Contact lens design to third order to compensate the spherical aberration of the eye from Zernike polynomials

O. Garcia-Lievanos; Emiliano Teran-Bobadilla; Luis A. Hernandez-Flores; Leticia Sanchez-Gonzalez

doi:10.1117/12.2526476

Contact lens design to third order to compensate the spherical aberration of the eye from Zernike polynomials

O. Garcia-Lievanos, Emiliano Teran-Bobadilla, Luis A. Hernandez-Flores, Leticia Sanchez-Gonzalez

Centro Interdisciplinario de Ciencias de La Salud, Unidad Santo Tomás (CICS-Santo Tomás)

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Resumen

To compensate the spherical aberration of the eye using the conic constant of the first surface of a contact lens for different refractive errors. Refractive errors were simulated by modifying only the first curvature of the cornea. For every refractive error was calculating Zernike polynomials using Optics Software for Layout and Optimization (OSLO) EDU edition with and without contact lens. To calculate the conic constant of the contact lens we use the Seidel sums for thin lenses from the longitudinal spherical aberration as it proposes V. Mahajan. The value of Zernike spherical aberration coefficient for the eye with farsightedness (+ 5.00 D) + spherical contact lens was 0.142691 μm. The conic constant value to compensate the spherical aberration was-0.222995 and the value of Zernike spherical aberration coefficient of the eye + aspherical contact lens was 0.004354 μm. The value of Zernike spherical aberration coefficient for the eye with myopia (-5.00 D) + spherical contact lens was 0.144505 μm. The conic constant value to compensate the spherical aberration was-0.101424 and the value of Zernike spherical aberration coefficient of the eye + aspherical contact lens was 0.072820 μm. The proposed method allows us to design contact lenses that compensate for the spherical aberration of the eye from the Zernike polynomials. Although the design of contact lenses is to third order, we obtain a smaller spherical aberration than the chromatic aberration on the axis without use optimization routine.

Idioma original	Inglés
Título de la publicación alojada	Current Developments in Lens Design and Optical Engineering XX
Editores	R. Barry Johnson, Virendra N. Mahajan, Simon Thibault
Editorial	SPIE
ISBN (versión digital)	9781510629011
DOI	https://doi.org/10.1117/12.2526476
Estado	Publicada - 2019
Evento	Current Developments in Lens Design and Optical Engineering XX 2019 - San Diego, Estados Unidos Duración: 12 ago. 2019 → …

Serie de la publicación

Nombre	Proceedings of SPIE - The International Society for Optical Engineering
Volumen	11104
ISSN (versión impresa)	0277-786X
ISSN (versión digital)	1996-756X

Conferencia

Conferencia	Current Developments in Lens Design and Optical Engineering XX 2019
País/Territorio	Estados Unidos
Ciudad	San Diego
Período	12/08/19 → …

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Garcia-Lievanos, O., Teran-Bobadilla, E., Hernandez-Flores, L. A., & Sanchez-Gonzalez, L. (2019). Contact lens design to third order to compensate the spherical aberration of the eye from Zernike polynomials. En R. B. Johnson, V. N. Mahajan, & S. Thibault (Eds.), Current Developments in Lens Design and Optical Engineering XX Artículo 111040O (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11104). SPIE. https://doi.org/10.1117/12.2526476

Garcia-Lievanos, O. ; Teran-Bobadilla, Emiliano ; Hernandez-Flores, Luis A. et al. / Contact lens design to third order to compensate the spherical aberration of the eye from Zernike polynomials. Current Developments in Lens Design and Optical Engineering XX. editor / R. Barry Johnson ; Virendra N. Mahajan ; Simon Thibault. SPIE, 2019. (Proceedings of SPIE - The International Society for Optical Engineering).

@inproceedings{c946e9be86204fb9b710694292a5c3fa,

title = "Contact lens design to third order to compensate the spherical aberration of the eye from Zernike polynomials",

abstract = "To compensate the spherical aberration of the eye using the conic constant of the first surface of a contact lens for different refractive errors. Refractive errors were simulated by modifying only the first curvature of the cornea. For every refractive error was calculating Zernike polynomials using Optics Software for Layout and Optimization (OSLO) EDU edition with and without contact lens. To calculate the conic constant of the contact lens we use the Seidel sums for thin lenses from the longitudinal spherical aberration as it proposes V. Mahajan. The value of Zernike spherical aberration coefficient for the eye with farsightedness (+ 5.00 D) + spherical contact lens was 0.142691 μm. The conic constant value to compensate the spherical aberration was-0.222995 and the value of Zernike spherical aberration coefficient of the eye + aspherical contact lens was 0.004354 μm. The value of Zernike spherical aberration coefficient for the eye with myopia (-5.00 D) + spherical contact lens was 0.144505 μm. The conic constant value to compensate the spherical aberration was-0.101424 and the value of Zernike spherical aberration coefficient of the eye + aspherical contact lens was 0.072820 μm. The proposed method allows us to design contact lenses that compensate for the spherical aberration of the eye from the Zernike polynomials. Although the design of contact lenses is to third order, we obtain a smaller spherical aberration than the chromatic aberration on the axis without use optimization routine.",

