Magnetostatics and micromagnetics with physics informed neural networks

Partial differential equations and variational problems can be solved with physics informed neural networks (PINNs). The unknown field is approximated with neural networks. Minimizing the residuals of the static Maxwell equation at collocation points or the magnetostatic energy, the weights of the neural network are adjusted so that the neural network solution approximates the magnetic vector potential. This way, the magnetic flux density for a given magnetization distribution can be estimated. With the magnetization as an additional unknown, inverse magnetostatic problems can be solved. Augmenting the magnetostatic energy with additional energy terms, micromagnetic problems can be solved. We demonstrate the use of physics informed neural networks for solving magnetostatic problems, computing the magnetization for inverse problems, and calculating the demagnetization curves for two-dimensional geometries.

Automated summary

Physics informed neural networks can be used to solve partial differential equations and variational problems related to magnetic fields, by approximating the unknown field with neural networks. This method can be applied to estimate magnetic flux density, solve inverse magnetostatic problems, and address micromagnetic problems.