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Main Authors: Layden, David, Sweke, Ryan, Havlíček, Vojtěch, Chowdhury, Anirban, Neklyudov, Kirill
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.08462
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author Layden, David
Sweke, Ryan
Havlíček, Vojtěch
Chowdhury, Anirban
Neklyudov, Kirill
author_facet Layden, David
Sweke, Ryan
Havlíček, Vojtěch
Chowdhury, Anirban
Neklyudov, Kirill
contents Flow models are a cornerstone of modern machine learning. They are generative models that progressively transform probability distributions according to learned dynamics. Specifically, they learn a continuous-time Markov process that efficiently maps samples from a simple source distribution into samples from a complex target distribution. We show that these models are naturally related to the Schrödinger equation, for an unusual Hamiltonian on continuous variables. Moreover, we prove that the dynamics generated by this Hamiltonian can be efficiently simulated on a quantum computer. Together, these results give a quantum algorithm for preparing coherent encodings (a.k.a., qsamples) for a vast family of probability distributions--namely, those expressible by flow models--by reducing the task to an existing classical learning problem, plus Hamiltonian simulation. For statistical problems defined by flow models, such as mean estimation and property testing, this enables the use of quantum algorithms tailored to qsamples, which may offer advantages over classical algorithms based only on samples from a flow model. More broadly, these results reveal a close connection between state-of-the-art machine learning models, such as flow matching and diffusion models, and one of the main expected capabilities of quantum computers: simulating quantum dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2510_08462
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Wavefunction Flows: Efficient Quantum Simulation of Continuous Flow Models
Layden, David
Sweke, Ryan
Havlíček, Vojtěch
Chowdhury, Anirban
Neklyudov, Kirill
Quantum Physics
Machine Learning
Flow models are a cornerstone of modern machine learning. They are generative models that progressively transform probability distributions according to learned dynamics. Specifically, they learn a continuous-time Markov process that efficiently maps samples from a simple source distribution into samples from a complex target distribution. We show that these models are naturally related to the Schrödinger equation, for an unusual Hamiltonian on continuous variables. Moreover, we prove that the dynamics generated by this Hamiltonian can be efficiently simulated on a quantum computer. Together, these results give a quantum algorithm for preparing coherent encodings (a.k.a., qsamples) for a vast family of probability distributions--namely, those expressible by flow models--by reducing the task to an existing classical learning problem, plus Hamiltonian simulation. For statistical problems defined by flow models, such as mean estimation and property testing, this enables the use of quantum algorithms tailored to qsamples, which may offer advantages over classical algorithms based only on samples from a flow model. More broadly, these results reveal a close connection between state-of-the-art machine learning models, such as flow matching and diffusion models, and one of the main expected capabilities of quantum computers: simulating quantum dynamics.
title Wavefunction Flows: Efficient Quantum Simulation of Continuous Flow Models
topic Quantum Physics
Machine Learning
url https://arxiv.org/abs/2510.08462