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 (ODEs) to the constraints of spintronics: few measured outputs, multiple inputs and internal parameters. We demonstrate with Spin-Neural ODEs 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 Spin-Neural ODEs on five milliseconds of their measured response to different excitations. Spin-Neural ODE is 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. Spin-Neural ODE can also be generalized to other electronic devices involving dynamics.
翻译:深层学习对协助研究具有越来越大的影响,例如,可以发现新材料。然而,直到现在,这些人工智能技术还没有发现实验物理系统的全面差异方程式。在这里,我们显示,与通常用来模拟的微磁模拟相比,一个以最低数量数据培训的动态神经网络能够以高精度和极高效的模拟时间预测脊柱性装置的行为,与通常用来模拟这些装置的微磁模拟相比,这种动态神经神经网络能够以高精度和极高效的模拟时间预测其行为。为此,我们重新界定神经普通差异方程式(ODS)对脊柱性装置限制的形式:很少测量产出、多种输入和内部参数。我们用Spin-Neural 代码显示一个超过200的加速系数,而与微磁性模拟相比,对于复杂的问题 -- -- 由磁性电磁性云模型制作的模拟(20分钟至3天) -- -- 与通常用于模拟的储油层纳米振动模型相比 -- -- 我们可以预测实验实验性纳米振动纳米振动器对各种投入的冷度反应:在对其测量时间的5毫秒内测量性动态反应进行训练后,对于不同振动的微变变变变变动应用的模拟也是无法适应的磁工具的。