Self-triggered Model Predictive Control for nonholonomic systems

This paper proposes a Model Predictive Control (MPC) framework combined with a self-triggering mechanism for constrained uncertain systems. Under the proposed scheme, the control input as well as the next control update time are provided at each triggering instant. Between two consecutive triggering...

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Hauptverfasser:	Eqtami, Alina, Heshmati-alamdari, Shahab, Dimarogonas, Dimos V., Kyriakopoulos, Kostas J.
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Closed loop systems Constrained uncertain systems Control framework Control trajectory Convergence Non-holonomic robot Nonholonomic systems Robot kinematics Stability analysis Stability and convergence Trajectory Triggering mechanism Ultimately bounded
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creator	Eqtami, Alina Heshmati-alamdari, Shahab Dimarogonas, Dimos V. Kyriakopoulos, Kostas J.
description	This paper proposes a Model Predictive Control (MPC) framework combined with a self-triggering mechanism for constrained uncertain systems. Under the proposed scheme, the control input as well as the next control update time are provided at each triggering instant. Between two consecutive triggering instants, the control trajectory given by the MPC is applied to the plant in an open-loop fashion. This results to less frequent computations while preserving stability and convergence of the closed-loop system. A scenario for the stabilization of a nonholonomic robot subject to constraints and disturbances is considered, with the aim of reaching a specific triggering mechanism. The robot under the proposed control framework is driven to a compact set where it is ultimately bounded. The efficiency of the proposed approach is illustrated through a simulated example.
doi_str_mv	10.23919/ECC.2013.6669628
format	Conference Proceeding
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Under the proposed scheme, the control input as well as the next control update time are provided at each triggering instant. Between two consecutive triggering instants, the control trajectory given by the MPC is applied to the plant in an open-loop fashion. This results to less frequent computations while preserving stability and convergence of the closed-loop system. A scenario for the stabilization of a nonholonomic robot subject to constraints and disturbances is considered, with the aim of reaching a specific triggering mechanism. The robot under the proposed control framework is driven to a compact set where it is ultimately bounded. The efficiency of the proposed approach is illustrated through a simulated example.</abstract><pub>EUCA</pub><doi>10.23919/ECC.2013.6669628</doi><tpages>6</tpages></addata></record>
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identifier	ISBN: 9783033039629
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source	IEEE Electronic Library (IEL) Conference Proceedings
subjects	Closed loop systems Constrained uncertain systems Control framework Control trajectory Convergence Non-holonomic robot Nonholonomic systems Robot kinematics Stability analysis Stability and convergence Trajectory Triggering mechanism Ultimately bounded
title	Self-triggered Model Predictive Control for nonholonomic systems
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