Physics-informed digital twin and onboard control of a brainbot for intelligent active matter

TL;DR

This paper presents an autonomous brainbot with a physics-informed digital twin and onboard model predictive control, enabling it to sense, predict, and navigate complex paths, advancing active matter research.

Contribution

It introduces a scalable framework combining physical modeling, data-driven parameter identification, and control for intelligent active particles.

Findings

Digital twin accurately reproduces trajectory statistics

Onboard MPC enables precise trajectory tracking

Proof of concept for autonomous, agentic active matter

Abstract

Establishing adaptive particles that sense their state, anticipate their evolution, and compute control inputs onboard has been a major challenge in non-equilibrium physics. We address this challenge by realizing an autonomous brainbot, building on a recently developed programmable bristlebot. First, we construct a physics-informed digital twin of the device, based on a kinematic model that reproduces measured trajectory statistics and generates long, statistically faithful synthetic trajectories. The kinematics forms the foundation for implementing onboard model predictive control (MPC), enabling autonomous trajectory tracking, demonstrated by accurate execution of a non-trivial target path. This provides a proof of principle for a brainbot that senses its state, predicts its evolution, and computes control inputs onboard, unlike conventional active particles with fixed motility, thereby transforming the brainbot into an agentic physical entity. By integrating physical modeling, data-driven parameter identification, and control into a unified framework, our approach provides a scalable platform for machine-learning-enabled multi-agent studies and lays the groundwork for intelligent, adaptive active matter.