High Entropy Random Selection Protocols

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

High Entropy Random Selection Protocols. / Buhrman, Harry; Christandl, Matthias; Koucky, Michal; Lotker, Zvi; Patt-Shamir, Boaz; Vereshchagin, Nikolay.

In: Algorithmica, Vol. 83, No. 2, 2021, p. 667-694.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Buhrman, H, Christandl, M, Koucky, M, Lotker, Z, Patt-Shamir, B & Vereshchagin, N 2021, 'High Entropy Random Selection Protocols', Algorithmica, vol. 83, no. 2, pp. 667-694. https://doi.org/10.1007/s00453-020-00770-y

APA

Buhrman, H., Christandl, M., Koucky, M., Lotker, Z., Patt-Shamir, B., & Vereshchagin, N. (2021). High Entropy Random Selection Protocols. Algorithmica, 83(2), 667-694. https://doi.org/10.1007/s00453-020-00770-y

Vancouver

Buhrman H, Christandl M, Koucky M, Lotker Z, Patt-Shamir B, Vereshchagin N. High Entropy Random Selection Protocols. Algorithmica. 2021;83(2):667-694. https://doi.org/10.1007/s00453-020-00770-y

Author

Buhrman, Harry ; Christandl, Matthias ; Koucky, Michal ; Lotker, Zvi ; Patt-Shamir, Boaz ; Vereshchagin, Nikolay. / High Entropy Random Selection Protocols. In: Algorithmica. 2021 ; Vol. 83, No. 2. pp. 667-694.

Bibtex

@article{88fd8d03ee0d46749af1074dd4a056d0,
title = "High Entropy Random Selection Protocols",
abstract = "We study the two party problem of randomly selecting a common string among all the strings of length n. We want the protocol to have the property that the output distribution has high Shannon entropy or high min entropy, even when one of the two parties is dishonest and deviates from the protocol. We develop protocols that achieve high, close to n, Shannon entropy and simultaneously min entropy close to n/2. In the literature the randomness guarantee is usually expressed in terms of {"}resilience{"}. The notion of Shannon entropy is not directly comparable to that of resilience, but we establish a connection between the two that allows us to compare our protocols with the existing ones. We construct an explicit protocol that yields Shannon entropy n - O(1) and has O(log* n) rounds, improving over the protocol of Goldreich et al. (SIAM J Comput 27: 506-544, 1998) that also achieves this entropy but needs O(n) rounds. Both these protocols need O(n(2)) bits of communication. Next we reduce the number of rounds and the length of communication in our protocols. We show the existence, non-explicitly, of a protocol that has 6 rounds, O(n) bits of communication and yields Shannon entropy n - O(log n) and min entropy n/2 - O(log n). Our protocol achieves the same Shannon entropy bound as, also non-explicit, protocol of Gradwohl et al. (in: Dwork (ed) Advances in Cryptology-CRYPTO `06, 409-426, Technical Report, 2006), however achieves much higher min entropy: n/2 - O(log n) versus O(log n). Finally we exhibit a very simple 3-round explicit {"}geometric{"} protocol with communication length O(n). We connect the security parameter of this protocol with the well studied Kakeya problem motivated by Harmonic Analysis and Analytic Number Theory. We prove that this protocol has Shannon entropy n - o(n). Its relation to the Kakeya problem follows a new and different approach to the random selection problem than any of the previously known protocols.",
keywords = "KAKEYA SETS",
author = "Harry Buhrman and Matthias Christandl and Michal Koucky and Zvi Lotker and Boaz Patt-Shamir and Nikolay Vereshchagin",
year = "2021",
doi = "10.1007/s00453-020-00770-y",
language = "English",
volume = "83",
pages = "667--694",
journal = "Algorithmica",
issn = "0178-4617",
publisher = "Springer",
number = "2",

