[1] Z W Cheng, H J Yu. Existing state and development of vibration control technology. Journal of Vibration and Shock, 2009, 28(3): 73-77. (in Chinese)
[2] X J Li, F F Li, J B Ji, et al. A new control technology of shaking table based on the jerk. Advanced Engineering Sciences, 2018(3): 64-72. (in Chinese)
[3] Y G Xin, B H Dou, Y Pei, et al. Application of high frequency electro-hydraulic vibration system. Machine Tool & Hydraulics, 2015, 43(13): 106-107. (in Chinese)
[4] W Wang. Research on the technology of impact vibration based on four-way rotary valve. Zhejiang University, 2016. (in Chinese)
[5] MTS Systems Corporation. 1000 Hz high-cycle fatigue test system, 2015. https://www.mts.com/cs/groups/public/documents/library/dev_002041.pdf.
[6] MTS Systems Corporation. Servovalves, 2015. https://www.mts.com/cs/groups/public/documents/library/mts_006302.pdf.
[7] MOOG Inc. Overview servo valve range, 2019. https://www.moog.it/content/dam/sites/italy/pdf/servovalvole/Moog-Servo-Valve-Overview-en.pdf.
[8] MOOG Inc. D633/D634 series servovalves, 2019. https://www.moog.com/literature/ICD/Moog-Valves-D633_D634-Catalog-en.pdf.
[9] MOOG Inc. D765 series servovalves, 2019. https://www.mylesgroupcompanies.com/moog_pdfs/CDL6563-F%20D765%20Series.pdf.
[10] MOOG Inc. 760 Series servovalves, 2019. https://www.moog.com/literature/ICD/760seriesvalves.pdf.
[11] MOOG Inc. 79 Series servovalves, 2019. https://www.moog.com/literature/ICD/Moog-Valves-79-Series-Catalog-en.pdf.
[12] TEAM Corporation. MANTIS brochure, 2014. http://www.teamcorporation.com/images/brochures/Mantis.pdf.
[13] TEAM Corporation. The CUBE brochure, 2016. http://www.teamcorporation.com/images/brochures/Team_Cube_8.5_x_11.pdf.
[14] TEAM Corporation. Engine simulator brochure, 2014. http://www.teamcorporation.com/images/brochures/Engine-Simulation-Systems.pdf.
[15] G Shen, Y Tang, X Li. Parallel redundantly actuated electro-hydraulic shaking table control system. Beijing: Science Press, 2016: 3-21. (in Chinese)
[16] SERVOTEST Testing Systems Ltd. Vibration MAST systems, 2013. http://www.servotestsystems.com/images/PDFs/ST_brochures/08_Vibration_MAST_tables.pdf.
[17] SERVOTEST Testing Systems Ltd. Company introduction, 2018. http://www.servotestsystems.com/images/PDFs/ST_brochures/Servotest_Company_Introduction.pdf.
[18] IMV Corporation. Dynamic simulation system full lineup catalogue, 2016. http://www.imv-china.cn/catalog_dl/pdf/dss_catalogue.pdf.
[19] M Nakashima, T Nagae, R Enokida, et al. Experiences, accomplishments, lessons, and challenges of E-defense—Tests using world's largest shaking table. Japan Architectural Review, 2018, 1(1): 4-17.
[20] T L Zhang. Design and servo control study of single-axis high-frequency electro-hydraulic shaking table. Zhejiang University, 2018. (in Chinese)
[21] K Wan, P Wang, D Y Zhu. Present situation and the development in electro-hydraulic vibration control system. Electronic Instrumentation Customers, 2012, 19(4): 1-5. (in Chinese)
[22] J W Han, L P Zhang. The development and control technology of multi-DOF shaker. Chinese Hydraulics & Pneumatics, 2014(1): 1-6. (in Chinese)
[23] C J Li. Research on key issues in design of large earthquake simulation shaking table foundation. Southeast University, 2016. (in Chinese)
[24] M Goldfarb, E J Barth, K B Fite, et al. High bandwidth rotary servo valves: US, 7322375B2. 2008-01-29. https://patents.google.com/patent/US7322375B2/en.
