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Neural-Network Control of a Stand-Alone Tall Building-Like Structure With an Eccentric Load: An Experimental Investigation

Hejia Gao, Wei He, Liang Zhang, Changyin Sun

2020IEEE Transactions on Cybernetics22 citationsDOI

Abstract

This article develops a finite-dimensional dynamic model to describe a stand-alone tall building-like structure with an eccentric load by using the assumed mode method (AMM). To compensate for the dynamic uncertainties, a new neural-network (NN) control strategy is designed to suppress vibrations of the tall buildings. The output constraint on the angle of the pendulum is also considered, and such an angle can be ensured within the safety limit by incorporating a barrier Lyapunov function. The semiglobally uniform ultimate boundness (SGUUB) of the closed-loop system is proved via Lyapunov's stability. The simulation results reveal that the new NN strategy can effectively realize vibration suppression in the flexible beam and pendulum. The effectiveness of the new NN approach is further verified through the experiments on the Quanser smart structure.

Topics & Concepts

Control theory (sociology)Lyapunov functionArtificial neural networkVibrationComputer scienceInverted pendulumConstraint (computer-aided design)Beam (structure)Vibration controlPendulumStability (learning theory)Lyapunov stabilityLimit (mathematics)Control (management)MathematicsStructural engineeringEngineeringPhysicsNonlinear systemMathematical analysisArtificial intelligenceGeometryMechanical engineeringMachine learningQuantum mechanicsVibration Control and Rheological FluidsStructural Health Monitoring TechniquesVibration and Dynamic Analysis
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