SESaMo: Symmetry-Enforcing Stochastic Modulation for Normalizing Flows
Abstract
Deep generative models have recently garnered significant attention across various fields, from physics to chemistry, where sampling from unnormalized Boltzmann-like distributions represents a fundamental challenge. In particular, autoregressive models and normalizing flows have become prominent due to their appealing ability to yield closed-form probability densities. Moreover, it is well-established that incorporating prior knowledge - such as symmetries - into deep neural networks can substantially improve training performances. In this context, recent advances have focused on developing symmetry-equivariant generative models, achieving remarkable results. Building upon these foundations, this paper introduces Symmetry-Enforcing Stochastic Modulation (SESaMo). Similar to equivariant normalizing flows, SESaMo enables the incorporation of inductive biases (e.g., symmetries) into normalizing flows through a novel technique called stochastic modulation. This approach enhances the flexibility of the generative model, allowing to effectively learn a variety of exact and broken symmetries. Our numerical experiments benchmark SESaMo in different scenarios, including an 8-Gaussian mixture model and physically relevant field theories, such as the theory and the Hubbard model.
Keywords
Cite
@article{arxiv.2505.19619,
title = {SESaMo: Symmetry-Enforcing Stochastic Modulation for Normalizing Flows},
author = {Janik Kreit and Dominic Schuh and Kim A. Nicoli and Lena Funcke},
journal= {arXiv preprint arXiv:2505.19619},
year = {2025}
}
Comments
27 pages, 14 figures