English

Matrix Discrepancy from Quantum Communication

Data Structures and Algorithms 2021-10-22 v1 Computational Complexity Combinatorics Quantum Physics

Abstract

We develop a novel connection between discrepancy minimization and (quantum) communication complexity. As an application, we resolve a substantial special case of the Matrix Spencer conjecture. In particular, we show that for every collection of symmetric n×nn \times n matrices A1,,AnA_1,\ldots,A_n with Ai1\|A_i\| \leq 1 and AiFn1/4\|A_i\|_F \leq n^{1/4} there exist signs x{±1}nx \in \{ \pm 1\}^n such that the maximum eigenvalue of inxiAi\sum_{i \leq n} x_i A_i is at most O(n)O(\sqrt n). We give a polynomial-time algorithm based on partial coloring and semidefinite programming to find such xx. Our techniques open a new avenue to use tools from communication complexity and information theory to study discrepancy. The proof of our main result combines a simple compression scheme for transcripts of repeated (quantum) communication protocols with quantum state purification, the Holevo bound from quantum information, and tools from sketching and dimensionality reduction. Our approach also offers a promising avenue to resolve the Matrix Spencer conjecture completely -- we show it is implied by a natural conjecture in quantum communication complexity.

Keywords

Cite

@article{arxiv.2110.10099,
  title  = {Matrix Discrepancy from Quantum Communication},
  author = {Samuel B. Hopkins and Prasad Raghavendra and Abhishek Shetty},
  journal= {arXiv preprint arXiv:2110.10099},
  year   = {2021}
}
R2 v1 2026-06-24T07:01:08.579Z