[25] P G V Kerckhove, P Ma. Rotary-actuated electro-hydraulic valve: US, 7735517B2. 2010-06-15. https://patents.google.com/patent/US7735517B2/en.
[26] M Ruggeri, P Marani. A new high performance roto-translating valve for fault tolerant applications (No. 2014-01-2403). SAE Technical Paper, 2014.
[27] W Yang. Research on fault tolerance principle and error correction method for fluid drive and control application system. University of Electronic Science and Technology of China, 2012. (in Chinese)
[28] P Y Li, T R Chase. Pulse width modulated fluidic valve: US, 8286939B2. 2012-10-16. https://patents.google.com/patent/US8286939B2/en.
[29] M Wang. CFD analysis, sensing and control of a rotary pulse width modulating valve to enable a virtually variable displacement pump. USA: University of Minnesota, 2017.
[30] M Pan, N Johnston, J Robertson, et al. Experimental investigation of a switched inertance hydraulic system with a high-speed rotary valve. Journal of Dynamic Systems Measurement & Control, 2015, 137(12): 121003.
[31] J Ruan, S Li, X Pei, et al. Electrohydraulic vibration exciter controlled by 2D valve. Journal of Mechanical Engineering, 2009, 45(11): 131-138. (in Chinese)
[32] M J Lu. The research of the controller for the single-axis high frequency electro-hydraulic shaking table. Zhejiang University of Technology, 2012. (in Chinese)
[33] G F Gong, D Han, Y Liu, et al. An electro-hydraulic exciter: CN, 102734279B. 2014-12-10. http://pro.soopat.com/Chinese/Patent?SQH=201210218096&lx=FMSQ#. (in Chinese)
[34] D Han, G F Gong, Y Liu, et al. New electro-hydraulic exciter based on different spools. Journal of Zhejiang University (Engineering Science), 2014, 48(5): 757-763. (in Chinese)
[35] J F Li, Z B Xu, J L Wang. Magneto-strictive driven electro-hydraulic exciter: CN, 103075395A. 2013-05-01. http://pro.soopat.com/Chinese/Patent?SQH=201310037249&lx=FMZL#. (in Chinese)
[36] G Toet. Device for compacting a granular mass such as concrete cement: US, 9211663B2. 2015-12-15. https://patents.google.com/patent/US9211663B2/en.
[37] A Kleibl, C Heichel. Vibration exciter: US, 20140305234A1. 2014-10-16. https://patents.google.com/patent/US20140305234A1/en.
[38] K Kobayashi, I Kono, T Kondo, et al. Vibration exciter: US, 20180031445A1. 2018-02-01. https://patents.google.com/patent/US20180031445A1/en.
[39] D D Hou, D Cheng, L P Qin, et al. Electro-hydraulic acceleration control strategy based on three states controller. Chinese Hydraulics & Pneumatics, 2018(5): 47-53. (in Chinese)
[40] B Liu, J Zhang, X C Dou, et al. Research on three state controller policy of hydraulic vibration table. Machine Tool & Hydraulics, 2014, 42(19): 136-140. (in Chinese)
[41] P Righettini, R Strada, S Valilou, et al. Nonlinear model of a servo-hydraulic shaking table with dynamic model of effective bulk modulus. Mechanical Systems & Signal Processing, 2018, 110: 248-259.
[42] W Kim, D Won, D Shin, et al. Output feedback nonlinear control for electro-hydraulic systems. Mechatronics, 2012, 22(6): 766-777.
[43] S K Wang, J Z Wang, W Xie, et al. Development of hydraulically driven shaking table for damping experiments on shock absorbers. Mechatronics, 2014, 24(8): 1132-1143.
[44] N Nakata. Acceleration trajectory tracking control for earthquake simulators. Engineering Structures, 2010, 32(8): 2229-2236.
[45] A Klimchik, D Chablat, A Pashkevich. Stiffness modeling for perfect and non-perfect parallel manipulators under internal and external loadings. Mechanism & Machine Theory, 2014, 79(79): 1-28.
