[1] [1] OHMORI H. Electrolytic in-process dressing (ELID) grinding method for ultra-precision mirror surface grinding［J］. Journal of Japan Society for Precision Engineering, 1993,59(9):1451.

[2] [2] YIN SH H, ZENG X L, FAN Y F, et al.. Research progresses of ELID mirror grinding technology［J］. China Mechanical Engineering, 2010,21(6):750-755. (in Chinese)

[3] [3] PAN J H. The Design, Manufacture and Test of the Aspherical Optical Surfaces ［M］. Suzhou: Soochow University Press, 1994. (in Chinese)

[4] [4] JONES R A. Optimization of computer controlled polishing ［J］. Applied Optics, 1977,16(1):218-224.

[5] [5] LI H Y, ZHANG W, YU G Y.Study of weighted space deconvolution algorithm in computer controlled optical surfacing formation ［J］. Chinese Optics Letters,2009,7(7):627-631.

[6] [6] ZHANG F, XU L D, FAN D, et al.. Fabrication of surface modification aspheric SiC mirror ［J］. Opt. Precision Eng., 2008,16(12): 2479-2484. (in Chinese)

[7] [7] PROKHOROW I V, KORDONSKY W I, GLEB L K, et al.. New high-precision magnetorheological instrument-based method of polishing optics［J］. OSA OF&T Workshop Digest, 1992,24:134-136.

[8] [8] SHI F, DAI Y F, PENG X Q, et al.. Study on the novel process of reducing subsurface damage in grinding by Magnetorheological Finishing ［J］. Opt. Precision Eng., 2010,18(1):162-168.(in Chinese)

[9] [9] ALLEN, L N, HANNON J J, WAMBACH R W. Final surface error correction of an off-axis aspheric petal by ion figuring ［J］. SPIE, 1992,1543:190-200.

[10] [10] ZHANG F, ZHANG X J, YU J C, et al.. Foundation of mathematics model of magnetorheological finishing ［J］. Optical Technique, 2000,26(2):190-192.

[11] [11] ZHANG F, ZHANG B Z. Surface roughness of optical elements fabricated by magnetic fluid-assisted polishing［J］. Opt. Precision Eng., 2005,13(1):34-39. (in Chinese)

[12] [12] ZHANG F, FAN D, LI R G, et al.. Fabrication and testing of aspheric silicon carbide mirror ［J］. Journal of Applied Optics, 2008，29(6)：1004-1008. (in Chinese)

[13] [13] WANG P, ZHAO W C, HU M Y, et al.. Hindle testing of the off-axis convex asphere surface［J］. Opt. Precision Eng., 2002,10(2):139-142. (in Chinese)

[14] [14] BURGE J H, ANDERSON D S. Full-aperture interferometric test of convex secondary mirrors using holographic test plates［J］. SPIE, 1994,2199:181-190.

[15] [15] XIE Y, CHEN Q, WU F, et al.. Design and fabrication of twin computer-generated holograms for testing concave aspherical surfaces ［J］. Opto-Electronic Engineering, 2010,6(35):59-62. (in Chinese)

[16] [16] LIU Y M, GEORGE N L. Subaperture testing of aspheres with annular zones［J］. Applied Optics, 1988,27(21):4504-4513.

[17] [17] ZHANG W , WANG Z , REN ZH B , et al.. Stitching arithmetic of the sub-aperture testing of large convex aspheric surface ［J］. Optical Technique, 2010,2(36):182-186. (in Chinese)

[18] [18] WANG X K, ZHENG L G, ZHANG X J. Testing convex aspheres by subaperture stitching interferometry［J］. Acta Optica Sinica, 2010, 30(7)：2022-2026. (in Chinese)

[19] [19] CHEN X, LIU W Q, KANG Y S, et al. Design and tolerance analysis of Offner compensator［J］. Opt. Precision Eng., 2010,18(1): 88-93. (in Chinese)

[20] [20] LI H, XIANG Y. Design of 10° FOV telecentric off-axis three-mirror anastigmatic telescope［J］. Acta Photonica Sinica, 2009,38(9):2256-2260. (in Chinese)