[1] Wen H D, Hui L J, Hou J et al. Research on the wave front gradient control technology of aspherical lens based on CCOS[J]. Proceedings of SPIE, 10838, 1083811(2019).

[2] Wang D E, Hu D X, Yuan Q et al. Wavefront control of main-amplifier system in the SG-Ⅲ laser facility[J]. Optics Communications, 394, 92-97(2017).

[3] Yang H, He J G, Huang W et al. Spot breeding method to evaluate the determinism of magnetorheological finishing[J]. Optical Engineering, 56, 035101(2017).

[4] Dai Y F, Shi F, Peng X Q et al. Deterministic figuring in optical machining by magnetorheological finishing[J]. Acta Optica Sinica, 30, 198-205(2010).

[5] Beier M, Scheiding S, Gebhardt A et al. Fabrication of high precision metallic freeform mirrors with magnetorheological finishing (MRF)[J]. Proceedings of SPIE, 8884, 88840S(2013).

[6] Sun X W. Magnetorheological finishing pre-compensation cross-coupled contour control algorithm[J]. Manufacturing Automation, 34, 7-11(2012).

[7] Zhang Y F, Huang W, Zheng Y C et al. Research on the magnetorheological finishing of large aperture off-axis aspheric optical surfaces for zinc sulfide[J]. Proceedings of SPIE, 10255, 102550R(2017).

[8] Song C, Dai Y F, Peng X Q et al. Post processing for magnetorheological finishing of optical mirrors[J]. Optics and Precision Engineering, 18, 1715-1721(2010).

[9] Chen M J, Liu H N, Su Y R et al. Design and fabrication of a novel magnetorheological finishing process for small concave surfaces using small ball-end permanent-magnet polishing head[J]. The International Journal of Advanced Manufacturing Technology, 83, 823-834(2016).

[10] Liu H N, Chen M J, Yu B et al. Configuration design and accuracy analysis of a novel magnetorheological finishing machine tool for concave surfaces with small radius of curvature[J]. Journal of Mechanical Science and Technology, 30, 3301-3311(2016).

[11] Maloney C, Lormeau J P, Dumas P. Improving low, mid and high-spatial frequency errors on advanced aspherical and freeform optics with MRF[J]. Proceedings of SPIE, 10009, 100090R(2016).

[12] Menapace J A, Peer A S, Tham G C. Manufacturing high-gradient freeform continuous phase plates (CPPs) using magnetorheological finishing. [C]∥Optical Design and Fabrication 2019 (Freeform, OFT), June 10-12, 2019, Washington, DC, United States. Washington, D.C.: OSA, JW1A, 5(2019).

[13] Xu W J, Chen J. Lau H Y K, et al. Data-driven methods towards learning the highly nonlinear inverse kinematics of tendon-driven surgical manipulators[J]. The International Journal of Medical Robotics and Computer Assisted Surgery, 13, e1774(2017).

[14] Momani S. Abo-Hammou Z S, MK Alsmad O. Solution of inverse kinematics problem using genetic algorithms[J]. Applied Mathematics & Information Sciences, 10, 225-233(2016).

[15] Goodman D. Geometric optics, handbook of optics: fundamentals, techniques, and design[M]. New York: McGraw-Hill(1995).

[16] Yang H, He J G, Huang W et al. Differential decoupling method employed in MRF spotting process[J]. High Power Laser and Particle Beams, 27, 082005(2015).

[17] Ahookhosh M, Amini K, Kimiaei M. A globally convergent trust-region method for large-scale symmetric nonlinear systems[J]. Numerical Functional Analysis and Optimization, 36, 830-855(2015).

[18] Yuan Y. A review of trust region algorithms for optimization. [C]∥ICIAM. [S.l.: s.n.], 271-282(2000).