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Harnessing synthetic active particles for physical reservoir computing

Xiangzun Wang, Frank Cichos

2024Nature Communications19 citationsDOIOpen Access PDF

Abstract

The processing of information is an indispensable property of living systems realized by networks of active processes with enormous complexity. They have inspired many variants of modern machine learning, one of them being reservoir computing, in which stimulating a network of nodes with fading memory enables computations and complex predictions. Reservoirs are implemented on computer hardware, but also on unconventional physical substrates such as mechanical oscillators, spins, or bacteria often summarized as physical reservoir computing. Here we demonstrate physical reservoir computing with a synthetic active microparticle system that self-organizes from an active and passive component into inherently noisy nonlinear dynamical units. The self-organization and dynamical response of the unit are the results of a delayed propulsion of the microswimmer to a passive target. A reservoir of such units with a self-coupling via the delayed response can perform predictive tasks despite the strong noise resulting from the Brownian motion of the microswimmers. To achieve efficient noise suppression, we introduce a special architecture that uses historical reservoir states for output. Our results pave the way for the study of information processing in synthetic self-organized active particle systems.

Topics & Concepts

Reservoir computingComputer scienceNoise (video)Physical systemSynthetic biologyBrownian motionDistributed computingArtificial intelligencePhysicsArtificial neural networkImage (mathematics)BioinformaticsRecurrent neural networkBiologyQuantum mechanicsNeural Networks and Reservoir ComputingAdvanced Memory and Neural ComputingNeural dynamics and brain function