keywords = "Aberration of the eye and Zernike polynomials, Contact lens, Spherical aberration",

author = "O. Garcia-Lievanos and Emiliano Teran-Bobadilla and Hernandez-Flores, {Luis A.} and Leticia Sanchez-Gonzalez",

note = "Publisher Copyright: {\textcopyright} 2019 SPIE.; Current Developments in Lens Design and Optical Engineering XX 2019 ; Conference date: 12-08-2019",

year = "2019",

doi = "10.1117/12.2526476",

language = "Ingl{\'e}s",

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Garcia-Lievanos, O, Teran-Bobadilla, E, Hernandez-Flores, LA & Sanchez-Gonzalez, L 2019, Contact lens design to third order to compensate the spherical aberration of the eye from Zernike polynomials. En RB Johnson, VN Mahajan & S Thibault (eds.), Current Developments in Lens Design and Optical Engineering XX., 111040O, Proceedings of SPIE - The International Society for Optical Engineering, vol. 11104, SPIE, Current Developments in Lens Design and Optical Engineering XX 2019, San Diego, Estados Unidos, 12/08/19. https://doi.org/10.1117/12.2526476

Contact lens design to third order to compensate the spherical aberration of the eye from Zernike polynomials. / Garcia-Lievanos, O.; Teran-Bobadilla, Emiliano; Hernandez-Flores, Luis A. et al.
Current Developments in Lens Design and Optical Engineering XX. ed. / R. Barry Johnson; Virendra N. Mahajan; Simon Thibault. SPIE, 2019. 111040O (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11104).

Producción científica: Capítulo del libro/informe/acta de congreso › Contribución a la conferencia › revisión exhaustiva

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AU - Hernandez-Flores, Luis A.

AU - Sanchez-Gonzalez, Leticia

PY - 2019

Y1 - 2019

N2 - To compensate the spherical aberration of the eye using the conic constant of the first surface of a contact lens for different refractive errors. Refractive errors were simulated by modifying only the first curvature of the cornea. For every refractive error was calculating Zernike polynomials using Optics Software for Layout and Optimization (OSLO) EDU edition with and without contact lens. To calculate the conic constant of the contact lens we use the Seidel sums for thin lenses from the longitudinal spherical aberration as it proposes V. Mahajan. The value of Zernike spherical aberration coefficient for the eye with farsightedness (+ 5.00 D) + spherical contact lens was 0.142691 μm. The conic constant value to compensate the spherical aberration was-0.222995 and the value of Zernike spherical aberration coefficient of the eye + aspherical contact lens was 0.004354 μm. The value of Zernike spherical aberration coefficient for the eye with myopia (-5.00 D) + spherical contact lens was 0.144505 μm. The conic constant value to compensate the spherical aberration was-0.101424 and the value of Zernike spherical aberration coefficient of the eye + aspherical contact lens was 0.072820 μm. The proposed method allows us to design contact lenses that compensate for the spherical aberration of the eye from the Zernike polynomials. Although the design of contact lenses is to third order, we obtain a smaller spherical aberration than the chromatic aberration on the axis without use optimization routine.

AB - To compensate the spherical aberration of the eye using the conic constant of the first surface of a contact lens for different refractive errors. Refractive errors were simulated by modifying only the first curvature of the cornea. For every refractive error was calculating Zernike polynomials using Optics Software for Layout and Optimization (OSLO) EDU edition with and without contact lens. To calculate the conic constant of the contact lens we use the Seidel sums for thin lenses from the longitudinal spherical aberration as it proposes V. Mahajan. The value of Zernike spherical aberration coefficient for the eye with farsightedness (+ 5.00 D) + spherical contact lens was 0.142691 μm. The conic constant value to compensate the spherical aberration was-0.222995 and the value of Zernike spherical aberration coefficient of the eye + aspherical contact lens was 0.004354 μm. The value of Zernike spherical aberration coefficient for the eye with myopia (-5.00 D) + spherical contact lens was 0.144505 μm. The conic constant value to compensate the spherical aberration was-0.101424 and the value of Zernike spherical aberration coefficient of the eye + aspherical contact lens was 0.072820 μm. The proposed method allows us to design contact lenses that compensate for the spherical aberration of the eye from the Zernike polynomials. Although the design of contact lenses is to third order, we obtain a smaller spherical aberration than the chromatic aberration on the axis without use optimization routine.

KW - Aberration of the eye and Zernike polynomials

KW - Contact lens

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Garcia-Lievanos O, Teran-Bobadilla E, Hernandez-Flores LA, Sanchez-Gonzalez L. Contact lens design to third order to compensate the spherical aberration of the eye from Zernike polynomials. En Johnson RB, Mahajan VN, Thibault S, editores, Current Developments in Lens Design and Optical Engineering XX. SPIE. 2019. 111040O. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.2526476

Contact lens design to third order to compensate the spherical aberration of the eye from Zernike polynomials

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