Coupling-Robust Accuracy in Multiphysics Physics Informed Neural Networks via Kronecker-Preconditioned Optimization

Abstract

Physics-informed neural networks (PINNs) for coupled multiphysics systems suffer systematic accuracy degradation as inter-equation coupling strengthens. We provide a theoretical explanation for this phenomenon through neural tangent kernel (NTK) analysis: for linearly coupled systems, we prove that the standard NTK's spectral radius grows as Ω(γ2) with coupling strength γ, shrinking the stable learning rate, while block-diagonal Gauss--Newton (GN) preconditioning yields a preconditioned NTK KP = J H+ J (where H is the block-diagonal GN Hessian) whose spectral radius is bounded by S (S = number of networks), independent of γ. We verify the Ω(γ2) growth numerically across symmetric, asymmetric, and nonlinear coupled PDE systems, and confirm λ(KP) = S with equality in all cases. Combining the Kronecker-preconditioned optimizer SOAP with inverse-gradient-norm loss balancing (SOAP+GN) yields coupling-robust accuracy: across 234 experiments spanning three 1D systems of increasing nonlinearity and a 2D electroosmotic flow benchmark, SOAP+GN maintains final-epoch L2 degradation ≤ 1.1× (ratio of strong- to weak-coupling error) even as coupling parameters vary over one to two orders of magnitude, compared with > 102× for Adam+GN. SOAP+GN further scales to a 2D, 6-PDE electroosmotic flow system at EDL-resolved conditions -- a regime that all prior PINN electrokinetics studies have avoided through simplified physics -- where Adam+GN fails entirely (L2 > 0.9).