Data driven soliton solution of the nonlinear Schr\"odinger equation with certain $\mathcal{PT}$-symmetric potentials via deep learning

TL;DR

This paper demonstrates how physics-informed neural networks can accurately approximate soliton solutions of the nonlinear Schrödinger equation with various PT-symmetric potentials, exploring different activation functions and network configurations.

Contribution

It introduces the use of a physics-informed neural network to solve the nonlinear Schrödinger equation with PT-symmetric potentials, including a novel activation function, and analyzes factors affecting model performance.

Findings

Deep learning accurately approximates soliton solutions.

Sech activation function performs well for this problem.

Network structure and data size influence accuracy.

Abstract

We investigate the physics informed neural network method, a deep learning approach, to approximate soliton solution of the nonlinear Schr\"odinger equation with parity time symmetric potentials. We consider three different parity time symmetric potentials, namely Gaussian, periodic and Rosen-Morse potentials. We use physics informed neural network to solve the considered nonlinear partial differential equation with the above three potentials. We compare the predicted result with actual result and analyze the ability of deep learning in solving the considered partial differential equation. We check the ability of deep learning in approximating the soliton solution by taking squared error between real and predicted values. {Further, we examine the factors that affect the performance of the considered deep learning method with different activation functions, namely ReLU, sigmoid and tanh. We also use a new activation function, namely sech which is not used in the field of deep learning and analyze whether this new activation function is suitable for the prediction of soliton solution of nonlinear Schr\"odinger equation for the aforementioned parity time symmetric potentials. In addition to the above, we present how the network's structure and the size of the training data influence the performance of the physics informed neural network. Our results show that the constructed deep learning model successfully approximates the soliton solution of the considered equation with high accuracy.