Infrared and Laser Engineering, Volume. 51, Issue 9, 20220384(2022)
Long focal length aspherical mirror testing with CGH and auxiliary lenses (invited)
[1] Shuang Zhang, Hua Qin, Kai Yang, et al. Particle swarm optimization method for designing aspheric lens Gaussian beam shaping. Infrared and Laser Engineering, 46, 1206005(2017).
[2] Linfeng Ma, Zhiying Liu, Yunhan Huang, et al. Optical design and analysis of illumination system based on augmented reality. Journal of Applied Optics, 43, 179-190(2022).
[3] Zhengbo Zhu, Shili Wei, Zichao Fan, et al. Freeform illumination optics design for extended LED sources through a localized surface control method. Optics Express, 30, 11524-11535(2022).
[4] Lei Yu. Development and application of imaging spectrometer (
[5] Y Wang, W Liu, X Meng, et al. Development of an immersive virtual reality head-mounted display with high performance. Applied Optics, 55, 6969(2016).
[6] Lamprecht Bernhard, Ulm Andreas, Lichtenegger Philip, et al. Origination of free-form micro-optical elements using one- and two-photon grayscale laser lithography. Applied Optics, 61, 1863-1875(2022).
[7] Jing Luo, Jinxin Wang, Guohao Ju, et al. Computer-aided alignment for large-aperture off-axis three mirrors optical system with artificially random air flow. Optics and Precision Engineering, 30, 802-812(2022).
[8] Xinghua Li, Dong Zhang, Lingyu Gao, et al. Study on line-of-sight deflection error for off-axis three mirror system. Infrared and Laser Engineering, 47, 0918005(2018).
[9] Qinfang Chen, Yingcai Li, Zhen Ma, et al. Alignment of off-axis conic aspheric mirrors in stigmatic null test. Acta Optica Sinica, 31, 0222001(2011).
[10] Junhua Yan, Zijia Hu, Deyan Zhu, et al. Design of compensator for parabolic aspheric surface zero interference detection. Electronic Design Engineering, 30, 66-75(2022).
[11] L Yan, D Zhu, X Zeng, et al. Experimental study on hybrid compensation testing of an off-axis convex ellipsoid surface. Optics Express, 27, 27546(2019).
[12] Yuhang He, Qiang Li, Bo Gao, et al. Measurement of the transmission wavefront of a large-aperture aspheric lens based on computer-generated hologram. Laser & Optoelectronics Progress, 56, 021202(2019).
[13] H Y Li, D Walker, G Y Yu, et al. Modeling and validation of polishing tool influence functions for manufacturing segments for an extremely large telescope. Appl Opt, 52, 5781-5787(2013).
[14] [14] Burge J H, Kot L B, Martin H M. Design analysis f interferometric measurements of the GMT primary mirr segments [C]Proceedings of SPIE, 2006, 6273: 627322.
[15] [15] Burge J H. Efficient testing of offaxis aspheres with test plate computergenerated holograms [C]Proceedings of SPIE, 1999, 3782: 348357.
[16] [16] Li Shijie. Testing offaxis aspheric surface by combinedhologram [D]. Chengdu: The Institute of Optics Electronics, Chinese Academy of Sciences, 2014. (in Chinese)
[18] Jiantai Dou, Zhishan Gao, Zhongming Yang, et al. Deep aspheric surface test based on combination of computer generated holograms with low spatial frequency. Acta Optica Sinica, 36, 1112004(2016).
[19] D Y Zhu, F Wang, P Li, et al. Research on hybrid compensation testing of convex aspherical mirror. Optics and Lasers in Engineering, 132, 106108(2020).
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Yuxin Zhang, Fazhi Li, Lisong Yan, Dong Yan, Chaofan Wang, Yuhe Zhang, Binzhi Zhang, Xin Zhang, Mingxuan Cai, Junchao He, Xiaokun Wang. Long focal length aspherical mirror testing with CGH and auxiliary lenses (invited)[J]. Infrared and Laser Engineering, 2022, 51(9): 20220384
Category: Special issue—Ultra precision manufacture and testing technology of optical aspheric surface
Received: Jun. 6, 2022
Accepted: --
Published Online: Jan. 6, 2023
The Author Email: Yan Lisong (yanlisong@hust.edu.cn)