English

On the Optimal Message Size in PIR Under Arbitrary Collusion Patterns

Information Theory 2026-01-27 v1 math.IT

Abstract

A private information retrieval protocol (PIR) scheme under an arbitrary collusion pattern P\mathcal{P} enables a client to retrieve one message from a library of KK equal-sized messages duplicated in NN servers, while keeping the index of the desired message private from any colluding set in P\mathcal{P}. Although achieving high rates typically requires sufficiently large message sizes, smaller message sizes also desirable due to reduced implementation complexity and fewer constraints. By characterizing the capacity-achieving schemes, Tian, Sun, and Chen (2019) showed that the optimal message size for uniformly decomposable PIR schemes under no-collusion setting is N1N-1. However, comparable results are not yet available for more general collusion settings. In this work, we present a complete characterization of the properties of capacity-achieving decomposable PIR schemes under arbitrary collusion patterns. Building on this characterization, we derive a general lower bound on the optimal message size for capacity-achieving uniformly decomposable PIR schemes under an arbitrary collusion pattern P\mathcal{P}, expressed in terms of the hitting number of a newly defined family of subsets of servers determined by the collusion pattern P\mathcal{P}. Finally, we specialize the lower bound to several important classes of collusion patterns, including TT-collusion, disjoint collections of colluding sets, cyclically TT-contiguous collusion, and disjoint collections of cyclically contiguous colluding sets. For the last two collusion patterns, we present matching achievable schemes that attain the corresponding bounds, thereby providing a complete characterization of the optimal message size.

Keywords

Cite

@article{arxiv.2601.18440,
  title  = {On the Optimal Message Size in PIR Under Arbitrary Collusion Patterns},
  author = {Guru S. Dornadula and Manikya Pant and Gowtham R. Kurri and Prasad Krishnan},
  journal= {arXiv preprint arXiv:2601.18440},
  year   = {2026}
}

Comments

12 pages

R2 v1 2026-07-01T09:20:17.813Z