TY - GEN
T1 - On the Optimal Communication Complexity of Error-Correcting Multi-server PIR
AU - Eriguchi, Reo
AU - Kurosawa, Kaoru
AU - Nuida, Koji
N1 - Publisher Copyright:
© 2022, The Author(s), under exclusive license to Springer Nature Switzerland AG.
PY - 2022
Y1 - 2022
N2 - An ℓ -server Private Information Retrieval (PIR) scheme enables a client to retrieve a data item from a database replicated among ℓ servers while hiding the identity of the item. It is called b-error-correcting if a client can correctly compute the data item even in the presence of b malicious servers. It is known that b-error correction is possible if and only if ℓ> 2 b. In this paper, we first prove that if error correction is perfect, i.e., the client always corrects errors, the minimum communication cost of b-error-correcting ℓ -server PIR is asymptotically equal to that of regular (ℓ- 2 b) -server PIR as a function of the database size n. Secondly, we formalize a relaxed notion of statistical b-error-correcting PIR, which allows non-zero failure probability. We show that as a function of n, the minimum communication cost of statistical b-error-correcting ℓ -server PIR is asymptotically equal to that of regular (ℓ- b) -server one, which is at most that of (ℓ- 2 b) -server one. Our main technical contribution is a generic construction of statistical b-error-correcting ℓ -server PIR for any ℓ> 2 b from regular (ℓ- b) -server PIR. We can therefore reduce the problem of determining the optimal communication complexity of error-correcting PIR to determining that of regular PIR. In particular, our construction instantiated with the state-of-the-art PIR schemes and the previous lower bound for single-server PIR result in a separation in terms of communication cost between perfect and statistical error correction for any ℓ> 2 b.
AB - An ℓ -server Private Information Retrieval (PIR) scheme enables a client to retrieve a data item from a database replicated among ℓ servers while hiding the identity of the item. It is called b-error-correcting if a client can correctly compute the data item even in the presence of b malicious servers. It is known that b-error correction is possible if and only if ℓ> 2 b. In this paper, we first prove that if error correction is perfect, i.e., the client always corrects errors, the minimum communication cost of b-error-correcting ℓ -server PIR is asymptotically equal to that of regular (ℓ- 2 b) -server PIR as a function of the database size n. Secondly, we formalize a relaxed notion of statistical b-error-correcting PIR, which allows non-zero failure probability. We show that as a function of n, the minimum communication cost of statistical b-error-correcting ℓ -server PIR is asymptotically equal to that of regular (ℓ- b) -server one, which is at most that of (ℓ- 2 b) -server one. Our main technical contribution is a generic construction of statistical b-error-correcting ℓ -server PIR for any ℓ> 2 b from regular (ℓ- b) -server PIR. We can therefore reduce the problem of determining the optimal communication complexity of error-correcting PIR to determining that of regular PIR. In particular, our construction instantiated with the state-of-the-art PIR schemes and the previous lower bound for single-server PIR result in a separation in terms of communication cost between perfect and statistical error correction for any ℓ> 2 b.
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U2 - 10.1007/978-3-031-22368-6_3
DO - 10.1007/978-3-031-22368-6_3
M3 - Conference contribution
AN - SCOPUS:85146676988
SN - 9783031223679
T3 - Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
SP - 60
EP - 88
BT - Theory of Cryptography - 20th International Conference, TCC 2022, Proceedings
A2 - Kiltz, Eike
A2 - Vaikuntanathan, Vinod
PB - Springer Science and Business Media Deutschland GmbH
T2 - 20th Theory of Cryptography Conference, TCC 2022
Y2 - 7 November 2022 through 10 November 2022
ER -