Henrique Ferraz scite author profile

Summary We propose a novel event‐triggered optimal tracking control algorithm for nonlinear systems with an infinite horizon discounted cost. The problem is formulated by appropriately augmenting the system and the reference dynamics and then using ideas from reinforcement learning to provide a solution. Namely, a critic network is used to estimate the optimal cost while an actor network is used to approximate the optimal event‐triggered controller. Because the actor network updates only when an event occurs, we shall use a zero‐order hold along with appropriate tuning laws to encounter for this behavior. Because we have dynamics that evolve in continuous and discrete time, we write the closed‐loop system as an impulsive model and prove asymptotic stability of the equilibrium point and Zeno behavior exclusion. Simulation results of a helicopter, a one‐link rigid robot under gravitation field, and a controlled Van‐der‐Pol oscillator are presented to show the efficacy of the proposed approach. Copyright © 2016 John Wiley & Sons, Ltd.

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Event-triggered H-infinity control for unknown continuous-time linear systems using Q-learning

Vamvoudakis

Ferraz

2016

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Dynamic intermittent Q‐learning–based model‐free suboptimal co‐design of ‐stabilization

Yang

Vamvoudakis

Ferraz

et al. 2019

Intl J Robust & Nonlinear

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Summary This paper proposes an intermittent model‐free learning algorithm for linear time‐invariant systems, where the control policy and transmission decisions are co‐designed simultaneously while also being subjected to worst‐case disturbances. The control policy is designed by introducing an internal dynamical system to further reduce the transmission rate and provide bandwidth flexibility in cyber‐physical systems. Moreover, a Q‐learning algorithm with two actors and a single critic structure is developed to learn the optimal parameters of a Q‐function. It is shown by using an impulsive system approach that the closed‐loop system has an asymptotically stable equilibrium and that no Zeno behavior occurs. Furthermore, a qualitative performance analysis of the model‐free dynamic intermittent framework is given and shows the degree of suboptimality concerning the optimal continuous updated controller. Finally, a numerical simulation of an unknown system is carried out to highlight the efficacy of the proposed framework.

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Henrique Ferraz

Model-free event-triggered control algorithm for continuous-time linear systems with optimal performance

Event-triggered optimal tracking control of nonlinear systems

Event-triggered H-infinity control for unknown continuous-time linear systems using Q-learning

Dynamic intermittent Q‐learning–based model‐free suboptimal co‐design of ‐stabilization

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