In this paper, a new Discontinuity Capturing Shallow Neural Network (DCSNN) for approximating $d$-dimensional piecewise continuous functions and for solving elliptic interface problems is developed. There are three novel features in the present network; namely, (i) jump discontinuities are accurately captured, (ii) it is completely shallow, comprising only one hidden layer, (iii) it is completely mesh-free for solving partial differential equations. The crucial idea here is that a $d$-dimensional piecewise continuous function can be extended to a continuous function defined in $(d+1)$-dimensional space, where the augmented coordinate variable labels the pieces of each sub-domain. We then construct a shallow neural network to express this ne...
We consider the discretization of elliptic boundary-value problems by variational physics-informed n...
Various researchers have used one hidden layer neural networks (weighted sums of sigmoids) to find t...
Recently there has been much interest in understanding why deep neural networks are preferred to sha...
In this paper, we propose a cusp-capturing physics-informed neural network (PINN) to solve discontin...
In this paper, we propose a novel mesh-free numerical method for solving the elliptic interface prob...
Most stochastic gradient descent algorithms can optimize neural networks that are sub-differentiable...
Most stochastic gradient descent algorithms can optimize neural networks that are sub-differentiable...
2In the framework of discontinuous function approximation and discontinuity interface detection, we ...
We present a scalable strategy for development of mesh-free hybrid neuro-symbolic partial differenti...
A new and efficient neural-network and finite-difference hybrid method is developed for solving Pois...
We study the necessary and sufficient complexity of ReLU neural networks---in terms of depth and num...
Deep learning—in particular, deep neural networks (DNNs)—as a mesh-free and self-adapting method has...
The aim of this article is to analyze numerical schemes using two-layer neural networks with infinit...
Continuous-depth neural networks, such as the Neural Ordinary Differential Equations (ODEs), have ar...
This book presents as its main subject new models in mathematical neuroscience. A wide range of neur...
We consider the discretization of elliptic boundary-value problems by variational physics-informed n...
Various researchers have used one hidden layer neural networks (weighted sums of sigmoids) to find t...
Recently there has been much interest in understanding why deep neural networks are preferred to sha...
In this paper, we propose a cusp-capturing physics-informed neural network (PINN) to solve discontin...
In this paper, we propose a novel mesh-free numerical method for solving the elliptic interface prob...
Most stochastic gradient descent algorithms can optimize neural networks that are sub-differentiable...
Most stochastic gradient descent algorithms can optimize neural networks that are sub-differentiable...
2In the framework of discontinuous function approximation and discontinuity interface detection, we ...
We present a scalable strategy for development of mesh-free hybrid neuro-symbolic partial differenti...
A new and efficient neural-network and finite-difference hybrid method is developed for solving Pois...
We study the necessary and sufficient complexity of ReLU neural networks---in terms of depth and num...
Deep learning—in particular, deep neural networks (DNNs)—as a mesh-free and self-adapting method has...
The aim of this article is to analyze numerical schemes using two-layer neural networks with infinit...
Continuous-depth neural networks, such as the Neural Ordinary Differential Equations (ODEs), have ar...
This book presents as its main subject new models in mathematical neuroscience. A wide range of neur...
We consider the discretization of elliptic boundary-value problems by variational physics-informed n...
Various researchers have used one hidden layer neural networks (weighted sums of sigmoids) to find t...
Recently there has been much interest in understanding why deep neural networks are preferred to sha...