NUMERICAL SIMULATION AND BEHAVIOUR ANALYSIS OF A 3D 6-DOF SEISMIC SIMULATION SHAKING TABLE SYSTEM, 9-15.

Binbin Li, Juanli Zhao, Bo Liu, and Fan Xu

References

1. [1] D.P. Newell, M.K. Sain, H.L. Dai, et al., Nonlinear mod-eling and control of a hydraulic seismic simulator, Proceed-ings of the 1995 American Control Conference, vol. 1, 1995,801–805.
2. [2] J.S. Shortreed, F. Seible, and G. Benzoni, Simulation is-sues with a real-time, full-scale seismic testing system,Journal of Earthquake Engineering, 6(Sp.Iss. S1), 2002,185–201.
3. [3] J.G. Chase, N.H. Hudson, J. Lin, et al., Nonlinear shaketable identification and control for near - field earthquaketesting, Journal of Earthquake Engineering, 9(4), 2005,461–482.
4. [4] O. Ozcelik, J.E. Luco, J.P. Conte et al., Experimental char-acterization, modeling and identification of the NEES-UCSDshake table mechanical system, Earthquake Engineering &Structural Dynamics, 37(2), 2008, 243–264.
5. [5] A.R. Plummer, A detailed dynamic model of a six-axis shakingtable, Journal of Earthquake Engineering, 12(4), 2008, 631–662.
6. [6] X. Yan, C. Zhu, and Y. Hu, Building model study of the sixdegree of freedom shaking table, Machine Tool & Hydraulics,11,2006, 98–100+125.
7. [7] J. Wang, B.-L. Niu, and S.-q. Hu, The electro-hydraulic shakermodeling and applications of the simulation model, Journal ofSystem Simulation, 20(suppl.), 2008, 258–264.
8. [8] Q. Wang, J. Wang, F. Jin, and C. Zhang, Real-time dy-namic hybrid simulation testing based on virtual shaking-table,Earthquake Engineering and Engineering Dynamics, 29(6),2009, 25–32.
9. [9] W. Kim, D. Won, D. Shin, and C.C. Chung, Output feedbacknonlinear control for electro-hydraulic systems, Mechatronics,22(6), 2012, 766–777.
10. [10] A. R. Plummer, “Model-based motion control for multi-axisservo hydraulic shaking tables,” Control Engineering Practice,53, 2016, 109–122.
11. [11] K. Seki, M. Iwasaki, M. Kawafuku, H. Hirai, and K. Yasuda,Adaptive compensation for reaction force with frequency varia-tion in shaking table systems, IEEE Transactions on IndustrialElectronics, 56(10), 2009, 3864–3871.
12. [12] H. Chen, J. Gao, and R. Lu, A time-delay-dependent quantiza-tion feedback control approach for networked control system,Mechatronic Systems and Control, 45(4), 2017, 172–180.
13. [13] Y. Shang and F. Gao, Global adaptive stabilization of non-linearly parameterized time-delay systems by state feedback,Mechatronic Systems and Control, 44(4), 2016, 153–160.
14. [14] B.-B. Liu and W. Zhou, On adaptive iterative learning controlalgorithm for discrete-time systems with parametric uncer-tainties subject to second-order internal model, MechatronicSystems and Control, 43(4), 2015, 183–190.
15. [15] Y. Dozono, T. Horiuchi, and H. Katsumata, Improvement ofshaking-table control by real-time compensation of the reactionforce caused by a non-linear specimen, ASME Pressure VesselsPiping Div Publ PVP, 428(1), 2001, 247–255.
16. [16] Y. Shen, Y. Yang,and T. Li, The design of dynamic simulationsystem on earthquake surroundings. ACADJ XJTU, 15(1),2003, 102–106.
17. [17] X. Li, Research on simulation control method of digital shakingtable (Xi’an:Xi’an University of Architecture and Technology,2014).

Important Links:

• Abstract
• DOI: 10.2316/J.2022.201-0211
• From Journal (201) Mechatronic Systems and Control - 2022

Go Back