International Journal of Control, Vol.83, No.8, 1701-1709, 2010
Decentralised energy-based hybrid control for the multi-RTAC system
The concept of decentralised energy-based hybrid control involves hybrid dynamic subcontrollers with discontinuous states that individually control each subsystem of a large interconnected dynamical system. Specifically, each subcontroller accumulates the emulated energy and when the states of the subcontroller coincide with a high emulated energy level, then we can reset these states to remove the emulated energy so that the emulated energy is not returned to the subsystem. The real physical energy of each subsystem in this case is constantly dissipated through the motion of the actuators due to the subcontroller state resettings. In this article, we experimentally implement the decentralised energy-based hybrid control framework on the multi-rotational/translational proof mass actuator (RTAC) system. We discuss the hardware used and the experimental testbed involving three RTAC carts connected by the springs. This testbed presents a unique experimental platform for studying benchmark problems in decentralised nonlinear control design. Finally, we present experimental results using decentralised energy-based hybrid controllers.
Keywords:rotational;translational proof-mass actuator;hybrid control;impulsive systems;Euler-Lagrange systems;dynamic compensation