access icon free Boundary control of a flexible crane system in two-dimensional space

© The Institution of Engineering and Technology
Received 16/11/2016, Accepted 28/04/2017, Revised 29/03/2017, Published 04/05/2017

A flexible crane system with vibrating and varying cable is investigated in two-dimensional space. Two partial differential equations and four ordinary differential equations derived by the Hamilton's principle are used to describe the dynamics of the flexible crane system. The dynamic model of the crane system considers the variation of the tension of the cable. Boundary control design is given to suppress vibrations of the flexible crane system. The Lyapunov's direct method is employed to prove the uniform ultimate boundedness of the states of the cable system. The effectiveness and performance of the proposed control schemes are depicted via numerical simulations.

Inspec keywords: numerical analysis; cranes; vibration control; partial differential equations

Other keywords: flexible crane system; varying cable; two-dimensional space; partial differential equations; numerical simulations; boundary control; vibrations suppression; boundary control design; vibrating cable; ordinary differential equations

Subjects: Mechanical variables control; Differential equations (numerical analysis); Numerical analysis; Materials handling equipment; Control applications to materials handling; Vibrations and shock waves (mechanical engineering); Control technology and theory (production)

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