DESIGN OF THE MULTIORDER INTRAOCULAR LENSES

Intraocular lenses (IOLs) are used to replace the natural crystalline lens of the eye. Just few basic designs of IOLs are used clinically. Multiorder diffractive lenses (MODL) which operate simultaneously in several diffractive orders were proposed to decrease the chromatic aberration. Properties analysis of MODL showed a possibility to use them to develop new designs of IOLs. The purpose of this paper was to develop a new method of designing of multiorder intraocular lenses with decreased chromatic aberration. The theoretical research of the lens properties was carried out. The diffraction efficiency dependence with the change of wavelength was studied. A computer simulation of MODL in a schematic model of the human eye was carried out. It is found the capability of the multiorder diffractive lenses to focus polychromatic light into a segment on the optical axis with high diffraction efficiency. At each point of the segment is present each component of the spectral range, which will build a color image in combination. The paper describes the new design method of intraocular lenses with reduced chromaticism and with endless adaptation. An optical system of an eye with an intraocular lens that provides sharp vision of objects located at a distance of 700 mm to infinity is modeled.

1. Koronkevich V.P, Lenkova G.A., Korol’kov A.G., Poleschyk A.G. and other. New generation of bifocal diffractive-refractive lenses. Kompyuternaya optika, 2008, vol. 32, no. 1, pp. 50–58.

2. Kolobrodov V.G., Tymchik G.S. Prikladnaya difraktsionnaya optika [Applied diffractive optics]. Kiev, NTUU «KPI» Publ., 2014, 312 p. (in Ukrainian).

3. Vega F., Alba-Bueno F., Millan M.S. Energy Efficiency Of A New Trifocal Intraocular Lens. Journal Of The European Optical Society – Rapid Publications, 2014, Vol. 9, pp. 140021–140028.

4. Faklis D., Morris G. M. Spectral properties of multiorder diffractive lenses. Appl. Opt., 1995, Vol. 34, No. 14, pp. 2462–2468. 5. Sweeney D.W., Sommargren G.E. Harmonic diffractive lenses. Appl. Opt., 1995, Vol. 34, No. 14, pp. 2469–2475.

5. Chang-Jiang F., Zhao-Qi W., Lie L. Mei Z., HaiYing F. Design of infrared telephoto-optical system with double-layer harmonic diffractive element. Chin. Phys. Lett., 2007, Vol. 24, No.7, pp. 1973–1976.

6. Lou D., Bai J., Hou X., Yang G. Application and research of harmonic diffractive/refractive optics in visible spectrum. Proc. SPIE., Holography, Diffractive Optics, and Applications II, 2005, Vol. 5636, pp. 78–85.

7. Reichelt S., Sahm H., Leister N., Schwerdtner A. Capabilities of diffractive optical elements for real-time holographic displays. Proc. SPIE., Holography XXII: Materials and Applications, 2008, Vol. 6912, pp. 69120– 69130.

8. Qiang S., Zhaoqi W., Fengyou L., Hongli L. and other. Study of an athermal infrared dual optical system design containing harmonic diffractive element. Chinese Science Bulletin, 2003, Vol. 48, No. 12, pp. 1193–1198.

9. Lenkova G.A. Chromatic Aberrations of Diffractive-Refractive Intraocular Lenses in an Eye Model. Optoelectr., Instrum. Data Process., 2009, Vol. 45, No. 2, pp. 171–183.

10. Kolobrodov V.G., Kuchugura Ie.O., Kuchugura I.O. Projektirovanije mnogoporjadkovykh difrakcionnykh linz [Design of multiorder diffractive lenses]. Research Bulletin of NTUU «KPI», 2015, No. 2, pp. 82−88 (in Ukrainian).

11. Sokurenko V.M., Tymchik G.S., Chyzh І.H. Glaz cheloveka i oftal’mologicheskije pribory [The human eye and ophthalmic devices]. Kiev, NTUU «KPI» Publ., 2009, 264 p. (in Ukrainian).