both transmission and memory. In C. G. Gunther, editor, In Advances in Cryptology ÔÇö EUROCRYPT -88, volume 330 of LNCS, pages 123-128. Springer- Verlag, 1988.
[8] T. Helleseth and T. Johansson. Universal hash functions from exponential sums over finite fields and galois rings. In CRYPTO -96: Proceedings of the 16th Annual International Cryptology Conference on Advances in Cryptology, pages 31-44, London, UK, 1996. Springer-Verlag.
[9] R. Koenig, U. Maurer, and R. Renner. On the power of quantum memory. IEEE Transaction on Information Theory, 51(7):2391-2401, July 2005.
[10] H. Krawczyk. LFSR-based hashing and authentication. In CRYPTO -94: Proceedings of the 14th Annual International Cryptology Conference on Advances in Cryptology, pages 129-139, London, UK, 1994. Springer- Verlag.
[11] K. Mehlhorn and U. Vishkin. Randomized and deterministic simulations of PRAMs by parallel machines with restricted granularity of parallel memories. Acta Inf., 21(4):339-374, 1984.
[12] A. Menezes, P. C. van Oorschot, and S. Vanstone. Handbook of applied Cryptography. CRC Press LLC, 1997.
[13] S. Rass. How to send messages over quantum networks in an unconditionally secure manner. Technical Report TR-syssec-05-05, University of Klagenfurt, Computer Science, System Security, Klagenfurt, September 2005.
[14] R. Renner and R. Koenig. Universally composable privacy amplification against quantum adversaries. In J. Kilian, editor, 2nd Theory of Cryptography Conference, TCC 2005, volume 3378 of LNCS, pages 407-425. Springer, Feb. 2005.
[15] P. Rogaway. Bucket hashing and its application to fast message authentication. Journal of Cryptology, 12(2):91-115, 1999.
[16] P. Shor and J. Preskill. Simple proof of security of the BB84 quantum key distribution protocol. Phys. Rev. Lett., 85:441-444, 2000.
[17] V. Shoup. On fast and provably secure message authentication based on universal hashing. In CRYPTO -96: Proceedings of the 16th Annual International Cryptology Conference on Advances in Cryptology, pages 313-328, London, UK, 1996. Springer-Verlag.
[18] D. R. Stinson. Universal hashing and authentication codes. In CRYPTO -91: Proceedings of the 11th Annual International Cryptology Conference on Advances in Cryptology, pages 74-85, London, UK, 1992. Springer-Verlag.
[19] M. Wegman and J. Carter. Universal classes of hashing functions. Journal of Computer and System Sciences, 22:265-279, 1981.
[20] M. Wegman and L. Carter. New hash functions and their use in authentication and set equality. Journal of Computer and System Sciences, 22:265-279, 1981.