A NEW HYBRID OPTIMAL-BASED ROBUST AND PROPORTIONAL–INTEGRAL– DERIVATIVE CONTROL FOR VIBRATION CONTROL OF A SEISMIC-EXCITED STRUCTURES

Seyed M.H. Baygi,∗ Ali Karsaz,∗ and Javad Faraji∗

References

1. [1] J.T.P. Yao, Concept of structural control, Journal of the Structural Division, 98(7), 1972, 1567–1574. 211
2. [2] C. Roberts and D. Ewins, Multi-axis vibration testing of an aerodynamically excited structure, Journal of Vibration and Control, 24(2), 2016, 427–437. doi: 10.1177/1077546316642064.
3. [3] X. Dong, Z. Peng, and G. Meng, Vibration control of a lead zirconate titanate structure considering controller– structure interactions, Journal of Low Frequency Noise, Vibration and Active Control, 37(4), 2018, 1201–1218. doi: 10.1177/1461348418795372.
4. [4] T.K. Datta, A state-of-the-art review on active control of structures, ISET Journal of Earthquake Technology, 40, 2003, 1–17.
5. [5] G.W. Housner, et al., Structural control: Past, present and future, Journal of Engineering Mechanics, 123, 1997, 897–974.
6. [6] S. Pourzeynali, H. Lavasani, and A. Modarayi, Active control of high rise building structures using fuzzy logic and genetic algorithms, Engineering Structures, 29(3), 2007, 346–357.
7. [7] A. Bathaei, S. Zahrai, and M. Ramezani, Semi-active seismic control of an 11-DOF building model with TMD+MR damper using type-1 and -2 fuzzy algorithms, Journal of Vibration and Control, 24(13), 2017, 2938–2953. doi: 10.1177/1077546317696369.
8. [8] Y. Eljajeh and M. Petkovski, Self-adaptive approach for optimisation of passive control systems for seismic resistant buildings, Bulletin of Earthquake Engineering, 16(7), 2018, 3171–3194. doi: 10.1007/s10518-018-0309-9.
9. [9] T. Manjunath and B. Bandyopadhyay, Vibration control of a smart structure using periodic output feedback technique, Asian Journal of Control, 6(1), 2008, 74–87. doi: 10.1111/j.1934-6093.2004.tb00185.x.
10. [10] P. Bagheri, A. Ramirez-Serrano, and J.K. Pieper, Adaptive nonlinear robust control of a novel unconventional unmanned aerial vehicle, Control and Intelligent Systems, 43(1), 2015.
11. [11] C. Li and J. Mao, Adaptive vibration control on six degree-of-freedom magnetostrictive smart structure, Materials Science Forum, 546-549, 2007, 2199–2204. doi: 10.4028/www.scientific.net/msf.546-549.2199.
12. [12] C. Zhou, X. Zhao, and Q. Yu, Adaptive robust control for active suspension system using T–S fuzzy model approach, Mechatron Systems Control (Former Control Intelligent Systems), 46(2), 2018, 46–54.
13. [13] E. Glbahe and M. elik, Active vibration control of a smart beam by a tuner-based PID controller, Journal of Low Frequency Noise, Vibration and Active Control, 37(4), 2018, 1125–1133. doi: 10.1177/1461348418782169.
14. [14] K. Park and S. Ok, Modal-space reference-model-tracking fuzzy control of earthquake excited structures, Journal of Sound and Vibration, 334, 2015, 136–150.
15. [15] F. Shirazi, J. Mohammadpour, K. Grigoriadis, and G. Song, Identification and control of an MR damper with stiction effect and its application in structural vibration mitigation, IEEE Transactions on Control Systems Technology, 20(5), 2012, 1285–1301.
16. [16] H. Bui, C. Nguyen, N. Vu, and C. Nguyen, General design method of hedge-algebras-based fuzzy controllers and an application for structural active control, Applied Intelligence, 43(2), 2015, 251–275.
17. [17] Y. Chen, W. Zhang, and H. Gao, Finite frequency control for building under earthquake excitation, Mechatronics, 20(1), 2010, 128–142.
18. [18] S.Pourzeynali, S. Salimi, H. Eimani Kalesar, Robust multiobjective optimization design of TMD control device to reduce tall building responses againstearthquake excitations using genetic algorithms, Scientia Iranica, Transactions A: Civil Engineering, 20, 2013, 207–221.
