English

Symmetric Private Polynomial Computation From Lagrange Encoding

Information Theory 2021-11-09 v3 math.IT

Abstract

The problem of XX-secure TT-colluding symmetric Private Polynomial Computation (PPC) from coded storage system with BB Byzantine and UU unresponsive servers is studied in this paper. Specifically, a dataset consisting of MM files is stored across NN distributed servers according to (N,K+X)(N,K+X) Maximum Distance Separable (MDS) codes such that any group of up to XX colluding servers can not learn anything about the data files. A user wishes to privately evaluate one out of a set of candidate polynomial functions over the MM files from the system, while guaranteeing that any TT colluding servers can not learn anything about the identity of the desired function and the user can not learn anything about the MM data files more than the desired polynomial function evaluations, in the presence of BB Byzantine servers that can send arbitrary responses maliciously to confuse the user and UU unresponsive servers that will not respond any information at all. A novel symmetric PPC scheme using Lagrange encoding is proposed. This scheme achieves a PPC rate of 1G(K+X1)+T+2BNU1-\frac{G(K+X-1)+T+2B}{N-U} with secrecy rate G(K+X1)+TN(G(K+X1)+T+2B+U)\frac{G(K+X-1)+T}{N-(G(K+X-1)+T+2B+U)} and finite field size N+max{K,N(G(K+X1)+T+2B+U)}N+\max\{K,N-(G(K+X-1)+T+2B+U)\}, where GG is the maximum degree over all the candidate polynomial functions. Moreover, to further measure the efficiency of PPC schemes, upload cost, query complexity, server computation complexity and decoding complexity required to implement the scheme are analyzed. Remarkably, the PPC setup studied in this paper generalizes all the previous MDS coded PPC setups and the degraded schemes strictly outperform the best known schemes in terms of (asymptotical) PPC rate, which is the main concern of the PPC schemes.

Keywords

Cite

@article{arxiv.2010.09326,
  title  = {Symmetric Private Polynomial Computation From Lagrange Encoding},
  author = {Jinbao Zhu and Qifa Yan and Xiaohu Tang and Songze Li},
  journal= {arXiv preprint arXiv:2010.09326},
  year   = {2021}
}
R2 v1 2026-06-23T19:26:41.940Z