Litcius/Paper detail

Supervised Learning in Physical Networks: From Machine Learning to Learning Machines

Menachem Stern, Daniel Hexner, Jason W. Rocks, Andrea J. Liu

2021Physical Review X56 citationsDOIOpen Access PDF

Abstract

Materials and machines are often designed with particular goals in mind, so that they exhibit desired responses to given forces or constraints. Here we explore an alternative approach, namely physical coupled learning. In this paradigm, the system is not initially designed to accomplish a task, but physically adapts to applied forces to develop the ability to perform the task. Crucially, we require coupled learning to be facilitated by physically plausible learning rules, meaning that learning requires only local responses and no explicit information about the desired functionality. We show that such local learning rules can be derived for any physical network, whether in equilibrium or in steady state, with specific focus on two particular systems, namely disordered flow networks and elastic networks. By applying and adapting advances of statistical learning theory to the physical world, we demonstrate the plausibility of new classes of smart metamaterials capable of adapting to users' needs in situ.

Topics & Concepts

Computer scienceMachine learningArtificial intelligenceFocus (optics)Active learning (machine learning)Robot learningComputational learning theoryPhysical systemSupervised learningOnline machine learningUnsupervised learningStability (learning theory)Semi-supervised learningInstance-based learningArtificial neural networkMulti-task learningAlgorithmic learning theoryMeaning (existential)Inductive transferLearning theoryInformation flowRobotHuman–computer interactionError-driven learningNeural Networks and Reservoir ComputingMicro and Nano RoboticsAdvanced Materials and Mechanics