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20 results on '"Hornung, Fabian"'

1. Space-time deep neural network approximations for high-dimensional partial differential equations

Author

Hornung, Fabian, Jentzen, Arnulf, and Salimova, Diyora

Subjects
Mathematics - Probability, Computer Science - Machine Learning, Mathematics - Analysis of PDEs, Mathematics - Numerical Analysis
Abstract

It is one of the most challenging issues in applied mathematics to approximately solve high-dimensional partial differential equations (PDEs) and most of the numerical approximation methods for PDEs in the scientific literature suffer from the so-called curse of dimensionality in the sense that the number of computational operations employed in the corresponding approximation scheme to obtain an approximation precision $\varepsilon>0$ grows exponentially in the PDE dimension and/or the reciprocal of $\varepsilon$. Recently, certain deep learning based approximation methods for PDEs have been proposed and various numerical simulations for such methods suggest that deep neural network (DNN) approximations might have the capacity to indeed overcome the curse of dimensionality in the sense that the number of real parameters used to describe the approximating DNNs grows at most polynomially in both the PDE dimension $d\in\mathbb{N}$ and the reciprocal of the prescribed accuracy $\varepsilon>0$. There are now also a few rigorous results in the scientific literature which substantiate this conjecture by proving that DNNs overcome the curse of dimensionality in approximating solutions of PDEs. Each of these results establishes that DNNs overcome the curse of dimensionality in approximating suitable PDE solutions at a fixed time point $T>0$ and on a compact cube $[a,b]^d$ in space but none of these results provides an answer to the question whether the entire PDE solution on $[0,T]\times [a,b]^d$ can be approximated by DNNs without the curse of dimensionality. It is precisely the subject of this article to overcome this issue. More specifically, the main result of this work in particular proves for every $a\in\mathbb{R}$, $ b\in (a,\infty)$ that solutions of certain Kolmogorov PDEs can be approximated by DNNs on the space-time region $[0,T]\times [a,b]^d$ without the curse of dimensionality., Comment: 56 pages, 2 figures

Published
2020

2. Space-time error estimates for deep neural network approximations for differential equations

Author

Grohs, Philipp, Hornung, Fabian, Jentzen, Arnulf, and Zimmermann, Philipp

Subjects
Mathematics - Numerical Analysis, Computer Science - Machine Learning, 65L70, 68T99
Abstract

Over the last few years deep artificial neural networks (DNNs) have very successfully been used in numerical simulations for a wide variety of computational problems including computer vision, image classification, speech recognition, natural language processing, as well as computational advertisement. In addition, it has recently been proposed to approximate solutions of partial differential equations (PDEs) by means of stochastic learning problems involving DNNs. There are now also a few rigorous mathematical results in the scientific literature which provide error estimates for such deep learning based approximation methods for PDEs. All of these articles provide spatial error estimates for neural network approximations for PDEs but do not provide error estimates for the entire space-time error for the considered neural network approximations. It is the subject of the main result of this article to provide space-time error estimates for DNN approximations of Euler approximations of certain perturbed differential equations. Our proof of this result is based (i) on a certain artificial neural network (ANN) calculus and (ii) on ANN approximation results for products of the form $[0,T]\times \mathbb{R}^d\ni (t,x)\mapsto tx\in \mathbb{R}^d$ where $T\in (0,\infty)$, $d\in \mathbb{N}$, which we both develop within this article., Comment: 86 pages

Published
2019

3. Overcoming the curse of dimensionality in the numerical approximation of Allen-Cahn partial differential equations via truncated full-history recursive multilevel Picard approximations

Author

Beck, Christian, Hornung, Fabian, Hutzenthaler, Martin, Jentzen, Arnulf, and Kruse, Thomas

Subjects
Mathematics - Numerical Analysis, Mathematics - Analysis of PDEs, 65Mxx
Abstract

One of the most challenging problems in applied mathematics is the approximate solution of nonlinear partial differential equations (PDEs) in high dimensions. Standard deterministic approximation methods like finite differences or finite elements suffer from the curse of dimensionality in the sense that the computational effort grows exponentially in the dimension. In this work we overcome this difficulty in the case of reaction-diffusion type PDEs with a locally Lipschitz continuous coervice nonlinearity (such as Allen-Cahn PDEs) by introducing and analyzing truncated variants of the recently introduced full-history recursive multilevel Picard approximation schemes., Comment: 30 pages

