On the power of many one-bit provers

Per Austrin; Johan Håstad; Rafae Pass

doi:10.1145/2422436.2422461

On the power of many one-bit provers

Per Austrin, Johan Håstad, Rafae Pass

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

We study the class of languages, denoted by MIP[k, 1-∈, s], which have k-prover games where each prover just sends a single bit, with completeness 1-∈ and soundness error s. For the case that k=1 (i.e., for the case of interactive proofs), Goldreich, Vadhan and Wigderson (Computational Complexity'02) demonstrate that SZK exactly characterizes languages having 1-bit proof systems with "non-trivial" soundness (i.e., 1/2 < s ≤ 1-2∈). We demonstrate that for the case that k ≥ 2, 1-bit k-prover games exhibit a significantly richer structure: •(Folklore) When s ≤ 1/2 ^k - ∈, MIP[k, 1-∈, s] = BPP; • When 1/2^k + ∈ ≤ s < 2/2^k -∈, MIP[k, 1-∈, s] = SZK; • When s ≥ 2/2^k + ∈, AM ⊆ MIP[k, 1-∈, s]; • For s ≤ 0.62 k/2^k and sufficiently large k, MIP[k, 1-∈, s] ⊆ EXP; • For s ≥ 2k/2^k, MIP[k, 1, 1-∈, s] = NEXP. As such, 1-bit k-prover games yield a natural "quantitative" approach to relating complexity classes such as BPP, SZK, AM, EXP, and NEXP. We leave open the question of whether a more fine-grained hierarchy (between AM and NEXP) can be established for the case when s ≥ 2/2^k + ∈.

Original language	English
Title of host publication	ITCS 2013 - Proceedings of the 2013 ACM Conference on Innovations in Theoretical Computer Science
Pages	215-220
Number of pages	6
DOIs	https://doi.org/10.1145/2422436.2422461
State	Published - 2013
Externally published	Yes
Event	2013 4th ACM Conference on Innovations in Theoretical Computer Science, ITCS 2013 - Berkeley, CA, United States Duration: 9 Jan 2013 → 12 Jan 2013

Publication series

Name	ITCS 2013 - Proceedings of the 2013 ACM Conference on Innovations in Theoretical Computer Science

Conference

Conference	2013 4th ACM Conference on Innovations in Theoretical Computer Science, ITCS 2013
Country/Territory	United States
City	Berkeley, CA
Period	9/01/13 → 12/01/13

Keywords

laconic provers
multi-prover interactive proofs

All Science Journal Classification (ASJC) codes

Management of Technology and Innovation
Computer Science (miscellaneous)

Access to Document

10.1145/2422436.2422461

Cite this

@inproceedings{480a8eadc18d4e71818213ccc67b5c7d,

title = "On the power of many one-bit provers",

abstract = "We study the class of languages, denoted by MIP[k, 1-∈, s], which have k-prover games where each prover just sends a single bit, with completeness 1-∈ and soundness error s. For the case that k=1 (i.e., for the case of interactive proofs), Goldreich, Vadhan and Wigderson (Computational Complexity'02) demonstrate that SZK exactly characterizes languages having 1-bit proof systems with {"}non-trivial{"} soundness (i.e., 1/2 < s ≤ 1-2∈). We demonstrate that for the case that k ≥ 2, 1-bit k-prover games exhibit a significantly richer structure: •(Folklore) When s ≤ 1/2 k - ∈, MIP[k, 1-∈, s] = BPP; • When 1/2k + ∈ ≤ s < 2/2k -∈, MIP[k, 1-∈, s] = SZK; • When s ≥ 2/2k + ∈, AM ⊆ MIP[k, 1-∈, s]; • For s ≤ 0.62 k/2k and sufficiently large k, MIP[k, 1-∈, s] ⊆ EXP; • For s ≥ 2k/2k, MIP[k, 1, 1-∈, s] = NEXP. As such, 1-bit k-prover games yield a natural {"}quantitative{"} approach to relating complexity classes such as BPP, SZK, AM, EXP, and NEXP. We leave open the question of whether a more fine-grained hierarchy (between AM and NEXP) can be established for the case when s ≥ 2/2k + ∈.",

keywords = "laconic provers, multi-prover interactive proofs",

author = "Per Austrin and Johan H{\aa}stad and Rafae Pass",

year = "2013",

doi = "10.1145/2422436.2422461",

language = "الإنجليزيّة",

isbn = "9781450318594",

series = "ITCS 2013 - Proceedings of the 2013 ACM Conference on Innovations in Theoretical Computer Science",

pages = "215--220",

booktitle = "ITCS 2013 - Proceedings of the 2013 ACM Conference on Innovations in Theoretical Computer Science",

note = "2013 4th ACM Conference on Innovations in Theoretical Computer Science, ITCS 2013 ; Conference date: 09-01-2013 Through 12-01-2013",

