Edgar N. Sánchez scite author profile

This paper deals with adaptive tracking for discrete-time multiple-input-multiple-output (MIMO) nonlinear systems in presence of bounded disturbances. In this paper, a high-order neural network (HONN) structure is used to approximate a control law designed by the backstepping technique, applied to a block strict feedback form (BSFF). This paper also includes the respective stability analysis, on the basis of the Lyapunov approach, for the whole controlled system, including the extended Kalman filter (EKF)-based NN learning algorithm. Applicability of the scheme is illustrated via simulation for a discrete-time nonlinear model of an electric induction motor.

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Nonlinear adaptive trajectory tracking using dynamic neural networks

Poznyak

Sánchez

et al. 1999

IEEE Trans. Neural Netw.

163

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In this paper the adaptive nonlinear identification and trajectory tracking are discussed via dynamic neural networks. By means of a Lyapunov-like analysis we determine stability conditions for the identification error. Then we analyze the trajectory tracking error by a local optimal controller. An algebraic Riccati equation and a differential one are used for the identification and the tracking error analysis. As our main original contributions, we establish two theorems: the first one gives a bound for the identification error and the second one establishes a bound for the tracking error. We illustrate the effectiveness of these results by two examples: the second-order relay system with multiple isolated equilibrium points and the chaotic system given by Duffing equation.

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Predefined-time stability of dynamical systems with sliding modes

2015

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This paper introduces a class of fixed-time stable dynamical systems with settling time as a explicit parameter, namely the inverse the gain. Those systems are defined as predefined-timed stable dynamical systems. Continuous and discontinuous are cases are presented. A detailed Lyapunov characterization of this class of systems is also shown. Finally, the application to the design of a class of first order sliding mode controllers is exposed.

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A discontinuous recurrent neural network with predefined time convergence for solution of linear programming

Sánchez‐Torres

Sánchez

Loukianov

2014

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The aim of this paper is to introduce a new recurrent neural network to solve linear programming. The main characteristic of the proposed scheme is its design based on the predefined-time stability. The predefined-time stability is a stronger form of finite-time stability which allows the a priori definition of a convergence time that does not depend on the network initial state. The network structure is based on the Karush-Kuhn-Tucker (KKT) conditions and the KKT multipliers are proposed as sliding mode control inputs. This selection yields to an one-layer recurrent neural network in which the only parameter to be tuned is the desired convergence time. With this features, the network can be easily scaled from a small to a higher dimension problem. The simulation of a simple example shows the feasibility of the current approach.

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Input-to-state stability (ISS) analysis for dynamic neural networks

Sánchez¹,

Perez

191

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Edgar N. Sánchez

Delay-dependent exponential stability analysis of delayed neural networks: an LMI approach

Discrete-Time Inverse Optimal Control for Nonlinear Systems

Discrete-Time High Order Neural Control

Discrete-Time Adaptive Backstepping Nonlinear Control via High-Order Neural Networks

Nonlinear adaptive trajectory tracking using dynamic neural networks

Predefined-time stability of dynamical systems with sliding modes

A discontinuous recurrent neural network with predefined time convergence for solution of linear programming

Input-to-state stability (ISS) analysis for dynamic neural networks

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