19. [19] A. Heidari, S. Etedali, and M. Javaheri-Tafti, A hybrid LQRPID control design for seismic control of buildings equipped with ATMD, Frontiers of Structural and Civil Engineering, 12(1), 2017, 44–57.
20. [20] S. Etedali, A. Zamani, and S. Tavakoli, A GBMO-based PI λ D μ controller for vibration mitigation of seismic-excited structures, Automation in Construction, 87, 2018, 1–12. doi: 10.1016/j.autcon.2017.12.005.
21. [21] R. Mitchell, Y. Kim, T. El-Korchi, and Y. Cha, Wavelet-neurofuzzy control of hybrid building-active tuned mass damper system under seismic excitations, Journal of Vibration and Control, 19(12), 2012, 1881–1894.
22. [22] M. Uz and M. Hadi, Optimal design of semi active control for adjacent buildings connected by MR damper based on integrated fuzzy logic and multi-objective genetic algorithm, Engineering Structures, 69, 2014, 135–148.
23. [23] A. Ahlawat and A. Ramaswamy, Multiobjective optimal absorber system for torsionally coupled seismically excited structures, Engineering Structures, 25(7), 2003, 941–950.
24. [24] S. Thenozhi and W. Yu, Active vibration control of building structures using fuzzy proportional-derivative/proportionalintegral-derivative control, Journal of Vibration and Control, 21(12), 2013, 2340–2359. doi: 10.1177/1077546313509127.
25. [25] Y. Zhao and E. Collins, Fuzzy PI control design for an industrial weigh belt feeder, IEEE Transactions on Fuzzy Systems, 11(3), 2003, 311–319.
26. [26] M. Brodersen, A. Bjrke, and J. Hgsberg, Active tuned mass damper for damping of offshore wind turbine vibrations, Wind Energy, 20(5), 2016, 783–796. doi: 10.1002/we.2063.
27. [27] Y. Taskin, I. Yuksek, and N. Yagiz, Vibration control of vehicles with active tuned mass damper, Journal of Vibroengineering, 19(5), 2017, 3533–3541. doi: 10.21595/jve.2017.18138.
28. [28] J. Love and C. Lee, Nonlinear series-type tuned mass dampertuned sloshing damper for improved structural control, Journal of Vibration and Acoustics, 141(2), 2018, 021006. doi: 10.1115/1.4041513.
29. [29] A. Zamani, S. Tavakoli, and S. Etedali, Fractional order PID control design for semi-active control of smart base-isolated structures: A multi-objective cuckoo search approach, ISA Transactions, 67, 2017, 222–232. doi: 10.1016/j.isatra.2017.01.012.
30. [30] S. Hadad Baygi and A. Karsaz, A hybrid optimal PID-LQR control of structural system: A case study of salp swarm optimization, 2018 3rd Conference on Swarm Intelligence and Evolutionary Computation (CSIEC), Kerman, 2018, 1–6.
31. [31] S. Mirjalili and A. Lewis, The whale optimization algorithm, Advances in Engineering Software, 95, 2016, 51–67.
32. [32] A. Zamani, S. Tavakoli, S. Etedali, and J. Sadeghi, Online tuning of fractional order fuzzy PID controller in smart seismic isolated structures, Bulletin of Earthquake Engineering, 16(7), 2017, 3153–3170. doi: 10.1007/s10518-017-0294-4.
33. [33] F. Lin, Robust Control Design: An Optimal Control Approach (John Wiley & Sons, West Sussex, England, 2007).
34. [34] M.L. James, G.M. Smith, J.C. Wolford, and P.W. Whaley, Vibration of Mechanical and Structural Systems, 2nd ed. (New York, NY: Harper Collins College Publishers, 1994), 432–435.
35. [35] MATLAB (Natick, MA: The Math Works. Inc 2000).
36. [36] S.M.H. Baygi, A. Karsaz, and A. Elahi, A hybrid optimal PIDfuzzy control design for seismic exited structural system against earthquake: a salp swarm algorithm. In 2018 6th Iranian Joint Congress on Fuzzy and Intelligent Systems (CFIS) IEEE, 2018, pp. 220–225.

Important Links:

• Abstract
• DOI: 10.2316/J.2021.201-0082
• From Journal (201) Mechatronic Systems and Control - 2021

Go Back