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Quantum dynamical Hamiltonian Monte Carlo

Owen Lockwood, Peter Weiß, Filip Aronshtein, Guillaume Verdon

2024Physical Review Research12 citationsDOIOpen Access PDF

Abstract

One of the open challenges in quantum computing is to find meaningful and practical methods to leverage quantum computation to accelerate classical machine-learning workflows. A ubiquitous problem in machine-learning workflows is sampling from probability distributions that we only have access to via their log probability. To this end, we extend the well-known Hamiltonian Monte Carlo (HMC) method for Markov chain Monte Carlo (MCMC) sampling to leverage quantum computation in a hybrid manner as a proposal function. Our new algorithm, Quantum Dynamical Hamiltonian Monte Carlo (QD-HMC), replaces the classical symplectic integration proposal step with simulations of quantum-coherent continuous-space dynamics on digital or analog quantum computers. We show that QD-HMC maintains key characteristics of HMC, such as maintaining the detailed balanced condition with momentum inversion, while also having the potential for polynomial speedups over its classical counterpart in certain scenarios. As sampling is a core subroutine in many forms of probabilistic inference, and MCMC in continuously parametrized spaces covers a large class of potential applications, this work widens the areas of applicability of quantum devices. Published by the American Physical Society 2024

Topics & Concepts

Markov chain Monte CarloHybrid Monte CarloQuantum Monte CarloComputer scienceQuantum computerMonte Carlo methodStatistical physicsQuantum annealingImportance samplingQuantum algorithmMonte Carlo integrationTheoretical computer scienceAlgorithmQuantumComputational scienceMathematicsPhysicsBayesian probabilityArtificial intelligenceQuantum mechanicsStatisticsQuantum Computing Algorithms and ArchitectureMarkov Chains and Monte Carlo MethodsQuantum many-body systems
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