Partition function estimation with a quantum coin toss
Abstract
Estimating quantum partition functions is a critical task in a variety of fields. However, the problem is classically intractable in general due to the exponential scaling of the Hamiltonian dimension in the number of particles. This paper introduces a quantum algorithm for estimating the partition function of a generic Hamiltonian up to multiplicative error based on a quantum coin toss. The coin is defined by the probability of applying the quantum imaginary-time evolution propagator at inverse temperature to the maximally mixed state, realized by a block-encoding of into a unitary quantum circuit followed by a post-selection measurement. Our algorithm does not use costly subroutines such as quantum phase estimation or amplitude amplification; and the binary nature of the coin allows us to invoke tools from Bernoulli-process analysis to prove a runtime scaling as , quadratically better than previous general-purpose algorithms using similar quantum resources. Moreover, since the coin is defined by a single observable, the method lends itself well to quantum error mitigation. We test this in practice with a proof-of-concept 9-qubit experiment, where we successfully mitigate errors through a simple noise-extrapolation procedure. Our findings offer an interesting alternative for quantum partition function estimation relevant to early-fault quantum hardware.
Cite
@article{arxiv.2411.17816,
title = {Partition function estimation with a quantum coin toss},
author = {Thais de Lima Silva and Lucas Borges and Leandro Aolita},
journal= {arXiv preprint arXiv:2411.17816},
year = {2024}
}
Comments
10 pages + 1 appendix, 3 figures