Published
2019
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4. The stochastic nonlinear Schr\'odinger equation in unbounded domains and manifolds

Author

Hornung, Fabian

Subjects
Mathematics - Analysis of PDEs, Mathematics - Probability
Abstract

In this article, we construct a global martingale solution to a general nonlinear Schr\"{o}dinger equation with linear multiplicative noise in the Stratonovich form. Our framework includes many examples of spatial domains like $\mathbb{R}^d$, non-compact Riemannian manifolds, and unbounded domains in $\mathbb{R}^d$ with different boundary conditions. The initial value belongs to the energy space $H^1$ and we treat subcritical focusing and defocusing power nonlinearities. The proof is based on an approximation technique which makes use of spectral theoretic methods and an abstract Littlewood-Paley-decomposition. In the limit procedure, we employ tightness of the approximated solutions and Jakubowski's extension of the Skorohod Theorem to nonmetric spaces., Comment: 39 pages, 2 figures

Published
2019

6. Weak martingale solutions for the stochastic nonlinear Schr\'odinger equation driven by pure jump noise

Author

Brzeźniak, Zdzisław, Hornung, Fabian, and Manna, Utpal

Subjects
Mathematics - Probability, Mathematics - Analysis of PDEs
Abstract

We construct a martingale solution of the stochastic nonlinear Schr\"odinger equation with a multiplicative noise of jump type in the Marcus canonical form. The problem is formulated in a general framework that covers the subcritical focusing and defocusing stochastic NLS in $H^1$ on compact manifolds and on bounded domains with various boundary conditions. The proof is based on a variant of the Faedo-Galerkin method. In the formulation of the approximated equations, finite dimensional operators derived from the Littlewood-Paley decomposition complement the classical orthogonal projections to guarantee uniform estimates. Further ingredients of the construction are tightness criteria in certain spaces of cadlag functions and Jakubowski's generalization of the Skorohod-Theorem to nonmetric spaces., Comment: 47 pages, 1 figure

Published
2018

7. A proof that artificial neural networks overcome the curse of dimensionality in the numerical approximation of Black-Scholes partial differential equations

Author

Grohs, Philipp, Hornung, Fabian, Jentzen, Arnulf, and von Wurstemberger, Philippe

Subjects
Mathematics - Numerical Analysis, Computer Science - Machine Learning, Mathematics - Probability, Quantitative Finance - Mathematical Finance
Abstract

Artificial neural networks (ANNs) have very successfully been used in numerical simulations for a series of computational problems ranging from image classification/image recognition, speech recognition, time series analysis, game intelligence, and computational advertising to numerical approximations of partial differential equations (PDEs). Such numerical simulations suggest that ANNs have the capacity to very efficiently approximate high-dimensional functions and, especially, indicate that ANNs seem to admit the fundamental power to overcome the curse of dimensionality when approximating the high-dimensional functions appearing in the above named computational problems. There are a series of rigorous mathematical approximation results for ANNs in the scientific literature. Some of them prove convergence without convergence rates and some even rigorously establish convergence rates but there are only a few special cases where mathematical results can rigorously explain the empirical success of ANNs when approximating high-dimensional functions. The key contribution of this article is to disclose that ANNs can efficiently approximate high-dimensional functions in the case of numerical approximations of Black-Scholes PDEs. More precisely, this work reveals that the number of required parameters of an ANN to approximate the solution of the Black-Scholes PDE grows at most polynomially in both the reciprocal of the prescribed approximation accuracy $\varepsilon > 0$ and the PDE dimension $d \in \mathbb{N}$. We thereby prove, for the first time, that ANNs do indeed overcome the curse of dimensionality in the numerical approximation of Black-Scholes PDEs., Comment: To appear in Mem. Amer. Math. Soc.; 126 pages

Published
2018
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8. Uniqueness of martingale solutions for the stochastic nonlinear Schr\'odinger equation on 3d compact manifolds

