Inspired by applications in optimal control of semilinear elliptic partial differential equations and physics-integrated imaging, differential equation constrained optimization problems with constituents that are only accessible through data-driven techniques are studied. A particular focus is on the analysis and on numerical methods for problems with machine-learned components. For a rather general context, an error analysis is provided, and particular properties resulting from artificial neural network based approximations are addressed. Moreover, for each of the two inspiring applications analytical details are presented and numerical results are provided
In this paper, we study the statistical limits in terms of Sobolev norms of gradient descent for sol...
We briefly review recent work where deep learning neural networks have been interpreted as discretis...
In this article, we study a way to numerically solve differential equations using neural networks. B...
Inspired by applications in optimal control of semilinear elliptic partial differential equations an...
In this paper we study the optimal control of a class of semilinear elliptic partial differential eq...
The objectives of this study are the analysis and design of efficient computational methods for deep...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
In the present work we explore numerical methods inspired by optimal control theory to train image c...
Optimization problems subject to constraints governed by partial differential equations (PDEs) are a...
Physics-informed neural networks (PINNs) have recently become a popular method for solving forward a...
We propose a general framework for machine learning based optimization under uncertainty. Our approa...
Defence is held on 18.2.2022 12:15 – 16:15 (Zoom), https://aalto.zoom.us/j/61873808631Mechanistic...
The rapid development of artificial intelligence and computational sciences has attracted much more ...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
In this paper, we study the statistical limits in terms of Sobolev norms of gradient descent for sol...
We briefly review recent work where deep learning neural networks have been interpreted as discretis...
In this article, we study a way to numerically solve differential equations using neural networks. B...
Inspired by applications in optimal control of semilinear elliptic partial differential equations an...
In this paper we study the optimal control of a class of semilinear elliptic partial differential eq...
The objectives of this study are the analysis and design of efficient computational methods for deep...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
In the present work we explore numerical methods inspired by optimal control theory to train image c...
Optimization problems subject to constraints governed by partial differential equations (PDEs) are a...
Physics-informed neural networks (PINNs) have recently become a popular method for solving forward a...
We propose a general framework for machine learning based optimization under uncertainty. Our approa...
Defence is held on 18.2.2022 12:15 – 16:15 (Zoom), https://aalto.zoom.us/j/61873808631Mechanistic...
The rapid development of artificial intelligence and computational sciences has attracted much more ...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
In this paper, we study the statistical limits in terms of Sobolev norms of gradient descent for sol...
We briefly review recent work where deep learning neural networks have been interpreted as discretis...
In this article, we study a way to numerically solve differential equations using neural networks. B...