[1] B P Abbott, R Abbott, T D Abbott et al. Observation of gravitational waves from a binary black hole merger. Phys Rev Lett, 116, 061102(2016).
[2] K Danzmann, The LISA Study Team. LISA: laser interferometer space antenna for gravitational wave measurements. Class Quantum Grav, 13, A247(1996).
[3] J Luo, L S Chen, H Z Duan et al. TianQin: a space-borne gravitational wave detector. Class Quantum Grav, 33, 035010(2016).
[4] J Luo, Y Z Bai, L Cai et al. The first round result from the TianQin-1 satellite. Class Quantum Grav, 37, 185013. https://doi.org/10.1088/1361-6382/aba66a
[5] J Livas, S Sankar. Optical telescope design study results. J Phys Conf Ser, 610, 012029(2015).
[6] X Y Wang, S J Bai, Q Zhang et al. Research progress of telescopes for space-based gravitational wave missions. Opto-Electron Eng, 50, 230219.(2023).
[7] J. Sanjuán, A. Preston, D. Korytov et al. Carbon fiber reinforced polymer dimensional stability investigations for use on the laser interferometer space antenna mission telescope. Rev Sci Instrum, 82, 124501(2011).
[8] N Desnoyers, P Goyette, B Leduc et al. Dimensional stability performance of a CFRP sandwich optical bench for microsatellite payload. Proc SPIE, 10372, 103720G(2017).
[9] W T Fan, H C Zhao, L Fan et al. Preliminary analysis of space gravitational wave detection telescope system technology. Acta Sci Nat Univ Sunyatseni, 60, 178-185.(2021).
[10] J C Machado, T Heinrich, T Schuldt et al. Picometer resolution interferometric characterization of the dimensional stability of zero CTE CFRP. Proc SPIE, 7018, 70183D(2008).
[11] R Spannagel, I Hamann, J Sanjuan et al. Dilatometer setup for low coefficient of thermal expansion materials measurements in the 140 K-250 K temperature range. Rev Sci Instrum, 87, 103112(2016).
[12] R Spannagel, M Gohlke, T Schuldt et al. CTE measurement setup with 10 ppb/K sensitivity for characterizing lightweight and highly stable materials for space applications. Proc SPIE, 8450, 84500Q(2012).
[13] J Sanjuán, D Korytov, G Mueller et al. Note: silicon carbide telescope dimensional stability for space-based gravitational wave detectors. Rev Sci Instrum, 83, 116107(2012).
[14] A L Verlaan, H Hogenhuis, J Pijnenburg et al. LISA telescope assembly optical stability characterization for ESA. Proc SPIE, 8450, 845003(2012).
[15] B L Sang, X Q Deng, B Peng et al. Dimensional stability ground test and in-orbit prediction of SiC telescope frame for space gravitational wave detection. IEEE Access, 10, 21041-21047(2022).
[16] B H Li, J Luo, M Y Qiu et al. Design technology of the truss support structure of the ultra-low thermal deformation gravitational wave detection telescope. Opto-Electron Eng, 50, 230155.(2023).
[17] X Z Yu. Multi-degree of freedom optical metrology techniques(2017).
[18] W A Klop, A L Verlaan. Dimensional stability testing in thermal vacuum of the CHEOPS optical telescope assembly. Proc SPIE, 9904, 990437(2016).
[19] H Yan. Study on ultra-precision multi-degree-of-freedom optical measurement base on laser interferometry(2019).
[20] J P Yu. Study on planar capacitive sensors for multiple-dimensional precision displacement measurement(2013).
[21] C Sun. Research on multi-degree-of-freedom measurement method for precision engineering(2021).
[22] K Zhao, W T Fan, H W Hai et al. Design of optical path stability measurement scheme and theoretical analysis of noise in telescope. Opto-Electron Eng, 50, 230158.(2023).