1. Spring semester 2006 ESE 601: Hybrid Systems Review material on continuous systems I

2. References Kwakernaak, H. and Sivan, R. “Modern signal and systems”, Prentice Hall, 1991. Brogan, W., “Modern control theory”, Prentice Hall Int’l, 1991. Textbooks or lecture notes on linear systems or systems theory.

3. Contents Modeling with differential equations Taxonomy of systems Solution to linear ODEs General solution concept Simulation and numerical methods State space representation Stability Reachability

4. Physical systems Resistor Inductor Capacitor Damper Mass Spring

5. Electric circuit V + I(t) 1 0 t V(t) t L L

6. More electric circuit V I(t) + R L C

7. A pendulum Mg r

8. Contents Modeling with differential equations Taxonomy of systems Solution to linear ODEs General solution concept Simulation and numerical methods State space representation Stability Reachability

9. Linear vs nonlinear Linear systems: if the set of solutions is closed under linear operation, i.e. scaling and addition. All the examples are linear systems, except for the pendulum.

10. Time invariant vs time varying Time invariant: the set of solutions is closed under time shifting. Time varying: the set of solutions is not closed under time shifting.

11. Autonomous vs non-autonomous Autonomous systems: given the past of the signals, the future is already fixed. Non-autonomous systems: there is possibility for input, non-determinism.

12. Contents Modeling with differential equations Taxonomy of systems Solution to linear ODEs General solution concept Simulation and numerical methods State space representation Stability Reachability

13. Techniques for autonomous systems

14. Techniques for non-autonomous systems

15. Example: 1 u(t) t 1 y(t) t

16. Contents Modeling with differential equations Taxonomy of systems Solution to linear ODEs General solution concepts Simulation and numerical methods State space representation Stability Reachability

17. Solution concepts

18. Example of weak solution

19. Contents Modeling with differential equations Taxonomy of systems Solution to linear ODEs General solution concepts Simulation and numerical methods State space representation Stability Reachability

20. Simulation methods x(t) x[1] x[2] x[3]

21. Simulation methods

22. Contents Modeling with differential equations Taxonomy of systems Solution to linear ODEs General solution concepts Simulation and numerical methods State space representation Stability Reachability

23. State space representation One of the most important representations of linear time invariant systems.

24. State space representation

25. Solution to state space rep. Solution:

26. Exact discretization of autonomous systems x(t) x[1] x[2] x[3] t

27. Contents Modeling with differential equations Taxonomy of systems Solution to linear ODEs Simulation and numerical methods State space representation Stability Reachability Discrete time systems

28. Stability of LTI systems

29. Stability of nonlinear systems pp stable

30. Stability of nonlinear systems p Asymptotically stable

31. Lyapunov functions

32. Contents Modeling with differential equations Taxonomy of systems Solution to linear ODEs General solution concept Simulation and numerical methods State space representation Stability Reachability

34. Reachability of linear systems