Author

Brzezniak, Zdzislaw, Hornung, Fabian, and Weis, Lutz

Subjects
Mathematics - Analysis of PDEs, Mathematics - Probability
Abstract

We prove pathwise uniqueness for solutions of the nonlinear Schr\"{o}dinger equation with conservative multiplicative noise on compact 3D manifolds. In particular, we generalize the result by Burq, G\'erard and Tzvetkov (N. Burq, P. G\'erard, and N. Tzvetkov. Strichartz inequalities and the nonlinear Schr\"{o}dinger equation on compact manifolds. American Journal of Mathematics, 126 (3):569--605, 2004) to the stochastic setting. The proof is based on deterministic and stochastic Strichartz estimates and the Littlewood-Paley decomposition.

Published
2018

10. Martingale solutions for the stochastic nonlinear Schr\'odinger equation in the energy space

Author

Brzezniak, Zdzislaw, Hornung, Fabian, and Weis, Lutz

Subjects
Mathematics - Probability, Mathematics - Analysis of PDEs, 35Q41, 35R60, 60H15, 60H30
Abstract

We consider a stochastic nonlinear Schr\"odinger equation with multiplicative noise in an abstract framework that covers subcritical focusing and defocusing stochastic NLS in $H^1$ on compact manifolds and bounded domains. We construct a martingale solution using a modified Faedo-Galerkin-method based on the Littlewood-Paley-decomposition. For 2d manifolds with bounded geometry, we use Strichartz estimates to show pathwise uniqueness., Comment: Accepted for publication in Probability Theory and Related Fields

Published
2017

11. The nonlinear stochastic Schr\'odinger equation via stochastic Strichartz estimates

Author

Hornung, Fabian

Subjects
Mathematics - Probability, 35Q41, 35R60, 60H15, 60H30
Abstract

We consider the stochastic NLS with nonlinear Stratonovic noise for initial values in $L^2(R^d)$ and prove local existence and uniqueness of a mild solution for subcritical and critical nonlinearities. The proof is based on deterministic and stochastic Strichartz estimates. In the subcritical case, we prove that the solution is global, if we impose an additional assumption on the nonlinear noise., Comment: 25 pages. Typos corrected, global existence for nonlinear noise proved

Published
2016

18. Global solutions of the nonlinear Schrödinger equation with multiplicative noise

Author

Hornung, Fabian and Weis, L.

Subjects
Strichartz estimates, multiplicative noise, jump noise, Mathematics::Analysis of PDEs, martingale solutions, global solutions, ddc:510, Stochastic nonlinear Schrödinger equation, Stratonovich noise, Galerkin method, pathwise uniqueness, Mathematics
Abstract

In this thesis, we investigate existence and uniqueness of solutions to the stochastic nonlinear Schrödinger equation (NLS), i.e. the NLS perturbed by a multiplicative noise. First, we present a fixed point argument based on deterministic and stochastic Strichartz estimates. In this way, we prove local existence and uniqueness of stochastically strong solutions of the stochastic NLS with nonlinear Gaussian noise for initial values in $L^2(\mathbb{R}^d)$ and $H^1(\mathbb{R}^d),$ respectively. Using a stochastic generalization of mass conservation, we show that the $L^2$-solution exists globally under an additional restriction of the noise. In the second part, we develop a general existence theory for global martingale solutions of the stochastic NLS with a saturated Gaussian multiplicative noise. The proof is based on a modified Galerkin approximation and a limit process due to the tightness of the approximated solutions. As an application, we get existence results for the stochastic defocusing and focusing NLS and fractional NLS on various geometries like bounded domains with Dirichlet or Neumann boundary conditions as well as compact Riemannian manifolds. The martingale solution constructed by the Galerkin method is not necessarily unique. For this reason, we independently show pathwise uniqueness of solutions to the stochastic NLS with linear conservative Gaussian noise. The proof works in special cases as 2D and 3D Riemannian manifolds and is based on spectrally localized Strichartz estimates. In the last chapter, we replace the Gaussian noise by a Poisson noise in the Marcus form and transfer the proof of existence of martingale solutions to this case.

Published
2018

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