We consider parametrized linear-quadratic optimal control problems and provide their online-efficient solutions by combining greedy reduced basis methods and machine learning algorithms. To this end, we first extend the greedy control algorithm, which builds a reduced basis for the manifold of optimal final time adjoint states, to the setting where the objective functional consists of a penalty term measuring the deviation from a desired state and a term describing the control energy. Afterwards, we apply machine learning surrogates to accelerate the online evaluation of the reduced model. The error estimates proven for the greedy procedure are further transferred to the machine learning models and thus allow for efficient a posteriori erro...
This paper considers the problem of controlling a dynamical system when the state cannot be directly...
Reduced bases have been introduced for the approximation of parametrized PDEs in applications where ...
Motivated by online decision-making in time-varying combinatorial environments, we study the problem...
We consider parametrized linear-quadratic optimal control problems and provide their online-efficien...
We propose a suitable model reduction paradigm-the certified reduced basis method (RB)-for the rapid...
Solving complex optimal control problems have confronted computational challenges for a long time. R...
The objectives of this study are the analysis and design of efficient computational methods for deep...
In this paper, we employ the reduced basis method as a surrogate model for the solution of...
Optimal control theory and machine learning techniques are combined to formulate and solve in closed...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
Optimal control theory and machine learning techniques are combined to propose and solve in closed f...
We propose a Reduced Basis method for the solution of parametrized optimal control problems with con...
Leveraging machine learning to facilitate the optimization process is an emerging field that holds t...
The high computational requirements of nonlinear model predictive control (NMPC) are a long-standing...
We propose the reduced basis method for the solution of parametrized optimal control problems descri...
This paper considers the problem of controlling a dynamical system when the state cannot be directly...
Reduced bases have been introduced for the approximation of parametrized PDEs in applications where ...
Motivated by online decision-making in time-varying combinatorial environments, we study the problem...
We consider parametrized linear-quadratic optimal control problems and provide their online-efficien...
We propose a suitable model reduction paradigm-the certified reduced basis method (RB)-for the rapid...
Solving complex optimal control problems have confronted computational challenges for a long time. R...
The objectives of this study are the analysis and design of efficient computational methods for deep...
In this paper, we employ the reduced basis method as a surrogate model for the solution of...
Optimal control theory and machine learning techniques are combined to formulate and solve in closed...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
Optimal control theory and machine learning techniques are combined to propose and solve in closed f...
We propose a Reduced Basis method for the solution of parametrized optimal control problems with con...
Leveraging machine learning to facilitate the optimization process is an emerging field that holds t...
The high computational requirements of nonlinear model predictive control (NMPC) are a long-standing...
We propose the reduced basis method for the solution of parametrized optimal control problems descri...
This paper considers the problem of controlling a dynamical system when the state cannot be directly...
Reduced bases have been introduced for the approximation of parametrized PDEs in applications where ...
Motivated by online decision-making in time-varying combinatorial environments, we study the problem...