[1] Wang Jing, Wu Yuehao, Jiang Bo, et al. Application of chalcogenide glass in designing a long wavelength infrared athermalized wide-angle lens [J]. Acta Photonica Sinica, 2016, 45(12): 1211003. (in Chinese)

[2] Yin Shaohui, Zhu Kejun, Yu Jianwu, et al. Micro aspheric glass lens molding process[J]. Journal of Mechanical Engineering, 2012, 48(15): 182-192. (in Chinese)

[3] Zhou Tianfeng, Xie Jiaqing, Liu Yang, et al. Simulation and experimental study on the molding process for microgrooveson optical glass [J]. Optics and Precision Engineering, 2016, 24(10): 446-453. (in Chinese)

[4] Cha D H, Kim H J, Park H S, et al. Effect of temperature on the molding of chalcogenide glass lenses for infrared imaging applications [J]. Applied Optics, 2010, 49(9): 1607-1613.

[5] Chien H H, Kuo C H, Huang S W. Molding of Al2O3-coated chalcogenide glass lenses [J]. Optical Engineering, 2012, 51(3): 033401-033407.

[6] Zhou J, Yu J F, Lee L J, et al. Stress relaxation and refractive index change of As2S3 in compression molding [J]. International Journal of Applied Glass Science, 2017, 8(3): 255-265.

[7] Zhang Y L, Wang Zh B, LI J Q, et al. Mold design with simulation for chalcogenide glass precision molding [C]//SPIE, 2016, 9683(16): 1-6.

[8] Liu Weiguo, Shen Ping. Viscoelastic properties of chalcogenide glasses and simulation of molding process [J]. Infrared and Laser Engineering, 2012, 41(3): 569-574. (in Chinese)

[9] Wang F, Chen Y, Klocke F, et al. Numerical simulation assisted curve compensation in compression molding of high precision aspherical glass lenses[J]. Journal of Manufacturing Science and Engineering, 2009, 131(1): 123-136.

[10] Ananthasayanam B, Joseph P F, Joshi D, et al. Final shape of precision molded optics: Part I-Computational approach, material definitions and the effect of lens shape [J]. Journal of Thermal Stresses, 2012, 35(6): 550-578.

[11] AraiI M, Kato Y, Kodera T. Characterization of the thermo-viscoelastic property of glass and numerical simulation of the press molding of glass lens[J]. Journal of Thermal Stresses, 2009, 32(12): 1235-1255.

[12] Chen Y, Allen Y, Su L J, et al. Numerical simulation and experimental study of residual stresses in compression molding of precision glass optical components [J]. Journal of Manufacturing Science and Engineering, 2008, 130: 051012.

[13] Su L J, Yi A Y. Finite element calculation of refractive index in optical glass undergoing viscous relaxation and analysis of the effects of cooling rate and material properties [J]. International Journal of Applied Glass Science, 2012, 3(3): 263-274.

[14] Yan J W, Zhou T F, Masuda J, et al. Modeling high-temperature glass molding process by coupling heat transfer and viscous deformation analysis [J]. Precision Engineering, 2009, 33: 150-159.

[15] Zhou J, Li M J, Hu Y, et al. Numerical evaluation on the curve deviation of the molded glass lens [J]. Journal of Manufacturing Science and Engineering, 2014, 136: 051004.

[16] Braunecker B, Hentschel R, Tiziani H. Advanced Optics Using Aspherical Elements Understanding Fiber Optics [M]. Tian Ailing, Wang Hongjun, Liu Bingcai, et al. transl. Hangzhou: Zhejiang University Press, 2011. (in Chinese)

[17] Cha D H, Kim J H, Kim H J. Experimental study of the fabrication of chalcogenide glass lenses by using precision glass molding [J]. Journal of the Korean Physical Society, 2014, 65(10): 1675-1681.

[18] Tang Kun, Kong Minghui, Zhu Yongjian, et al. Experimental study on precision molding of small dual aspherical chalcogenide glass lens [J]. Infrared and Laser Engineering, 2018, 47(4): 0418006. (in Chinese)