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Linear Active Disturbance Rejection Control for Double-Pendulum Overhead Cranes

Lin Chai, Qihang Guo, Huikang Liu, Mingbo Ding

2021IEEE Access25 citationsDOIOpen Access PDF

Abstract

Because of the complexity, non-linearity, and under-actuated features of double pendulum overhead cranes, a control method based on linear active disturbance rejection control (LADRC) and differential flatness theory is proposed to realize accurate trolley positioning and effective swing eliminating. Specifically, in order to simplify the system model, we introduce the differential flatness theory to construct system output. Based on this method, the uncertainty and system external disturbance become total disturbance. The control method of the crane is designed according to LADRC. Then, we use the bird swarm algorithm (BSA) to optimize controller's parameters. Finally, the double-pendulum crane control method based on the LADRC can better accomplish the crane's anti-swing and location in the real environment according to simulation and experimental results, which confirms its effectiveness and robustness in existing system.

Topics & Concepts

Control theory (sociology)Active disturbance rejection controlOverhead craneFlatness (cosmology)Robustness (evolution)Double pendulumComputer scienceSwingControl engineeringRobust controlDisturbance (geology)Control systemDSPACEInverted pendulumEngineeringNonlinear systemState observerControl (management)AlgorithmArtificial intelligenceBiochemistryGeneElectrical engineeringQuantum mechanicsPaleontologyPhysicsStructural engineeringChemistryMechanical engineeringBiologyCosmologyDynamics and Control of Mechanical SystemsHydraulic and Pneumatic SystemsVehicle Dynamics and Control Systems