English

Quantum communication complexity of linear regression

Quantum Physics 2023-05-16 v2 Computational Complexity

Abstract

Quantum computers may achieve speedups over their classical counterparts for solving linear algebra problems. However, in some cases -- such as for low-rank matrices -- dequantized algorithms demonstrate that there cannot be an exponential quantum speedup. In this work, we show that quantum computers have provable polynomial and exponential speedups in terms of communication complexity for some fundamental linear algebra problems \update{if there is no restriction on the rank}. We mainly focus on solving linear regression and Hamiltonian simulation. In the quantum case, the task is to prepare the quantum state of the result. To allow for a fair comparison, in the classical case, the task is to sample from the result. We investigate these two problems in two-party and multiparty models, propose near-optimal quantum protocols and prove quantum/classical lower bounds. In this process, we propose an efficient quantum protocol for quantum singular value transformation, which is a powerful technique for designing quantum algorithms. This will be helpful in developing efficient quantum protocols for many other problems.

Keywords

Cite

@article{arxiv.2210.01601,
  title  = {Quantum communication complexity of linear regression},
  author = {Ashley Montanaro and Changpeng Shao},
  journal= {arXiv preprint arXiv:2210.01601},
  year   = {2023}
}

Comments

34 pages, updated some minor typos, and added one new section on the connection between dequantized algorithms and communication complexity

R2 v1 2026-06-28T02:46:26.528Z