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212 Ketter Hall, North Campus, Buffalo, NY 14260 civil.buffalo

212 Ketter Hall, North Campus, Buffalo, NY 14260 www.civil.buffalo.edu Fax: 716 645 3733 Tel: 716 645 2114 x 2400 Control of Structural Vibrations Lecture #7_1 Active Control - Algorithms Instructor: Andrei M. Reinhorn P.Eng. D.Sc. Professor of Structural Engineering.

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212 Ketter Hall, North Campus, Buffalo, NY 14260 civil.buffalo

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  1. 212 Ketter Hall, North Campus, Buffalo, NY 14260 www.civil.buffalo.edu Fax: 716 645 3733 Tel: 716 645 2114 x 2400 Control of Structural Vibrations Lecture #7_1 Active Control - Algorithms Instructor: Andrei M. Reinhorn P.Eng. D.Sc. Professor of Structural Engineering

  2. Issues in Active Control • Control Logic - Algorithms • Control Considerations - Stability, etc. • Control Implementations - Force Generation • Physical Implementations • Full Scale Implementations

  3. Control Algorithms • Method 1: Optimal Control • Method 2: Poles Assignment • Method 3: Instantaneous optimum • Method 4: Independent Modal Space Control • Method 5: Bounded State Control • Method 6: H2 and H Control • Method 7: Sliding Mode Control • Method 8: Fuzzy Logic Control

  4. Control Considerations • Stability - Liapunov Considerations • Controlability • Observability • Spill-Over

  5. Control Implementations • Force Generation • Time Delay • Robustness

  6. Block Diagram of Control

  7. Control Algorithms • Method 1: Optimal Control • Method 2: Poles Assignment • Method 3: Instantaneous optimum • Method 4: Independent Modal Space Control • Method 5: Bounded State Control • Method 6: H2 and H Control • Method 7: Sliding Mode Control • Method 8: Fuzzy Logic Control

  8. Structure Equations Structure’s Equation Control Force Effective Equation with Control

  9. Structure Equations Denote Variables as: Structure’s Equation

  10. State Space Equation 0

  11. Quadratic Performance Index

  12. Optimized Solution • Solutions of the above leads to basic equations to determine control forces u(t):

  13. Closed Loop (Feed Back Loop)

  14. Closed Loop Control • Ricatti Equation

  15. Closed Loop Control

  16. Closed Loop Control For time independent P :

  17. Output Control Computed output Cz(t)

  18. Open-Closed Loop (Feed Back-Feed Forward)

  19. Open-Closed Loop Control • Closed Loop Control Excitation Open Loop Control

  20. Open Loop (Feed Forward)

  21. Open Loop Control • The solution needs the information of loading history and its derivative. Can’t work for earthquake type loading

  22. Active Tendon System

  23. Example of Control

  24. Example’s Parameters

  25. Example’s Equations

  26. Optimization Parameters

  27. SDOF System on Shaking Tableat University at Buffalo (SUNY)

  28. Active Tendon System

  29. Frequency Response Function

  30. Effect of Weighting Matrices

  31. Control Algorithms • Method 1: Optimal Control • Method 2: Poles Assignment • Method 3: Instantaneous optimum • Method 4: Independent Modal Space Control • Method 5: Bounded State Control • Method 6: H2 and H Control • Method 7: Sliding Mode Control • Method 8: Fuzzy Logic Control

  32. Method 2: Poles Assignment Desired eigenvalue for matrix: A+BG

  33. Determining Gain Matrix Determinant equation:

  34. Determining Gain Matrix

  35. Example of Poles Assignment

  36. Example of Poles Assignment

  37. Example of Poles Assignment

  38. Example of Poles Assignment

  39. Example of Poles Assignment

  40. Example of Poles Assignment Displacements at the two floors:

  41. Control Algorithms • Method 1: Optimal Control • Method 2: Poles Assignment • Method 3: Instantaneous optimum • Method 4: Independent Modal Space Control • Method 5: Bounded State Control • Method 6: H2 and H Control • Method 7: Sliding Mode Control • Method 8: Fuzzy Logic Control

  42. Method 3: Instantaneous Optimum

  43. Method 3: Instantaneous Optimum Modal formulation:

  44. Method 3: Instantaneous Optimum

  45. Method 3: Instantaneous Optimum

  46. Instantaneous Closed Loop

  47. Example of Instantaneous Control Data: mi=345.6 ton ki =3,404x105 kN/m 1= 2=2% I=5.79, 17.18, 27.98, 37.82, 46.38, 53.36, 58.53 rad/s md=29.63 ton (=2%W1) cd = 25 ton /m/sec (=7.3%) kd = 957.2 kN/m

  48. Example of Instantaneous Control

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