Physics-constrained 3D convolutional neural networks for electrodynamics
Alexander Scheinker, Reeju Pokharel
Abstract
We present a physics-constrained neural network (PCNN) approach to solving Maxwell’s equations for the electromagnetic fields of intense relativistic charged particle beams. We create a 3D convolutional PCNN to map time-varying current and charge densities J(r, t) and ρ(r, t) to vector and scalar potentials A(r, t) and φ(r, t) from which we generate electromagnetic fields according to Maxwell’s equations: B = ∇ × A and E = −∇φ − ∂A/∂t. Our PCNNs satisfy hard constraints, such as ∇ · B = 0, by construction. Soft constraints push A and φ toward satisfying the Lorenz gauge.
Topics & Concepts
PhysicsLorenz gauge conditionScalar (mathematics)Electromagnetic fieldMaxwell's equationsConvolutional neural networkVector potentialGauge (firearms)Magnetic fieldArtificial neural networkCharge (physics)Mathematical physicsClassical mechanicsQuantum electrodynamicsGauge theoryGauge bosonParticle physicsQuantum mechanicsGauge fixingArtificial intelligenceComputer scienceGeometryMathematicsArchaeologyHistoryModel Reduction and Neural NetworksComputational Physics and Python ApplicationsMagnetic confinement fusion research