English

Hamiltonian bridge: A physics-driven generative framework for targeted pattern control

Soft Condensed Matter 2024-10-17 v1 Statistical Mechanics Artificial Intelligence Dynamical Systems Optimization and Control

Abstract

Patterns arise spontaneously in a range of systems spanning the sciences, and their study typically focuses on mechanisms to understand their evolution in space-time. Increasingly, there has been a transition towards controlling these patterns in various functional settings, with implications for engineering. Here, we combine our knowledge of a general class of dynamical laws for pattern formation in non-equilibrium systems, and the power of stochastic optimal control approaches to present a framework that allows us to control patterns at multiple scales, which we dub the "Hamiltonian bridge". We use a mapping between stochastic many-body Lagrangian physics and deterministic Eulerian pattern forming PDEs to leverage our recent approach utilizing the Feynman-Kac-based adjoint path integral formulation for the control of interacting particles and generalize this to the active control of patterning fields. We demonstrate the applicability of our computational framework via numerical experiments on the control of phase separation with and without a conserved order parameter, self-assembly of fluid droplets, coupled reaction-diffusion equations and finally a phenomenological model for spatio-temporal tissue differentiation. We interpret our numerical experiments in terms of a theoretical understanding of how the underlying physics shapes the geometry of the pattern manifold, altering the transport paths of patterns and the nature of pattern interpolation. We finally conclude by showing how optimal control can be utilized to generate complex patterns via an iterative control protocol over pattern forming pdes which can be casted as gradient flows. All together, our study shows how we can systematically build in physical priors into a generative framework for pattern control in non-equilibrium systems across multiple length and time scales.

Keywords

Cite

@article{arxiv.2410.12665,
  title  = {Hamiltonian bridge: A physics-driven generative framework for targeted pattern control},
  author = {Vishaal Krishnan and Sumit Sinha and L. Mahadevan},
  journal= {arXiv preprint arXiv:2410.12665},
  year   = {2024}
}

Comments

29 pages, 8 figures

R2 v1 2026-06-28T19:24:23.511Z