Fully parallelized multi prover protocols for NEXP-time

Author

Lapidot, Dror ; Shamir, Adi

Author_Institution

Dept. of Appl. Math., Wiezmann Inst. of Sci., Rehovot, Israel

fYear

1991

fDate

1-4 Oct 1991

Firstpage

13

Lastpage

18

Abstract

A major open problem in the theory of multiprover protocols is to characterize the languages which can be accepted by fully parallelized protocols which achieve an exponentially low probability of cheating in a single round. The problem was motivated by the observation that the probability of cheating the n parallel executions of a multiprover protocol can be exponentially higher than the probability of cheating in n sequential executions of the same protocol. The problem is solved by proving that any language in NEXP-time has a fully parallelized multiprover protocol. By combining this result with a fully parallelized version of the protocol of M. Ben-Or et al. (ACM Symp. on Theory of Computing, 1988), a one-round perfect zero-knowledge protocol (under no cryptographic assumptions) can be obtained for every NEXPTIME language

Keywords

computational complexity; formal languages; protocols; theorem proving; NEXP-time; fully parallelized multi prover protocols; language; one-round perfect zero-knowledge protocol; parallel executions; Cryptographic protocols; Cryptography; Iron; Mathematics; Polynomials;

fLanguage

English

Publisher

ieee

Conference_Titel

Foundations of Computer Science, 1991. Proceedings., 32nd Annual Symposium on

Conference_Location

San Juan

Print_ISBN

0-8186-2445-0

Type

conf

DOI

10.1109/SFCS.1991.185342

Filename

185342