Abstract
Using the data-driven control formulation, an iterative dynamic programming approach which is based on a multi-dimensional Taylor network is established to design the near optimal regulation of discrete-time nonlinear systems. For discrete-time general nonlinear systems, the iterative adaptive dynamic programming algorithm is developed and proved to guarantee the property of convergence and optimality. Three networks are constructed, namely, the identification network, critic network and action network. Moreover, a globalized dual heuristic programming technique with detailed implementation is developed. The cost function and its derivative can be approximated by this novel architecture. Besides, without the consideration of the system dynamics, this technique can learn the near-optimal control law simultaneously and adaptively. In addition, this technique greatly improves the existing results of the iterative adaptive dynamic programming algorithm in terms of reducing the requirement of the control matrix. Furthermore, because of the approach that is based on the multi-dimensional Taylor network, the amount of calculation needed is also greatly reduced. The simulation experiment is described to illustrate the effectiveness of the data-driven optimal regulation method proposed in this paper.
Highlights
A wide range of applications involve optimal control in engineering technology
Sun et al.: Data-Driven Nonlinear Near-Optimal Regulation Based on multi-dimensional Taylor network (MTN) Dynamic Programming mode control is designed in literature [14]
To address the above issues, a data-driven approximate optimal control method for discrete-time nonlinear systems based on multidimensional Taylor network dynamic programming is proposed
Summary
A wide range of applications involve optimal control in engineering technology. To optimize the performance index of the controlled system, the controller design is the basis of the optimal control research [1]. Sun et al.: Data-Driven Nonlinear Near-Optimal Regulation Based on MTN Dynamic Programming mode control is designed in literature [14]. Literature [15] proposes a new output-constrained robust adaptive controller for a class of uncertain multi-input multi-output (MIMO) nonlinear systems These methods which are simple to implement, do not require the controlled object model. The adaptive dynamic programming method is well developed [16] It is concerned with a novel generalized policy iteration algorithm for solving optimal control problems for discrete-time nonlinear systems [17]. To address the above issues, a data-driven approximate optimal control method for discrete-time nonlinear systems based on multidimensional Taylor network dynamic programming is proposed. The main contributions of the proposed control schemes are as followings:
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