English

Asymmetric Leaky Private Information Retrieval

Information Theory 2020-06-05 v1 Databases Information Retrieval math.IT

Abstract

Information-theoretic formulations of the private information retrieval (PIR) problem have been investigated under a variety of scenarios. Symmetric private information retrieval (SPIR) is a variant where a user is able to privately retrieve one out of KK messages from NN non-colluding replicated databases without learning anything about the remaining K1K-1 messages. However, the goal of perfect privacy can be too taxing for certain applications. In this paper, we investigate if the information-theoretic capacity of SPIR (equivalently, the inverse of the minimum download cost) can be increased by relaxing both user and DB privacy definitions. Such relaxation is relevant in applications where privacy can be traded for communication efficiency. We introduce and investigate the Asymmetric Leaky PIR (AL-PIR) model with different privacy leakage budgets in each direction. For user privacy leakage, we bound the probability ratios between all possible realizations of DB queries by a function of a non-negative constant ϵ\epsilon. For DB privacy, we bound the mutual information between the undesired messages, the queries, and the answers, by a function of a non-negative constant δ\delta. We propose a general AL-PIR scheme that achieves an upper bound on the optimal download cost for arbitrary ϵ\epsilon and δ\delta. We show that the optimal download cost of AL-PIR is upper-bounded as D(ϵ,δ)1+1N1δeϵNK11D^{*}(\epsilon,\delta)\leq 1+\frac{1}{N-1}-\frac{\delta e^{\epsilon}}{N^{K-1}-1}. Second, we obtain an information-theoretic lower bound on the download cost as D(ϵ,δ)1+1Neϵ1δ(Neϵ)K11D^{*}(\epsilon,\delta)\geq 1+\frac{1}{Ne^{\epsilon}-1}-\frac{\delta}{(Ne^{\epsilon})^{K-1}-1}. The gap analysis between the two bounds shows that our AL-PIR scheme is optimal when ϵ=0\epsilon =0, i.e., under perfect user privacy and it is optimal within a maximum multiplicative gap of NeϵN1\frac{N-e^{-\epsilon}}{N-1} for any (ϵ,δ)(\epsilon,\delta).

Keywords

Cite

@article{arxiv.2006.03048,
  title  = {Asymmetric Leaky Private Information Retrieval},
  author = {Islam Samy and Mohamed A. Attia and Ravi Tandon and Loukas Lazos},
  journal= {arXiv preprint arXiv:2006.03048},
  year   = {2020}
}
R2 v1 2026-06-23T16:03:58.651Z