# Analog quantum algorithms for the mixing of Markov chains

**Authors:** Shantanav Chakraborty, Kyle Luh, J\'er\'emie Roland

arXiv: 1904.11895 · 2022-09-14

## TL;DR

This paper introduces an analog quantum algorithm for Markov chain mixing that improves sampling efficiency, and explores quantum mixing times, extending previous results with new theoretical insights and numerical validation.

## Contribution

It presents a novel analog quantum algorithm for Markov chain mixing and extends understanding of quantum mixing times using advanced random matrix theory tools.

## Key findings

- Quantum algorithm scales with the sum of square roots of classical mixing and hitting times.
- Provided an intuitive understanding of eigenvalue statistics in random matrices.
- Numerical simulations support the analytical results and extend to general Markov chains.

## Abstract

The problem of sampling from the stationary distribution of a Markov chain finds widespread applications in a variety of fields. The time required for a Markov chain to converge to its stationary distribution is known as the classical mixing time. In this article, we deal with analog quantum algorithms for mixing. First, we provide an analog quantum algorithm that given a Markov chain, allows us to sample from its stationary distribution in a time that scales as the sum of the square root of the classical mixing time and the square root of the classical hitting time. Our algorithm makes use of the framework of interpolated quantum walks and relies on Hamiltonian evolution in conjunction with von Neumann measurements.   There also exists a different notion for quantum mixing: the problem of sampling from the limiting distribution of quantum walks, defined in a time-averaged sense. In this scenario, the quantum mixing time is defined as the time required to sample from a distribution that is close to this limiting distribution. Recently we provided an upper bound on the quantum mixing time for Erd\"os-Renyi random graphs [Phys. Rev. Lett. 124, 050501 (2020)]. Here, we also extend and expand upon our findings therein. Namely, we provide an intuitive understanding of the state-of-the-art random matrix theory tools used to derive our results. In particular, for our analysis we require information about macroscopic, mesoscopic and microscopic statistics of eigenvalues of random matrices which we highlight here. Furthermore, we provide numerical simulations that corroborate our analytical findings and extend this notion of mixing from simple graphs to any ergodic, reversible, Markov chain.

## Full text

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## Figures

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## References

69 references — full list in the complete paper: https://tomesphere.com/paper/1904.11895/full.md

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Source: https://tomesphere.com/paper/1904.11895