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Austrin, P, Håstad, J & Pass, R 2013, On the power of many one-bit provers. in ITCS 2013 - Proceedings of the 2013 ACM Conference on Innovations in Theoretical Computer Science. ITCS 2013 - Proceedings of the 2013 ACM Conference on Innovations in Theoretical Computer Science, pp. 215-220, 2013 4th ACM Conference on Innovations in Theoretical Computer Science, ITCS 2013, Berkeley, CA, United States, 9/01/13. https://doi.org/10.1145/2422436.2422461

On the power of many one-bit provers. / Austrin, Per; Håstad, Johan; Pass, Rafae.
ITCS 2013 - Proceedings of the 2013 ACM Conference on Innovations in Theoretical Computer Science. 2013. p. 215-220 (ITCS 2013 - Proceedings of the 2013 ACM Conference on Innovations in Theoretical Computer Science).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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T1 - On the power of many one-bit provers

AU - Austrin, Per

AU - Håstad, Johan

AU - Pass, Rafae

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N2 - We study the class of languages, denoted by MIP[k, 1-∈, s], which have k-prover games where each prover just sends a single bit, with completeness 1-∈ and soundness error s. For the case that k=1 (i.e., for the case of interactive proofs), Goldreich, Vadhan and Wigderson (Computational Complexity'02) demonstrate that SZK exactly characterizes languages having 1-bit proof systems with "non-trivial" soundness (i.e., 1/2 < s ≤ 1-2∈). We demonstrate that for the case that k ≥ 2, 1-bit k-prover games exhibit a significantly richer structure: •(Folklore) When s ≤ 1/2 k - ∈, MIP[k, 1-∈, s] = BPP; • When 1/2k + ∈ ≤ s < 2/2k -∈, MIP[k, 1-∈, s] = SZK; • When s ≥ 2/2k + ∈, AM ⊆ MIP[k, 1-∈, s]; • For s ≤ 0.62 k/2k and sufficiently large k, MIP[k, 1-∈, s] ⊆ EXP; • For s ≥ 2k/2k, MIP[k, 1, 1-∈, s] = NEXP. As such, 1-bit k-prover games yield a natural "quantitative" approach to relating complexity classes such as BPP, SZK, AM, EXP, and NEXP. We leave open the question of whether a more fine-grained hierarchy (between AM and NEXP) can be established for the case when s ≥ 2/2k + ∈.

AB - We study the class of languages, denoted by MIP[k, 1-∈, s], which have k-prover games where each prover just sends a single bit, with completeness 1-∈ and soundness error s. For the case that k=1 (i.e., for the case of interactive proofs), Goldreich, Vadhan and Wigderson (Computational Complexity'02) demonstrate that SZK exactly characterizes languages having 1-bit proof systems with "non-trivial" soundness (i.e., 1/2 < s ≤ 1-2∈). We demonstrate that for the case that k ≥ 2, 1-bit k-prover games exhibit a significantly richer structure: •(Folklore) When s ≤ 1/2 k - ∈, MIP[k, 1-∈, s] = BPP; • When 1/2k + ∈ ≤ s < 2/2k -∈, MIP[k, 1-∈, s] = SZK; • When s ≥ 2/2k + ∈, AM ⊆ MIP[k, 1-∈, s]; • For s ≤ 0.62 k/2k and sufficiently large k, MIP[k, 1-∈, s] ⊆ EXP; • For s ≥ 2k/2k, MIP[k, 1, 1-∈, s] = NEXP. As such, 1-bit k-prover games yield a natural "quantitative" approach to relating complexity classes such as BPP, SZK, AM, EXP, and NEXP. We leave open the question of whether a more fine-grained hierarchy (between AM and NEXP) can be established for the case when s ≥ 2/2k + ∈.

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U2 - 10.1145/2422436.2422461

DO - 10.1145/2422436.2422461

M3 - منشور من مؤتمر

SN - 9781450318594

T3 - ITCS 2013 - Proceedings of the 2013 ACM Conference on Innovations in Theoretical Computer Science

SP - 215

EP - 220

BT - ITCS 2013 - Proceedings of the 2013 ACM Conference on Innovations in Theoretical Computer Science

T2 - 2013 4th ACM Conference on Innovations in Theoretical Computer Science, ITCS 2013

Y2 - 9 January 2013 through 12 January 2013

ER -

On the power of many one-bit provers

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