Real time optimization by extremum seeking control

An up-close look at the theory behind and application of extremum seeking Originally developed as a method of adaptive control for hard-to-model systems, extremum seeking solves some of the same problems as today's neural network techniques, but in a more rigorous and practical way. Following the resurgence in popularity of extremum-seeking control in aerospace and automotive engineering, Real-Time Optimization by Extremum-Seeking Control presents the theoretical foundations and selected applications of this method of real-time optimization. Written by authorities in the field and pioneers in adaptive nonlinear control systems, this book presents both significant theoretic value and important practical potential. Filled with in-depth insight and expert advice, Real-Time Optimization by Extremum-Seeking Control: * Develops optimization theory from the points of dynamic feedback and adaptation * Builds a solid bridge between the classical optimization theory and modern feedback and adaptation techniques * Provides a collection of useful tools for problems in this complex area * Presents numerous applications of this powerful methodology * Demonstrates the immense potential of this methodology for future theory development and applications Real-Time Optimization by Extremum-Seeking Control is an important resource for both students and professionals in all areas of engineering-electrical, mechanical, aerospace, chemical, biomedical-and is also a valuable reference for practicing control engineers.

Preface. I: THEORY. 1. SISO Scheme and Linear Analysis. 2. Multiparameter Extremum Seeking. 3. Slope Seeking. 4. Discrete Time Extremum Seeking. 5. Nonlinear Analysis. 6. Limit Cycle Minimization. II: APPLICATIONS. 7. Antilock Braking. 8. Bioreactors. 9. Formation Flight. 10.Combustion Instabilities. 11. Compressor Instabilities: Part I. 12. Compressor Instabilities: Part II. Appendix A: Continuous Time Lemmas. Appendix B: Discrete Time Lemas. Appendix C: Aircraft Dynamics in Close Formation Flight. Appendix D: Derivation of (11.8) and (11.10). Appendix E: Derivation of the Critical Slopes. Appendix F: Proof of Lemma 11.1. Bibliography. Index.