Competitive Physics Informed Networks
This work addresses a key limitation in PINNs for solving PDEs, offering a method that significantly improves accuracy for researchers and practitioners in computational physics and engineering.
The authors tackled the problem of low accuracy in physics-informed neural networks (PINNs) by introducing competitive PINNs (CPINNs), an adversarial approach that trains a discriminator to predict PINN errors, achieving errors four orders of magnitude smaller than previous PINNs and reaching single-precision accuracy on a Poisson problem.
Neural networks can be trained to solve partial differential equations (PDEs) by using the PDE residual as the loss function. This strategy is called "physics-informed neural networks" (PINNs), but it currently cannot produce high-accuracy solutions, typically attaining about $0.1\%$ relative error. We present an adversarial approach that overcomes this limitation, which we call competitive PINNs (CPINNs). CPINNs train a discriminator that is rewarded for predicting mistakes the PINN makes. The discriminator and PINN participate in a zero-sum game with the exact PDE solution as an optimal strategy. This approach avoids squaring the large condition numbers of PDE discretizations, which is the likely reason for failures of previous attempts to decrease PINN errors even on benign problems. Numerical experiments on a Poisson problem show that CPINNs achieve errors four orders of magnitude smaller than the best-performing PINN. We observe relative errors on the order of single-precision accuracy, consistently decreasing with each epoch. To the authors' knowledge, this is the first time this level of accuracy and convergence behavior has been achieved. Additional experiments on the nonlinear Schrödinger, Burgers', and Allen-Cahn equation show that the benefits of CPINNs are not limited to linear problems.