[46] W Wei, Z D Yang, J W Han. Decoupling control of hyper-redundant shaking table based on dynamic coupling model. Journal of South China University of Technology (Natural Science Edition), 2014, 42(4): 124-130. (in Chinese)
[47] G Shen, Z C Zhu, L Zhang, et al. Adaptive feed-forward compensation for hybrid control with acceleration time waveform replication on electro-hydraulic shaking table. Control Engineering Practice, 2013, 21(8): 1128-1142.
[48] J J Yao, Z S Wan, Y Fu. Acceleration harmonic estimation in a hydraulic shaking table using water cycle algorithm. Shock and Vibration, 2018, 2018(6): 1-12.
[49] S D Bruyne, H V D Auweraer, B Peeters, et al. Model based control of a multi-axis hydraulic shaker using experimental modal analysis. IFAC Proceedings Volumes, 2012, 45(16): 524-528.
[50] K P S Rana. Fuzzy control of an electrodynamic shaker for automotive and aerospace vibration testing. Expert Systems with Applications, 2011, 38(9): 11335-11346.
[51] M Stehman, N Nakata. Direct acceleration feedback control of shake tables with force stabilization. Journal of Earthquake Engineering, 2013, 17(5): 736-749.
[52] G Shen, Z C Zhu, X Li, et al. Experimental evaluation of acceleration waveform replication on electrohydraulic shaking tables: A review. International Journal of Advanced Robotic Systems, 2016, 13(5): 1-25.
[53] L Zhang, D Cong, Z Yang, et al. Optimal design and hybrid control for the electro-hydraulic dual-shaking table system. Applied Sciences, 2016, 6(8): 220.
[54] Y Tang, G Shen, Z C Zhu, et al. Time waveform replication for electro-hydraulic shaking table incorporating off-line iterative learning control and modified internal model control. Proceedings of the Institution of Mechanical Engineers Part I Journal of Systems & Control Engineering, 2014, 228(9): 722-733.
[55] X Yan, Y Wang, B L Niu, et al. A displacement and acceleration hybrid control technology to improve high-frequency characteristics in hydraulic vibration system. Machine Tool & Hydraulics, 2015, 43(20): 84-87. (in Chinese)
[56] Y Liu, G F Gong, H Y Yang, et al. Mechanism of electro-hydraulic exciter for new tamping device. Journal of Central South University, 2014, 21(2): 511-520.
[57] Y Liu, G F Gong, C Q Min. Present status and prospect of tamping device exciting technology. Journal of Mechanical Engineering, 2013, 49(16): 138-145. (in Chinese)
[58] J Ruan, R T Burton. An electrohydraulic vibration exciter using a two-dimensional valve. Journal of Systems and Control Engineering, 2009, 223(2): 135-147.
[59] W R Li, J Ruan, Y Ren. Vibration waveform research on electro-hydraulic exciter of differential cylinder controlled by 2D valve. Transactions of the Chinese Society for Agricultural Machinery, 2013, 44(10): 266-271. (in Chinese)
[60] W R Li, H S Hu, J Z Wu. Research on the full-band vibration waveform of high frequency electric hydraulic vibrostand. Value Engineering, 2016, 35(4): 131-133. (in Chinese)
[61] Y Ren, J Ruan. Theoretical and experimental investigations of vibration waveforms excited by an electro-hydraulic type exciter for fatigue with a two-dimensional rotary valve. Mechatronics, 2016, 33: 161-172.
[62] Y Ren, J Ruan, W A Jia. Bias control strategy for electro-hydraulic vibration exciter with two-dimensional valve. Journal of Xi'an Jiaotong University, 2010, 44(9): 82-86. (in Chinese)
[63] H Q Shao, J Ruan, S Li, et al. High-frequency electro-hydraulic vibration system controller based on DSP. Journal of Mechanical & Electrical Engineering, 2012, 29(1): 66-69. (in Chinese)
[64] D Han, G F Gong, Y Liu, et al. Waveform saturation of electro-hydraulic excitation technology. Transactions of the Chinese Society for Agricultural Machinery, 2014, 45(2): 334-339. (in Chinese)
[65] D Han, G F Gong, H Y Yang, et al. Waveforms analysis and optimization of new electro-hydraulic excitation technology. Journal of Central South University, 2014, 21(8): 3098-3106.
