Neuro-adaptive dynamic integral sliding mode control design with output differentiation observer for uncertain higher order MIMO nonlinear systems
This paper proposes a practical design method for the robust control of a class of MIMO nonlinear plants operating under model uncertainties and matched disturbances where the only available information for feedback are the outputs of the plant. A neural networks based dynamic integral sliding mod...
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| Main Authors: | , |
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| Format: | Article |
| Language: | English English English |
| Published: |
Elsevier
2017
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| Subjects: | |
| Online Access: | http://irep.iium.edu.my/53663/1/53663_Neuro-adaptive%20dynamic%20integral%20sliding%20mode.pdf http://irep.iium.edu.my/53663/2/53663_Neuro-adaptive%20dynamic%20integral%20sliding%20mode_SCOPUS.pdf http://irep.iium.edu.my/53663/3/53663_Neuro-adaptive%20dynamic%20integral%20sliding%20mode_WOS.pdf http://irep.iium.edu.my/53663/ http://www.sciencedirect.com/science/article/pii/S0925231216314382 |
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| Summary: | This paper proposes a practical design method for the robust control of a class of MIMO nonlinear plants
operating under model uncertainties and matched disturbances where the only available information for
feedback are the outputs of the plant. A neural networks based dynamic integral sliding mode control
(NNDISMC) with output differentiator observer is developed for the considered class. This NNDISMC approach
utilizes the robust output differentiation observer for the higher derivative estimation and neural networks to
estimate the nonlinear functions which are assumed unknown. Having estimated the unknown derivatives and
uncertain functions, an integral manifold based on the estimated states is designed and a control law is
proposed which confirms the sliding mode enforcement across the designed integral manifold from the very
start of the process. The overall robustness of the controller is guaranteed by using the neural networks,
differentiator observer and dynamic integral control law in a closed loop. The closed loop stability analysis is
presented in detail, and the asymptotic convergence of the system states to the equilibrium is confirmed. The
proposed method is very practical and plays a very significant role in the robust control of electromechanical systems, such as robotic manipulators, unmanned air vehicles and underwater vehicles. The simulation results on a robotic manipulator are presented to demonstrate the effectiveness of the proposed method. |
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