On Concurrent and Resettable Zero-Knowledge Proofs for NP
Abstract
A proof is concurrent zero-knowledge if it remains zero-knowledge when many copies of the proof are run in an asynchronous environment, such as the Internet. It is known that zero-knowledge is not necessarily preserved in such an environment. Designing concurrent zero-knowledge proofs is a fundamental issue in the study of zero-knowledge since known zero-knowledge protocols cannot be run in a realistic modern computing environment. In this paper we present a concurrent zero-knowledge proof systems for all languages in NP. Currently, the proof system we present is the only known proof system that retains the zero-knowledge property when copies of the proof are allowed to run in an asynchronous environment. Our proof system has rounds (for a security parameter ), which is almost optimal, as it is shown by Canetti Kilian Petrank and Rosen that black-box concurrent zero-knowledge requires rounds. Canetti, Goldreich, Goldwasser and Micali introduced the notion of {\em resettable} zero-knowledge, and modified an earlier version of our proof system to obtain the first resettable zero-knowledge proof system. This protocol requires rounds. We note that their technique also applies to our current proof system, yielding a resettable zero-knowledge proof for NP with rounds.
Keywords
Cite
@article{arxiv.cs/0107004,
title = {On Concurrent and Resettable Zero-Knowledge Proofs for NP},
author = {Joe Kilian and Erez Petrank and Ransom Richardson},
journal= {arXiv preprint arXiv:cs/0107004},
year = {2007}
}
Comments
This paper is a join of two works. The preliminary versions of these works appeared in the Proceeedings of Advances in Cryptology - EUROCRYPT '99}, May 1999, Lecture Notes in Computer Science Vol. 1592 Springer 1999, pp. 415-431, and in the Proceedings of the thirty third annual ACM Symposium on Theory of Computing, ACM Press, 2001