[66] H Wang, G F Gong, H B Zhou, et al. Research on vibration waveform of electro-hydraulic exciter with rotary valve based on different valve port shapes. Journal of Mechanical Engineering, 2015, 51(24): 146-152. (in Chinese)
[67] H Wang, G F Gong, H B Zhou, et al. A rotary valve controlled electro-hydraulic vibration exciter. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2015, 230(19): 3397-3407.
[68] Y Liu, S K Cheng, G F Gong. Structure characteristics of valve port in the rotation-spool-type electro-hydraulic vibrator. Journal of Vibration & Control, 2015, 23(13): 2179-2189.
[69] Z D Yang. Research on control technologies of simulation of vibration environment using hydraulic vibration table. Harbin Institute of Technology, 2009. (in Chinese)
[70] Spectral Dynamics, Inc. JAGUAR shaker control and analysis system datasheet, 2017. http://www.spectraldynamics.com/images/docs/Jaguar/Brochures/DataSheet_jagHWds_012808.pdf.
[71] Data Physics Corporation. SIGNALSTAR family brochure, 2017. http://cdn2.hubspot.net/hubfs/409629/eBooks/Data_Physics/SignalStar_Controllers-Family_Brochure-Data_Physics_Corporation.pdf.
[72] ECON Technologies. MIMO vibration controller, 2019. http://www.econ-group.com.cn/ch/productView.asp?id=78&num=1&id2=101. (in Chinese)
[73] DynaTronic Corporation. MIMO vibration control system, 2019. http://www.dtc-solutions.cn/product/7162.html. (in Chinese)
[74] A R Plummer. Model-based motion control for multi-axis servo-hydraulic shaking tables. Control Engineering Practice, 2016, 53: 109-122.
[75] S Thenozhi, W Yu, R Garrido. A novel numerical integrator for velocity and position estimation. Transactions of the Institute of Measurement & Control, 2013, 35(6): 824-833.
[76] N Nakata. A multi-purpose earthquake simulator and a flexible development platform for actuator controller design. Journal of Vibration & Control, 2012, 18(18): 1552-1560.
[77] G Shen, X Li, Z C Zhu, et al. Acceleration tracking control combining adaptive control and off-line compensators for six-degree-of-freedom electro-hydraulic shaking tables. ISA Transactions, 2017, 70: 322.
[78] X Yan, B L Niu, Q S Li. Multi-dimensional waveform reproduction control system design and development. Journal of Vibration and Shock, 2007, 26(9): 162-164. (in Chinese)
[79] J C Xu. Research and implementation of random vibration controller based on DSP. Yangzhou University, 2015. (in Chinese)
[80] Y Shu, Q Song, Q S Li, et al. Design of digital servo controller for electro-hydraulic shaking table based on FPGA. Machine Tool & Hydraulics, 2013, 41(15): 148-150. (in Chinese)
[81] T Deng, X Yan, et al. Application of embedded controller in vibration test of earthquake-simulation on centrifuge. Computer Measurement & Control, 2016, 24(3): 127-128. (in Chinese)
[82] X G Feng, J Y Zhang, P M Xu, et al. PFC optimization control strategy research on hydraulic vibration servo system. Journal of Vibration Engineering, 2017, 30(3): 389-396. (in Chinese)
[83] Q L Luan, Z W Cheng, H N He. Control strategy for a hydraulic shaker controlled with a 3-stage electro-hydraulic servo valve. Journal of Vibration and Shock, 2014, 33(24): 138-143. (in Chinese)
[84] X B Ma, Z W Cheng, Y G Zhao, et al. Three-axis vibration control based on drive spectrum modified iterative control algorithm. Journal of Vibration and Shock, 2018, 37(3): 85-90. (in Chinese)
