Model-Free Stabilization by Extremum Seeking [electronic resource] /
by Alexander Scheinker, Miroslav Krstić.
- 1st ed. 2017.
- IX, 127 p. 46 illus., 33 illus. in color. online resource.
- SpringerBriefs in Control, Automation and Robotics, 2192-6794 .
- SpringerBriefs in Control, Automation and Robotics, .
Introduction -- Weak Limit Averaging for Studying the Dynamics of Extremum-Seeking-Stabilized Systems -- Minimization of Lyapunov Functions -- Control Affine Systems -- Non-C2 Extremum Seeking -- Bounded Extremum Seeking -- Extremum Seeking for Stabilization of Systems Not Affine in Control -- General Choice of Extremum-Seeking Dithers -- Application Study: Particle Accelerator Tuning.
With this brief, the authors present algorithms for model-free stabilization of unstable dynamic systems. An extremum-seeking algorithm assigns the role of a cost function to the dynamic system’s control Lyapunov function (clf) aiming at its minimization. The minimization of the clf drives the clf to zero and achieves asymptotic stabilization. This approach does not rely on, or require knowledge of, the system model. Instead, it employs periodic perturbation signals, along with the clf. The same effect is achieved as by using clf-based feedback laws that profit from modeling knowledge, but in a time-average sense. Rather than use integrals of the systems vector field, we employ Lie-bracket-based (i.e., derivative-based) averaging. The brief contains numerous examples and applications, including examples with unknown control directions and experiments with charged particle accelerators. It is intended for theoretical control engineers and mathematicians, and practitioners working in various industrial areas and in robotics.
9783319507903
10.1007/978-3-319-50790-3 doi
Control engineering. System theory. Control theory. Mathematical optimization. Calculus of variations. Particle accelerators. Artificial intelligence. Control and Systems Theory. Systems Theory, Control . Calculus of Variations and Optimization. Accelerator Physics. Artificial Intelligence.