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Main Authors: Sprague, Christopher Iliffe, Elofsson, Arne, Azizpour, Hossein
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.11433
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author Sprague, Christopher Iliffe
Elofsson, Arne
Azizpour, Hossein
author_facet Sprague, Christopher Iliffe
Elofsson, Arne
Azizpour, Hossein
contents Modeling complex systems that evolve toward equilibrium distributions is important in various physical applications, including molecular dynamics and robotic control. These systems often follow the stochastic gradient descent of an underlying energy function, converging to stationary distributions around energy minima. The local covariance of these distributions is shaped by the energy landscape's curvature, often resulting in anisotropic characteristics. While flow-based generative models have gained traction in generating samples from equilibrium distributions in such applications, they predominately employ isotropic conditional probability paths, limiting their ability to capture such covariance structures. In this paper, we introduce Hessian-Informed Flow Matching (HI-FM), a novel approach that integrates the Hessian of an energy function into conditional flows within the flow matching framework. This integration allows HI-FM to account for local curvature and anisotropic covariance structures. Our approach leverages the linearization theorem from dynamical systems and incorporates additional considerations such as time transformations and equivariance. Empirical evaluations on the MNIST and Lennard-Jones particles datasets demonstrate that HI-FM improves the likelihood of test samples.
format Preprint
id arxiv_https___arxiv_org_abs_2410_11433
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Hessian-Informed Flow Matching
Sprague, Christopher Iliffe
Elofsson, Arne
Azizpour, Hossein
Machine Learning
Systems and Control
Modeling complex systems that evolve toward equilibrium distributions is important in various physical applications, including molecular dynamics and robotic control. These systems often follow the stochastic gradient descent of an underlying energy function, converging to stationary distributions around energy minima. The local covariance of these distributions is shaped by the energy landscape's curvature, often resulting in anisotropic characteristics. While flow-based generative models have gained traction in generating samples from equilibrium distributions in such applications, they predominately employ isotropic conditional probability paths, limiting their ability to capture such covariance structures. In this paper, we introduce Hessian-Informed Flow Matching (HI-FM), a novel approach that integrates the Hessian of an energy function into conditional flows within the flow matching framework. This integration allows HI-FM to account for local curvature and anisotropic covariance structures. Our approach leverages the linearization theorem from dynamical systems and incorporates additional considerations such as time transformations and equivariance. Empirical evaluations on the MNIST and Lennard-Jones particles datasets demonstrate that HI-FM improves the likelihood of test samples.
title Hessian-Informed Flow Matching
topic Machine Learning
Systems and Control
url https://arxiv.org/abs/2410.11433