Learning quantum Hamiltonians at any temperature in polynomial time
Abstract
We study the problem of learning a local quantum Hamiltonian given copies of its Gibbs state at a known inverse temperature . Anshu, Arunachalam, Kuwahara, and Soleimanifar (arXiv:2004.07266) gave an algorithm to learn a Hamiltonian on qubits to precision with only polynomially many copies of the Gibbs state, but which takes exponential time. Obtaining a computationally efficient algorithm has been a major open problem [Alhambra'22 (arXiv:2204.08349)], [Anshu, Arunachalam'22 (arXiv:2204.08349)], with prior work only resolving this in the limited cases of high temperature [Haah, Kothari, Tang'21 (arXiv:2108.04842)] or commuting terms [Anshu, Arunachalam, Kuwahara, Soleimanifar'21]. We fully resolve this problem, giving a polynomial time algorithm for learning to precision from polynomially many copies of the Gibbs state at any constant . Our main technical contribution is a new flat polynomial approximation to the exponential function, and a translation between multi-variate scalar polynomials and nested commutators. This enables us to formulate Hamiltonian learning as a polynomial system. We then show that solving a low-degree sum-of-squares relaxation of this polynomial system suffices to accurately learn the Hamiltonian.
Keywords
Cite
@article{arxiv.2310.02243,
title = {Learning quantum Hamiltonians at any temperature in polynomial time},
author = {Ainesh Bakshi and Allen Liu and Ankur Moitra and Ewin Tang},
journal= {arXiv preprint arXiv:2310.02243},
year = {2026}
}
Comments
66 pages; v2 minor edits, clarification on locality