Abstract
Deep learning has an increasing impact to assist research, allowing, for example, the discovery of novel materials. Until now, however, these artificial intelligence techniques have fallen short of discovering the full differential equation of an experimental physical system. Here we show that a dynamical neural network, trained on a minimal amount of data, can predict the behavior of spintronic devices with high accuracy and an extremely efficient simulation time, compared to the micromagnetic simulations that are usually employed to model them. For this purpose, we re-frame the formalism of Neural Ordinary Differential Equations to the constraints of spintronics: few measured outputs, multiple inputs and internal parameters. We demonstrate with Neural Ordinary Differential Equations an acceleration factor over 200 compared to micromagnetic simulations for a complex problem – the simulation of a reservoir computer made of magnetic skyrmions (20 minutes compared to three days). In a second realization, we show that we can predict the noisy response of experimental spintronic nano-oscillators to varying inputs after training Neural Ordinary Differential Equations on five milliseconds of their measured response to a different set of inputs. Neural Ordinary Differential Equations can therefore constitute a disruptive tool for developing spintronic applications in complement to micromagnetic simulations, which are time-consuming and cannot fit experiments when noise or imperfections are present. Our approach can also be generalized to other electronic devices involving dynamics.
Highlights
The rich functionality of spintronic devices stems from the intricate magnetic textures from which they are formed, and the complex dynamical modes that can be excited in these textures
The perpendicular magnetic anisotropy (PMA) may be modulated by voltage through voltage-controlled magnetic anisotropy (VCMA) effects, while the Dzyaloshinskii-Moriya interaction (DMI) is typically a constant of the material
We show that the Neural Ordinary Differential Equations (ODE) trained in the previous section can be used without any change of parameters to predict the response of the spintronic system in a different setting, and with inputs that vary in a very different way, with computation time considerably reduced compared to micromagnetic simulations
Summary
Deep learning has an increasing impact to assist research, allowing, for example, the discovery of novel materials. We show that a dynamical neural network, trained on a minimal amount of data, can predict the behavior of spintronic devices with high accuracy and an extremely efficient simulation time, compared to the micromagnetic simulations that are usually employed to model them For this purpose, we re-frame the formalism of Neural Ordinary Differential Equations to the constraints of spintronics: few measured outputs, multiple inputs and internal parameters. They divide the structures into nanometer-sized cells and simulate the spin dynamics of each cell using the Landau-Lifshitz-Gilbert equation, taking into account local and non-local interactions between the micromagnetic cells[12–16] This technique, involves a considerable number of coupled differential equations and requires very long simulation times, reaching weeks in time-dependent experiments or in micrometer-scale devices. Once the Neural ODE has been properly trained on the training data, the corresponding equation becomes an appropriate model of the system dynamics and can be used to predict its behavior in novel situations not included in the training dataset
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