УДК: 535.317

Method for calculation and analysis of a cemented component with achromatic and aplanatic correction

Ivanova, T.V., Romanova, G.E., Zhukova, T.I., Kalinkina, O.S.

Publication in Journal of Optical Technology

For Russian citation (Opticheskii Zhurnal):

Иванова Т.В., Романова Г.Э., Жукова Т.И., Калинкина О.С. Метод расчёта и анализа склеенного компонента с ахроматической и апланатической коррекцией // Оптический журнал. 2017. Т. 84. № 8. С. 54–58.

Ivanova T.V., Romanova G.E., Zhukova T.I., Kalinkina O.S. Method for calculation and analysis of a cemented component with achromatic and aplanatic correction [in Russian] // Opticheskii Zhurnal. 2017. V. 84. № 8. P. 54–58.

For citation (Journal of Optical Technology):

T. V. Ivanova, G. E. Romanova, T. I. Zhukova, and O. S. Kalinkina, "Method for calculation and analysis of a cemented component with achromatic and aplanatic correction," Journal of Optical Technology. 84(8), 548-551 (2017). https://doi.org/10.1364/JOT.84.000548

Abstract:

This paper presents a method for calculating and analyzing a cemented component, developed on the basis of the methodology of G. G. Slyusarev. According to the given values of the main parameters P, W, and C, which determine the aberration characteristics of the system, several suitable pairs of glasses are selected that provide the required values of the third-order aberrations. For each pair, the design parameters of the cemented component are calculated, and the residual aberrations are determined according to the calculation of the real ray path.

Keywords:

cemented component, synthesis, third-order aberrations, coma, chromatism

OCIS codes: 080.1753, 080.3620, 220.3620

References:

1. G. G. Slyusarev, Calculation of Optical Systems (Mashinostroenie, Leningrad, 1975).
2. S. V. Trubko, Calculation of Cemented Doublet Objectives (Mashinostroenie, Leningrad, 1984).
3. A. Szulc, “Improved solution for the cemented doublet,” Appl. Opt. 35(19), 3548–3558 (1996).
4. J. L. Rayces and M. Rosete-Aguilar, “Selection of glasses for achromatic doublets with reduced secondary spectrum. I. Tolerance conditions for secondary spectrum, spherochromatism, and fifth-order spherical aberration,” Appl. Opt. 40(31), 5663–5676 (2001).
5. L. N. Andreev and V. V. Ezhova, “Cemented doublet objectives with an aspherical surface of the second order,” Nauchno-Tekh. Vestn. Inf. Tekhnol. Mekh. Opt. 1(71), 134–135 (2011).
6. W.-S. Sun, C.-H. Chu, and C.-L. Tien, “Well-chosen method for an optimal design of doublet lens design,” Opt. Express 17(3), 1414–1428 (2009).
7. G. Romanova, T. Ivanova, and N. Korotkova, “Automation design of cemented doublet,” Proc. SPIE 9626, 96262S (2015).
8. “Optical materials. Parameters,” GOST 23136-93, January 1995.
9. Zemax, Optical Design Program User’s Manual, 2014.
10. T. V. Ivanova, G. E. Romanova, D. V. Bondarenko, O. S. Kalinkina, and N. D. Korotkova, “Synthesis of the Cemented Component,” Certificate of state registration of the computer program No. 2016614896, May 11, 2016.
11. A. P. Grammatin, Automation of Design of Optical Systems (LITMO, Leningrad, 1989).
12. A. P. Grammatin, G. E. Romanova, and O. N. Balatsenko, Calculation and Automation of Design of Optical Systems (NIU ITMO, St. Petersburg, 2013).