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Neural network based feedback linearization control of a servo-hydraulic vehicle suspension system. (English) Zbl 1221.93088
Summary: This paper presents the design of a Neural Network Feedback Based Linearization (NNFBL) controller for a two Degree-Of-Freedom (DOF), quarter-car, servo-hydraulic vehicle suspension system. The main objective of the direct adaptive NNFBL controller is to improve the system’s ride comfort and handling quality. A feedforward, Multi-Layer Perceptron (MLP) Neural Network (NN) model that is well suited for control by discrete Input-Output Linearization (NNIOL) is developed using input-output data sets obtained from mathematical model simulation. The NN model is trained using the Levenberg-Marquardt optimization algorithm. The proposed controller is compared with a constant-gain PID controller (based on the Ziegler-Nichols tuning method) during suspension travel setpoint tracking in the presence of deterministic road disturbance. Simulation results demonstrate the superior performance of the proposed direct adaptive NNFBL controller over the generic PID controller in rejecting the deterministic road disturbance. This superior performance is achieved at a much lower control cost within the stipulated constraints.
MSC:
93B52Feedback control
93C95Applications of control theory
93B18Linearizability of systems
93C40Adaptive control systems
92B20General theory of neural networks (mathematical biology)