English

Secure Private Information Retrieval from Colluding Databases with Eavesdroppers

Information Theory 2017-10-04 v1 math.IT

Abstract

The problem of private information retrieval (PIR) is to retrieve one message out of KK messages replicated at NN databases, without revealing the identity of the desired message to the databases. We consider the problem of PIR with colluding servers and eavesdroppers, named T-EPIR. Specifically, any TT out of NN databases may collude, i.e. they may communicate their interactions with the user to guess the identity of the requested message. An eavesdropper is curious to know the database and can tap in on the incoming and outgoing transmissions of any EE databases. The databases share some common randomness unknown to the eavesdropper and the user, and use the common randomness to generate the answers, such that the eavesdropper can learn no information about the KK messages. Define RR^* as the optimal ratio of the number of the desired message information bits to the number of total downloaded bits, and ρ\rho^* to be the optimal ratio of the information bits of the shared common randomness to the information bits of the desired file. In our previous work, we found that when ETE \geq T, the optimal ratio that can be achieved equals 1EN1-\frac{E}{N}. In this work, we focus on the case when ETE \leq T. We derive an outer bound R(1TN)1EN(TN)K11(TN)KR^* \leq (1-\frac{T}{N}) \frac{1-\frac{E}{N} \cdot (\frac{T}{N})^{K-1}}{1-(\frac{T}{N})^K}. We also obtain a lower bound of ρEN(1(TN)K)(1TN)(1EN(TN)K1)\rho^* \geq \frac{\frac{E}{N}(1-(\frac{T}{N})^K)}{(1-\frac{T}{N})(1-\frac{E}{N} \cdot (\frac{T}{N})^{K-1})}. For the achievability, we propose a scheme which achieves the rate (inner bound) R=1TN1(TN)KEKNR=\frac{1-\frac{T}{N}}{1-(\frac{T}{N})^K}-\frac{E}{KN}. The amount of shared common randomness used in the achievable scheme is EN(1(TN)K)1TNEKN(1(TN)K)\frac{\frac{E}{N}(1-(\frac{T}{N})^K)}{1-\frac{T}{N}-\frac{E}{KN}(1-(\frac{T}{N})^K)} times the file size. The gap between the derived inner and outer bounds vanishes as the number of messages KK tends to infinity.

Keywords

Cite

@article{arxiv.1710.01190,
  title  = {Secure Private Information Retrieval from Colluding Databases with Eavesdroppers},
  author = {Qiwen Wang and Mikael Skoglund},
  journal= {arXiv preprint arXiv:1710.01190},
  year   = {2017}
}
R2 v1 2026-06-22T22:02:29.125Z