Nonlinear spatiotemporal dynamics in magnetic dipole systems for physical reservoir computing
摘要
To address the challenges of physical interpretability and scalability in artificial neural networks, physical reservoir computing (PRC) has emerged as a promising research direction in contemporary machine learning. PRC tackles these challenges by leveraging simple and efficient physical systems to emulate neural network dynamics. In this work, we develop a theoretical dynamic model of coupled magnetic dipoles driven by an external magnetic field and systematically analyze its dynamic behaviors. We employed this model to construct a standard physical reservoir computing architecture, and revealed the mechanism of magnetic dipole system for computing. Subsequently, the computational performance is evaluated using regression and classification benchmarks. Our results demonstrate that the models’ rich nonlinear dynamic responses provide a robust foundation for achieving high accuracy in both chaotic time-series prediction and spoken digit recognition. The proposed contactless and nonlocal coupling architecture offers valuable theoretical insights for the advancement of PRC hardware development.