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Abstract:
The work is devoted to the study of the point spread function of a harmonic diffractive lens illuminated by non-monochromatic radiation using a hybrid geometrical and wave optics approach.

Keywords:
geometric optics, harmonic diffractive lens, point spread function, chromaticism.

Citation:
Kharitonov SI, Volotovsky SG, Khonina SN. Geometic-optical calculation of the focal spot of a harmonic diffractive lens. Computer Optics 2016; 40(3): 331-337. DOI: 10.18287/2412-6179-2016-40-3-331-337.

References:

1. Bobrov ST, Greysukh GI, Turkevich YuG. Optics of diffractive elements and systems [In Russian]. Leningrad: Mashinostroenie; 1986.
2. Greysukh GI, Ezhov EG, Stepanov SA. Comparative analysis of the chromatizm of diffractive and refractive lenses [in Russian]. Computer Optics 2005; 28: 60-65.
3. Kazanskiy NL, Kharitonov SI, Karsakov AV, Khonina SN. Modeling action of a hyperspectrometer based on the Offner scheme within geometric optics. Computer Optics 2014; 38(2): 271-280.
4. Kazanskiy NL, Khonina SN, Skidanov RV, Morozov AA, Kharitonov SI, Volotovskiy SG. Formation of images using multi-level diffractive lens. Computer Optics 2014; 38(3): 425-434.
5. Karpeev SV, Khonina SN, Kharitonov SI. Study of the diffraction grating on the convex surface as a dispersive element. Computer Optics 2015; 39(2): 211-217.
6. Golovashkin DL, Kotlyar VV, Soifer VA (ed.), Doskolovich LL, Kazanskiy NL, Pavelyev VS, Khonina SN, Skidanov RV. Computer Design of Diffractive Optics. Cambridge Inter Scien Pub Ltd & Woodhead Pub Ltd; 2012.
7. Gavrilov AV, Golovashkin DL, Doskolovich LL, Dyachenko PN, Khonina SN, Kotlyar VV, Kovalev AA, Nalimov AG, Nesterenko DV, Pavelyev VS, Shuyupova YO, Skidanov RV, Soifer VA (ed.). Diffractive Nanophotonics. Boca Raton: CRC Press, Taylor&Francis Group, CISP; 2014.
8. Aieta F, Kats MA, Genevet P, Capasso F. Multiwavelength achromatic metaserfaces by dispersive phase compensation. Science 2015; 347(6228): 1342-1345.
9. Swanson GJ. Binary optics technology: the theory and design of multi-level diffractive optical elements. Technical Report 1989; 854: AD-A213-404.
10. Alferov SV, Karpeev SV, Khonina SN, Tukmakov KN, Moiseev OYu, Shulyapov SA, Ivanov KA, Savel’ev-Trofimov AB. On the possibility of controlling laser ablation by tightly focused femtosecond radiation. Quantum Electronics 2014; 44(11): 1061-1065.
11. Karpeev SV, Alferov SV, Khonina SN, Kudryashov SI. Study of the broadband radiation intensity distribution formed by diffractive optical elements. Computer Optics 2014; 38(4): 689-694.
12. Davidson N, Friesem AA, Hasman E. Analytic design of hybrid diffractive-refractive achromats. Applied Optics 1993; 32(25): 4770-4774.
13. Fang YC, Liu T-K, Tsai C-M, Chou J-H, Lin H-C, Lin WT. Extended optimization of chromatic aberrations via a hybrid Taguchi-genetic algorithm for zoom optics with a diffractive optical element. Journal of Optics A: Pure and Applied Optics 2009; 11(4): 045706.
14. Sweeney DW, Sommargen GE. Harmonic diffractive lenses. Applied Optics 1995; 34(14): 2469-2475.
15. Rossi M, Kunz RE, Herzig HP. Refractive and diffractive properties of planar micro-optical elements. Applied Optics 1995; 34(26): 5996-6007.
16. Sales TRM, Morris GM. Diffractive-refractive behavior of kinoform lenses. Applied Optics 1997; 36(1): 253-257.
17. Kharitonov SI, Kazanskiy NL, Doskolovich LL, Strelkov YS. Modeling the reflection of the electromagnetic waves at a diffraction grating generated on a curved surface. Computer Optics 2016; 40(2): 194-202. DOI: 10.18287/2412-6179-2016-40-2-194-202.

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