Laser & Optoelectronics Progress, Volume. 55, Issue 3, 030002(2018)
Review on Splicing Structure Technology of Large Aperture Space Primary Mirror
[1] Kendrick S E. Monolithic versus segmented primary mirror concepts for space telescopes[C]. SPIE, 7426, 74260O(2009).
[2] Nelson J E, Mast T S, Telescope[R]. Pasadena: Caltech. https: //authors. library.caltech.edu/37111/.(1985).
[3] Nelson J. Segmented mirror telescopes[M]. //Optics in Astrophysics. Springer Netherlands, 61-72(2006).
[4] National Research Council[M]. Astronomy and Astrophysics Survey Commit, Board on Physics and Astronomy. Astronomy and astrophysics in the new millennium(2001).
[5] Postman M, Argabright V, Arnold B et al[J]. ATLAST, : a technology roadmap for the next decade. arXiv preprint arXiv, 0941, 2009(904).
[7] Agrawal B, Kubby J. Applications of MEMS in segmented mirror space telescopes[C]. SPIE, 7931, 793102(2011).
[8] Agrawal B N, Kim J J. Surface control of actuated hybrid space mirrors[C]. Prague: 61th International Astronautical Congress(2010).
[9] Maly J R, Yingling A J, Griffin S F et al. Vibration damping for the segmented mirror telescope[C]. SPIE, 8450, 845004(2012).
[12] Acton D S, Knight J S, Contos A et al. Wavefront sensing and controls for the James Webb Space Telescope[C]. SPIE, 8442, 84422H(2012).
[13] Chaney D M, Hadaway J B, Lewis J A. Cryogenic radius of curvature matching for the JWST primary mirror segments[C]. SPIE, 7439, 743916(2009).
[14] Wells C, Coon M. Optomechanical integration and alignment verification of the James Webb Space Telescopes(JWST) optical telescope element[C]. SPIE, 7433, 743303(2009).
[15] Miller D W, Mohan S, Budinoff J. Assembly of a large modular optical telescope (ALMOST)[C]. SPIE, 7010, 70102H(2008).
[16] Stoll E, Kwon D. The benefit of multimodal telepresence for in-space robotic assembly[C]. IASTED International Conference on Robotics & Applications, 664-667(2009).
[17] Sternberg D C. Development of an incremental and iterative risk reduction facility for robotic servicing and assembly missions[D]. Cambridge: Massachusetts Institute of Technology(2014).
[18] Katz J G. Estimation and control of flexible space structures for autonomous on-orbit assembly[D]. Cambridge: Massachusetts Institute of Technology(2009).
[19] Postman M, Sparks W B, Liu F et al. Using the ISS as a testbed to prepare for the next generation of space-based telescopes[C]. SPIE, 8442, 84421T(2012).
[20] Carpenter K G, Etemad S, Seery B D et al. OpTIIX: An ISS-based testbed paving the roadmap toward a next generation large aperture UV/optical space telescope[R]. NASA Technical Reports Server(2012).
[21] Hickey G, Barbee T, Ealey M et al. Actuated hybrid mirrors for space telescopes[C]. SPIE, 7731, 773120(2010).
[23] Feinberg L D, Budinoff J G. MacEwen H A, et al. Modular assembled space telescope[J]. Optical Engineering, 52, 091802(2013).
[25] Wang X, Zhang G Y, Chu C B et al. Conceptual design of expandable lens system for space large diameter telescope[J]. Machine Design and Research, 20, 49-52(2004).
[26] Yang D W, Duan B Y, Qiu Y Y. Dynamics optimization design of a deployable space telescope structure[J]. China Mechanical Engineering, 17, 241-245(2006).
[27] Dai Y F, Liu Z Z. Modeling and surface of segmented primary mirror for a space-based telescope[J]. Optical Technique, 32, 239-242(2006).
[28] Wang C C, Zou G Y, Pang Z H et al. Analysis on deployment error of segmented mirror optical system[J]. Acta Optica Sinica, 36, 1122005(2016).
[29] Li B, Tang J L, Yu W H et al. Effect of segmented errors on image quality of segmented telescope[J]. Laser & Optoelectronics Progress, 54, 071202(2017).
[30] Lei C D, Zheng L Y, Che Y. Segmented telescope optical system and its maladjustment error analysis of aspheric sector-shaped sub-mirror[J]. Laser & Optoelectronics Progress, 52, 112203(2015).
[31] Song J B, Li G P. Design and simulation of splicing of sector-shaped segments of a large optical telescope[J]. Astronomical Research & Technology, 7, 355-361(2010).
[33] Hirzinger G, Brunner B, Dietrich J. ROTEX-the first remotely controlled robot in space[C]. IEEE International Conference on Robotics and Automation, 2604-2611(1994).
[34] Keski-Kuha R A, Saif B, Eegholm B et al. . Development of interferometry for testing the JWST Optical Telescope Element (OTE)[C]. SPIE, 7010, 70100R(2008).
[35] Mohan S. Reconfiguration methods for on-orbit servicing, assembly, and operations with application to space telescopes[D]. Cambridge: Massachusetts Institute of Technology(2007).
[36] Acton D S, Atcheson P D, Cermak M et al. James Webb Space Telescope wavefront sensing and control algorithms[C]. SPIE, 5487, 887-896(2004).
[37] Streetman S, Kingsbury L. Cryogenic nano-positioner development and test for space applications[C]. SPIE, 4850, 274-285(2003).
[38] Burge J H. Angel J R P, Cuerden B, et al. Lightweight mirror technology using a thin facesheet with active rigid support[C]. SPIE, 3356, 690-701(1998).
[39] Yan S Z, Wu D L, Huang T Q et al. Design and experiment for a piezo ceramic micro displacement actuator on spacecraft[J]. Missiles and Space Vehicles, 236, 25-31(1998).
[40] Yang D H, Qi Y J, Zhu Z D et al. Design and test of the active micro-motion mechanism for optical mirror segment[J]. Optics and Precision Engineering, 13, 191-197(2005).
Get Citation
Copy Citation Text
Xupeng Li, Jinfeng Shi, Wei Wang, Yongjie Wang, Xuewu Fan. Review on Splicing Structure Technology of Large Aperture Space Primary Mirror[J]. Laser & Optoelectronics Progress, 2018, 55(3): 030002
Category: General
Received: Jul. 31, 2017
Accepted: --
Published Online: Sep. 10, 2018
The Author Email: Fan Xuewu (fanxuewu@opt.ac.cn)