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Quantum Private Distributed Matrix Multiplication With Degree Tables

Information Theory 2025-12-01 v1 Cryptography and Security Networking and Internet Architecture Signal Processing math.IT Quantum Physics

Abstract

In this paper, we explore how quantum resources can be used to increase the rate of private distributed matrix multiplication (PDMM). In PDMM, a user who has two high-dimensional matrices, AA and BB, and lacks the computational capabilities to apply matrix multiplication locally, divides the matrices AA and BB into KK and LL sub-blocks, respectively. Then, the user sends them to NN servers to apply the required multiplication privately from any TT servers. The goal is to reduce the number of servers needed to perform the required matrix multiplication. In the quantum setting, we allow the servers to share an entangled state and respond over quantum channels. Upon receiving the qudits, the user applies measurements to obtain the required multiplication. There are two main regimes in the PDMM literature: The high-privacy regime and the low-privacy regime where TT is less than KK and LL. First, in the high-privacy regime, the state-of-the-art classical code is called the gap additive secure polynomial (GASP) code. We define a feasibility requirement in the quantum setting for the GASP code such that the highest performance is achieved when it is satisfied. When it is not satisfied, we address two main concerns. The first is to find a relation between the minimum privacy requirement and the dimensions of the two matrices needed for the feasibility condition to be satisfied. Second, we develop a new family of codes that can work in the quantum setting. Second, since GASP does not work efficiently in the low-privacy regimes compared to cyclic-addition degree tables (CAT) and discretely optimized GASP (DOG), we show that the feasibility condition developed for GASP can be adopted for both CAT and DOG codes as well. In addition, we propose another set of codes that can be used in the low privacy regime in the quantum setting when the feasibility requirement is not satisfied.

Keywords

Cite

@article{arxiv.2511.23406,
  title  = {Quantum Private Distributed Matrix Multiplication With Degree Tables},
  author = {Mohamed Nomeir and Alptug Aytekin and Lei Hu and Sennur Ulukus},
  journal= {arXiv preprint arXiv:2511.23406},
  year   = {2025}
}

Comments

The abstract here is trimmed due to the space limitations in the submission process

R2 v1 2026-07-01T07:59:48.942Z