A learning approach for optimal feedback gains for nonlinear continuous time control systems is proposed and analysed. The goal is to establish a rigorous framework for computing approximating optimal feedback gains using neural networks. The approach rests on two main ingredients. First, an optimal control formulation involving an ensemble of trajectories with ‘control’ variables given by the feedback gain functions. Second, an approximation to the feedback functions via realizations of neural networks. Based on universal approximation properties we prove the existence and convergence of optimal stabilizing neural network feedback controllers
Recent research shows that supervised learning can be an effective tool for designing near-optimal f...
Caption title.Includes bibliographical references (leaf 23).Supported by an NSF graduate fellowship....
Abstract Otimal tracking control of discrete‐time non‐linear systems is investigated in this paper. ...
A learning approach for optimal feedback gains for nonlinear continuous time control systems is prop...
This paper proposes a novel optimal tracking control scheme for nonlinear continuous-time systems in...
Designing optimal feedback controllers for nonlinear dynamical systems requires solving Hamilton-Jac...
This paper presents a method for developing control laws for nonlinear systems based on an optimal c...
The design of a feedback controller, so as to minimize a given performance criterion, for a general ...
Abstract—The paper presents neural dynamic optimization (NDO) as a method of optimal feedback contro...
This paper proposes a new algorithm with deep neural networks to solve optimal control problems for ...
Abstract — In this paper, using a neural-network-based online learning optimal control approach, a n...
The application of neural networks technology to dynamic system control has been constrained by the ...
Neural networks are expressive function approimators that can be employed for state estimation in co...
This study provides a lifelong integral reinforcement learning (LIRL)-based optimal tracking scheme ...
Computing optimal feedback controls for nonlinear systems generally requires solving Hamilton-Jacobi...
Recent research shows that supervised learning can be an effective tool for designing near-optimal f...
Caption title.Includes bibliographical references (leaf 23).Supported by an NSF graduate fellowship....
Abstract Otimal tracking control of discrete‐time non‐linear systems is investigated in this paper. ...
A learning approach for optimal feedback gains for nonlinear continuous time control systems is prop...
This paper proposes a novel optimal tracking control scheme for nonlinear continuous-time systems in...
Designing optimal feedback controllers for nonlinear dynamical systems requires solving Hamilton-Jac...
This paper presents a method for developing control laws for nonlinear systems based on an optimal c...
The design of a feedback controller, so as to minimize a given performance criterion, for a general ...
Abstract—The paper presents neural dynamic optimization (NDO) as a method of optimal feedback contro...
This paper proposes a new algorithm with deep neural networks to solve optimal control problems for ...
Abstract — In this paper, using a neural-network-based online learning optimal control approach, a n...
The application of neural networks technology to dynamic system control has been constrained by the ...
Neural networks are expressive function approimators that can be employed for state estimation in co...
This study provides a lifelong integral reinforcement learning (LIRL)-based optimal tracking scheme ...
Computing optimal feedback controls for nonlinear systems generally requires solving Hamilton-Jacobi...
Recent research shows that supervised learning can be an effective tool for designing near-optimal f...
Caption title.Includes bibliographical references (leaf 23).Supported by an NSF graduate fellowship....
Abstract Otimal tracking control of discrete‐time non‐linear systems is investigated in this paper. ...