[1] Zhijiang ZENG, Xue LI, Songmin ZHOU et al. SWIR focal plane array cooled assembly of Tianwen-1 mineralogical spectrometer. Infrared and Laser Engineering, 52, 20230005(2023).

[2] S CHAHIRA. Estimate of the effect of micro-vibration on the performance of the Algerian satellite (Alsat-1B) imager. Optics and Laser Technology, 96, 147-152(2017).

[3] [3] LIAO Jianhong. Analysis of vibration sensitivity thermal time constant of fourchannel ultrastable cavity f Yb optical clock [D]. Wuhan: Innovation Academy f Precision Measurement Science Technology, Chinese Academy of Sciences, 2022. (in Chinese)

[4] A VEPRIK, V I BABITSKY, N PUNDAK et al. Vibration control of linear split Stirling cryogenic cooler for airborne infrared application. Shock and Vibration, 7, 363-379(2000).

[5] [5] VEPRIK A, NACHMAN I, PUNDAK N. Dynamically Counterbalanced Singlepiston Linear Compress of a Cryogenic Cooler [M]Ross R G. Cryocoolers 13. Boston, MA: Springer, 2005: 241250.

[6] [6] VEPRIK A, ZECHTZER S, PUNDAK N, et al. Low vibration microminiature split Stirling cryogenic cooler f infrared aerospace applications [C]Infrared Technology Applications XXXVII, SPIE, 2011, 8012: 820831.

[7] [7] FLINT E, EVERT M, ERSON E, et al. Activepassive counterfce vibration control isolation systems [C]2000 IEEE Aerospace Conference. Proceedingsm, IEEE, 2000, 4: 285298.

[8] [8] ERSON E H, BLANKINSHIP R L, FOWLER R, et al. Adaptive filtering feedfward control f suppression of vibration jitter [C]Acquisition, Tracking, Pointing, Laser Systems Technologies XXI, SPIE, 2007, 6569: 243258.

[9] [9] CHE Mingshuo, LIN Zhe, MA Wenpo. A method of vibration suppression of a space mechanical cryocooler based on momentum compensation [C]4th International Symposium of Space Optical Instruments Applications, Springer International Publishing, 2018: 93102.

[10] Jinghao ZHU, Baoyu YANG, Jiakun ZHANG et al. Optimal driving method design of infrared cryocooler under high-order driving. Infrared and Laser Engineering, 52, 20220369(2023).

[11] [11] YANG Baoyu. Study of Adaptive Active Vibration control system f stirling cryocooler [D]. Shanghai: Shanghai Institute of Technological Physics, Chinese Academy of Sciences, 2008. (in Chinese)

[12] Tianzhi NI, Baoyu YANG. Adaptive active vibration control method for cryocooler compressor in space. Chinese Space Science and Technology, 37, 63-68(2017).

[13] [13] HOLLIDAY E S. Driving an active vibration balancer to minimize vibrations at the fundamental harmonic frequencies: US, 8800302[P]. 20140812.

[14] [14] AIGOUY G, BUTTERWTH J, REY J C, et al. Very compact integration of an ultralow vibration platfm f space cryocoolers using miniature highfrequency actuats [C]Cryocoolers 17 Proceedings of International Cryocooler Conference, 2012: 531537.

[15] Jiadeng WANG, Chong LIU, Xuerui LIU et al. Design and experimental investigation of the vibration isolation device for a spaceborne cryocooler. Noise and Vibration Control, 41, 194-198(2021).

[16] Shaojun BAI, Shaofan TANG, Yunsong NIE et al. Investigation of micro-vibration of space cryocoolers. Spacecraft Recovery & Remote Sensing, 34, 51-56(2013).

[17] Weiyi SHI, Jian CHEN, Weijun ZENG et al. Research on vibration control of space stirling cryocooler. Cryogenics & Superconductivity, 42, 10-15(2014).