}

RIS

TY - JOUR

T1 - High Entropy Random Selection Protocols

AU - Buhrman, Harry

AU - Christandl, Matthias

AU - Koucky, Michal

AU - Lotker, Zvi

AU - Patt-Shamir, Boaz

AU - Vereshchagin, Nikolay

PY - 2021

Y1 - 2021

N2 - We study the two party problem of randomly selecting a common string among all the strings of length n. We want the protocol to have the property that the output distribution has high Shannon entropy or high min entropy, even when one of the two parties is dishonest and deviates from the protocol. We develop protocols that achieve high, close to n, Shannon entropy and simultaneously min entropy close to n/2. In the literature the randomness guarantee is usually expressed in terms of "resilience". The notion of Shannon entropy is not directly comparable to that of resilience, but we establish a connection between the two that allows us to compare our protocols with the existing ones. We construct an explicit protocol that yields Shannon entropy n - O(1) and has O(log* n) rounds, improving over the protocol of Goldreich et al. (SIAM J Comput 27: 506-544, 1998) that also achieves this entropy but needs O(n) rounds. Both these protocols need O(n(2)) bits of communication. Next we reduce the number of rounds and the length of communication in our protocols. We show the existence, non-explicitly, of a protocol that has 6 rounds, O(n) bits of communication and yields Shannon entropy n - O(log n) and min entropy n/2 - O(log n). Our protocol achieves the same Shannon entropy bound as, also non-explicit, protocol of Gradwohl et al. (in: Dwork (ed) Advances in Cryptology-CRYPTO `06, 409-426, Technical Report, 2006), however achieves much higher min entropy: n/2 - O(log n) versus O(log n). Finally we exhibit a very simple 3-round explicit "geometric" protocol with communication length O(n). We connect the security parameter of this protocol with the well studied Kakeya problem motivated by Harmonic Analysis and Analytic Number Theory. We prove that this protocol has Shannon entropy n - o(n). Its relation to the Kakeya problem follows a new and different approach to the random selection problem than any of the previously known protocols.

AB - We study the two party problem of randomly selecting a common string among all the strings of length n. We want the protocol to have the property that the output distribution has high Shannon entropy or high min entropy, even when one of the two parties is dishonest and deviates from the protocol. We develop protocols that achieve high, close to n, Shannon entropy and simultaneously min entropy close to n/2. In the literature the randomness guarantee is usually expressed in terms of "resilience". The notion of Shannon entropy is not directly comparable to that of resilience, but we establish a connection between the two that allows us to compare our protocols with the existing ones. We construct an explicit protocol that yields Shannon entropy n - O(1) and has O(log* n) rounds, improving over the protocol of Goldreich et al. (SIAM J Comput 27: 506-544, 1998) that also achieves this entropy but needs O(n) rounds. Both these protocols need O(n(2)) bits of communication. Next we reduce the number of rounds and the length of communication in our protocols. We show the existence, non-explicitly, of a protocol that has 6 rounds, O(n) bits of communication and yields Shannon entropy n - O(log n) and min entropy n/2 - O(log n). Our protocol achieves the same Shannon entropy bound as, also non-explicit, protocol of Gradwohl et al. (in: Dwork (ed) Advances in Cryptology-CRYPTO `06, 409-426, Technical Report, 2006), however achieves much higher min entropy: n/2 - O(log n) versus O(log n). Finally we exhibit a very simple 3-round explicit "geometric" protocol with communication length O(n). We connect the security parameter of this protocol with the well studied Kakeya problem motivated by Harmonic Analysis and Analytic Number Theory. We prove that this protocol has Shannon entropy n - o(n). Its relation to the Kakeya problem follows a new and different approach to the random selection problem than any of the previously known protocols.

KW - KAKEYA SETS

U2 - 10.1007/s00453-020-00770-y

DO - 10.1007/s00453-020-00770-y

M3 - Journal article

VL - 83

SP - 667

EP - 694

JO - Algorithmica

JF - Algorithmica

SN - 0178-4617

IS - 2

ER -

ID: 261375727