[1] Yu T, Wang Y C, Dai S et al. Active thermal control system for space camera based on temperature level[J]. Infrared and Laser Engineering, 44, 249-253(2015).

[2] Vasudeva Murthy H S, Sharma A K, Badarinarayana K et al. Thermal management of GEO satellite communication payload[C], 469-470(2011).

[3] Li M, Wu Q W, Jiang F et al. Design of thermal control system for three-linear array mapping cameras[J]. Optics and Precision Engineering, 18, 1367-1373(2010).

[4] Huang J R, Fan Y F, Liu B Q et al. Design and on-orbit performance evaluation of thermal control system for SHENZHOU-7 spaceship[J]. Chinese Space Science and Technology, 29, 1-7(2009).

[5] Min G R, Guo S[M]. Thermal control of spacecraft(1998).

[6] Hengeveld D W, Mathison M M, Braun J E et al. Review of modern spacecraft thermal control technologies[J]. HVAC&R Research, 16, 189-220(2010).

[7] Tong Y L, Li G Q, Geng L Y. A review on precise temperature control technology for spacecraft[J]. Spacecraft Recovery & Remote Sensing, 37, 1-8(2016).

[8] Yang W G, Yu L, Chen R L et al. Precise thermal control design and validation for high resolution space camera[J]. Acta Photonica Sinica, 38, 2363-2367(2009).

[9] Liu S R, Liu B L, Zhang W R et al. Thermal control system design of the geostationary orbit satellite-borne optical-electro-mechanical instrument[J]. Laser & Infrared, 48, 1404-1410(2018).

[10] Li Y W, Yuan G Q, Yang H B et al. Thermal control design and proof test of altitude transmissive optical sensor[J]. Acta Optica Sinica, 33, 0928001(2013).

[11] Liu B L, Zhou Z X, Li J et al. Thermal control technology for optical antenna in geostationary orbit space satellite-borne laser communication[J]. Chinese Journal of Lasers, 44, 0306003(2017).

[12] Wang Y C. Design and implementation of active thermal control system for ultraviolet imaging spectrometer[J]. Journal of Astronautics, 35, 977-984(2014).

[13] Guo L, Wu Q W, Huang Y et al. Application of thermal management technique to thermal control for ultraviolet imaging spectrometers[J]. Optics and Precision Engineering, 22, 1877-1885(2014).

[14] Choi M. Thermal evaluation of NASA/Goddard heater controllers on Swift BAT, optical bench and ACS[C], 5607(2005).

[15] Choi M. Thermal assessment of Swift instrument module thermal control system and mini heater controllers after 5+ years in flight[C], 6003(2010).

[16] Chang X, Zhang P, Li K et al. Design of high precision control of space camera temperature controlling[J]. Computer Measurement & Control, 22, 2274-2276(2014).

[17] Lemmen M, Kouwen J, Koorevaar F et al. In-flight results of the sciamachy optical assembly active thermal control system[R](2004).

[18] Li G Q, Geng L Y, Tong Y L. A precise temperature control system for spacecraft rubidium atomic clock[J]. Spacecraft Engineering, 20, 93-98(2011).

[19] Guan F W, Liu J, Yu S M et al. Calibration and R-T characteristics of NTC thermistor[J]. OME Information, 28, 69-73(2011).

[20] Hu H B, Wu J W, Zhang L M et al. Composite measurement error analysis and model research of electrical signals RMS[J]. Transactions of China Electrotechnical Society, 27, 172-177(2012).

[21] Qin S. Model predictive thermal control method for precision lens system[J]. Laser & Optoelectronics Progress, 59, 1722006(2022).