Related papers: Multistable Physical Neural Networks

Multistable Physical Neural Networks

URL: http://arxiv.org/abs/2406.00082v1
Date: Fri, 31 May 2024 13:24:39 GMT
Title: Multistable Physical Neural Networks
Authors: Eran Ben-Haim, Sefi Givli, Yizhar Or, Amir Gat,
Abstract summary: Physical Neural Networks (PNNs) offer the opportunity to view common materials and physical phenomena as networks. In this work, we incorporated mechanical bistability into PNNs, enabling memory and a direct link between computation and physical action. The insights gained from our study pave the way for the implementation of intelligent structures in smart tech, metamaterials, medical devices, soft robotics, and other fields.
Score: 1.3499500088995462
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Artificial neural networks (ANNs), which are inspired by the brain, are a central pillar in the ongoing breakthrough in artificial intelligence. In recent years, researchers have examined mechanical implementations of ANNs, denoted as Physical Neural Networks (PNNs). PNNs offer the opportunity to view common materials and physical phenomena as networks, and to associate computational power with them. In this work, we incorporated mechanical bistability into PNNs, enabling memory and a direct link between computation and physical action. To achieve this, we consider an interconnected network of bistable liquid-filled chambers. We first map all possible equilibrium configurations or steady states, and then examine their stability. Building on these maps, both global and local algorithms for training multistable PNNs are implemented. These algorithms enable us to systematically examine the network's capability to achieve stable output states and thus the network's ability to perform computational tasks. By incorporating PNNs and multistability, we can design structures that mechanically perform tasks typically associated with electronic neural networks, while directly obtaining physical actuation. The insights gained from our study pave the way for the implementation of intelligent structures in smart tech, metamaterials, medical devices, soft robotics, and other fields.

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