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Learning protocols for the fast and efficient control of active matter

Corneel Casert, Stephen Whitelam

2024Nature Communications12 citationsDOIOpen Access PDF

Abstract

Exact analytic calculation shows that optimal control protocols for passive molecular systems often involve rapid variations and discontinuities. However, similar analytic baselines are not generally available for active-matter systems, because it is more difficult to treat active systems exactly. Here we use machine learning to derive efficient control protocols for active-matter systems, and find that they are characterized by sharp features similar to those seen in passive systems. We show that it is possible to learn protocols that effect fast and efficient state-to-state transformations in simulation models of active particles by encoding the protocol in the form of a neural network. We use evolutionary methods to identify protocols that take active particles from one steady state to another, as quickly as possible or with as little energy expended as possible. Our results show that protocols identified by a flexible neural-network ansatz, which allows the optimization of multiple control parameters and the emergence of sharp features, are more efficient than protocols derived recently by constrained analytical methods. Our learning scheme is straightforward to use in experiment, suggesting a way of designing protocols for the efficient manipulation of active matter in the laboratory. Exact analytic calculation shows that optimal control protocols for passive molecular systems often involve rapid variations and discontinuities. However, similar analytic baselines are not generally available for active-matter systems, because it is more difficult to treat active systems exactly. Here, the authors use machine learning to derive efficient control protocols for active-matter systems, and find that they are characterized by sharp features similar to those seen in passive systems.

Topics & Concepts

Computer scienceProtocol (science)Active matterClassification of discontinuitiesArtificial neural networkScheme (mathematics)AnsatzControl (management)Artificial intelligencePhysicsMathematicsBiologyMedicineMathematical analysisAlternative medicinePathologyCell biologyQuantum mechanicsMicro and Nano RoboticsAdvanced Thermodynamics and Statistical MechanicsNeural dynamics and brain function
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