Physics-informed Neural Model Predictive Control of Interacting Active Brownian Particles (2501.18809v1)

Abstract: Active matter systems, composed of self-propelled agents that convert energy into directed motion, exhibit a wide range of emergent behaviors, such as motility-induced phase separation, flocking, and swarming. These phenomena, observed across natural and engineered systems, hold immense potential for applications in programmable materials, directed assembly, and micro-robotics. However, precisely controlling their macroscopic continuum fields, e.g., density or flux, remains a significant challenge due to the complexity of multibody interactions and correlated particle dynamics. To address this challenge, we present a framework that combines physics-informed machine learning with Model Predictive Control. Our approach learns a closure model for complex particle interactions while incorporating known physical principles, resulting in an accurate predictive model suitable for real-time control. By integrating this model into a Model Predictive Control framework, we enable systematic optimization of control actions that can guide the system toward desired macroscopic behaviors. Through two illustrative examples, we showcase the versatility of the framework. First, we control the spatial distribution of particles by splitting them into two groups and dynamically juggling their densities. Second, we simultaneously control both the number density and the mean flux, guiding the latter to follow a prescribed sinusoidal profile. These results highlight the framework's potential to systematically control complex dynamics in active matter systems and provide a foundation for broader applications in programmable and adaptive materials.