[1] McElwain M W, Feinberg L D, Perrin M D et al. The James Webb space telescope mission: optical telescope element design, development, and performance[J]. Astron Soc Pac, 135, 058001(2023).

[2] Postman M, Argabright V, Arnold B et al. Advanced technology large-aperture space telescope (ATLAST): A technology roadmap for the next decade[EB/OL]. https://arxiv.org/abs/0904.0941

[3] Liao C H, Yu F, Liu C et al. Research on the decoupling control method of segmented deformable mirror surface shape[J]. Spacecr Recovery Remote Sens, 43, 69-78(2022).

[4] Jiang W H. Overview of adaptive optics development[J]. Opto-Electron Eng, 45, 1-15(2018).

[5] Guan C L, Zhang X J, Deng J M et al. Deformable mirror technologies at institute of optics and electronics, Chinese Academy of Sciences[J]. Opto-Electron Eng, 47, 51-62(2020).

[6] Chaney D M, Hadaway J B, Lewis J A. Cryogenic radius of curvature matching for the JWST primary mirror segments[J]. Proc SPIE, 7439, 743916(2009).

[7] Chonis T S, Gallagher B B, Knight J S et al. Characterization and calibration of the James Webb space telescope mirror actuators fine stage motion[J]. Proc SPIE, 10698, 106983S(2018).

[8] Redding D. Large segmented apertures in space: active vs. passive[EB/OL]. https://kiss.caltech.edu/special_events/JPL_MPIA/presentations/2_Redding. pdf

[9] Perrin M D, Acton D S, Lajoie C P et al. Preparing for JWST wavefront sensing and control operations[J]. Proc SPIE, 9904, 99040F(2016).

[10] Hirose M, Kumeta A, Miyamura N et al. Wavefront correction using MEMS deformable mirror for earth observation satellite with large segmented telescope[J]. Proc SPIE, 11448, 114487D(2020).

[11] Kimura T, Mizutani T, Shirasawa Y et al. Geostationary earth observation satellite with large segmented telescope[C], 5895-5897(2019). https://doi.org/10.1109/IGARSS.2019.8898683

[12] Fujii Y, Uno T, Ariki S et al. Experimental study of 3.6-meter segmented-aperture telescope for geostationary earth observation satellite[J]. Proc SPIE, 11852, 118522G(2021).

[13] Su D Q, Cui X Q. Active optics in LAMOST[J]. Chin J Astron Astrophys, 4, 1-9(2004).

[14] Chen J Y, Wang C, Huo T F et al. Research on detection method of large-aperture aspheric surface by laser tracker[J]. J Appl Opt, 42, 299-303(2021).

[15] Pang Z, Zong X Y, Du J X. A method measuring geometric parameters for large-aperture aspheric surface with the laser tracker[J]. Spacecr Recovery Remote Sens, 41, 47-59(2020).

[16] Shi Y L, Niu D S, Wang H et al. Research on micro-displacement actuator for high precision mirror position control[J]. Astron Res Technol, 20, 250-257(2023).

[17] Wu S H, Dong J H, Xu S Y et al. Overview of active support technology for main mirror of segmented telescopes[J]. Laser Optoelectron Prog, 58, 0300006(2021).

[18] Huang L H, Fan M W, Zhou R et al. System identification and control for large aperture fast-steering mirror driven by PZT[J]. Opto-Electron Eng, 45, 170704(2018).

[19] Cohan L E. Integrated modeling and design of lightweight, active mirrors for launch survival and on-orbit performance[D](2010).

[20] Ealey M A. Integrated actuator meniscus mirror[P].