Quantum-inspired sublinear algorithm for solving low-rank semidefinite programming
Nai-Hui Chia, Tongyang Li, Han-Hsuan Lin, Chunhao Wang

TL;DR
This paper introduces a quantum-inspired, sublinear-time algorithm for solving low-rank semidefinite programs, enabling efficient computation of solutions and spectral decompositions with applications to quantum state learning.
Contribution
It presents a novel sublinear-time algorithm for low-rank SDP solving using sampling techniques, including new methods for spectral decomposition and matrix exponential approximation.
Findings
Algorithm runs in time $O(m ext{poly}( ext{log} n, r, 1/\varepsilon))$
First sampling-based spectral decomposition method introduced
Application demonstrated in quantum state learning
Abstract
Semidefinite programming (SDP) is a central topic in mathematical optimization with extensive studies on its efficient solvers. In this paper, we present a proof-of-principle sublinear-time algorithm for solving SDPs with low-rank constraints; specifically, given an SDP with constraint matrices, each of dimension and rank , our algorithm can compute any entry and efficient descriptions of the spectral decomposition of the solution matrix. The algorithm runs in time given access to a sampling-based low-overhead data structure for the constraint matrices, where is the precision of the solution. In addition, we apply our algorithm to a quantum state learning task as an application. Technically, our approach aligns with 1) SDP solvers based on the matrix multiplicative weight (MMW) framework by Arora and Kale [TOC…
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