The Optical Design of the Human Eye: a Critical Review

Navarro, Rafael

doi:10.3921/joptom.2009.3

Cited by 100 publications

(71 citation statements)

References 94 publications

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“…Many of the proposrd models of the human eye often show good much with experimental data but still some discrepancies exist [12,13]. There is no a universal model [13]. On the other hand, these discrepancies are associated with the wide angle viewing [12,13] that is not considered in the paraxial approximation.…”

Section: Introductionmentioning

confidence: 93%

“…There is no a universal model [13]. On the other hand, these discrepancies are associated with the wide angle viewing [12,13] that is not considered in the paraxial approximation. Moreover, by studying a paraxial image formation, it is not necessary to take into account variations of the refractive indexes in the real human eye [12][13][14][15].…”

Section: Introductionmentioning

confidence: 94%

“…Optics of the human eye has been a subject of intensive investigations since development of optical instruments. Many of the proposrd models of the human eye often show good much with experimental data but still some discrepancies exist [12,13]. There is no a universal model [13].…”

Section: Introductionmentioning

confidence: 99%

“…A great variety of models describing the optics of the human eye, which itself poses a formidable challenge and is a complex optical system with evolutionary optimized design, have been proposed [12][13][14][15]. The variety of the models reflects the fact that all they are incomplete.…”

Section: Coupling With the Optical System Of The Eyementioning

confidence: 99%

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Assessment of minimum permissible geometrical parameters of a near-to-eye display

Valyukh

Slobodyanyuk

2015

Appl. Opt.

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Light weight and small dimensions are some of the most important characteristics of near-to-eye displays (NEDs). These displays consist of two basic parts: a microdisplay for generating an image and supplementary optics in order to see the image. Nowadays, the pixel size of microdisplays may be less than 4 mu m, which makes the supplementary optics the major factor in defining restrictions on a NED dimensions or at least on the distance between the microdisplay and the eye. The goal of the present work is to find answers to the following two questions: how small this distance can be in principle and what is the microdisplay maximum resolution that stays effective to see through the supplementary optics placed in immediate vicinity of the eye. To explore the first question, we consider an aberration-free magnifier, which is the initial stage in elaboration of a real optical system. In this case, the paraxial approximation and the transfer matrix method are ideal tools for simulation of light propagation from the microdisplay through the magnifier and the human eyes optical system to the retina. The human eye is considered according to the Gullstrand model. Parameters of the magnifier, its location with respect to the eye and the microdisplay, and the depth of field, which can be interpreted as the tolerance of the microdisplay position, are determined and discussed. The second question related to the microdisplay maximum resolution is investigated by using the principles of wave optics. (C) 2015 Optical Society of Americ

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Section: Introductionmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Section: Coupling With the Optical System Of The Eyementioning

confidence: 99%

See 2 more Smart Citations

Assessment of minimum permissible geometrical parameters of a near-to-eye display

Valyukh

Slobodyanyuk

2015

Appl. Opt.

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“…Surface elevation and normals can be evaluated efficiently at any position algebraically. This modeling represents only a rough approximation to a human crystalline lens, which has a non-homogeneous gradient index 69 -however most kinds of artificial lenses can be specified this way, including toric and aspheric lenses.…”

Section: Discussionmentioning

confidence: 99%

The Individual Virtual Eye: a Computer Model for Advanced Intraocular Lens Calculation

Einighammer

Oltrup

Bende

et al. 2009

Journal of Optometry

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PURPOSE:To describe the individual virtual eye, a computer model of a human eye with respect to its optical properties. It is based on measurements of an individual person and one of its major application is calculating intraocular lenses (IOLs) for cataract surgery. METHODS: The model is constructed from an eye's geometry, including axial length and topographic measurements of the anterior corneal surface. All optical components of a pseudophakic eye are modeled with computer scientific methods. A spline-based interpolation method efficiently includes data from corneal topographic measurements. The geometrical optical properties, such as the wavefront aberration, are simulated with real ray-tracing using Snell's law. Optical components can be calculated using computer scientific optimization procedures. The geometry of customized aspheric IOLs was calculated for 32 eyes and the resulting wavefront aberration was investigated. RESULTS: The more complex the calculated IOL is, the lower the residual wavefront error is. Spherical IOLs are only able to correct for the defocus, while toric IOLs also eliminate astigmatism. Spherical aberration is additionally reduced by aspheric and toric aspheric IOLs. The efficient implementation of time-critical numerical ray-tracing and optimization procedures allows for short calculation times, which may lead to a practicable method integrated in some device. CONCLUSIONS: The individual virtual eye allows for simulations and calculations regarding geometrical optics for individual persons. This leads to clinical applications like IOL calculation, with the potential to overcome the limitations of those current calculation methods that are based on paraxial optics, exemplary shown by calculating customized aspheric IOLs. (J Optom 2009;2:70-82 ©2009 Spanish Council of Optometry) KEY WORDS: real ray-tracing; Snell's law; corneal topography; wavefront aberration; intraocular lens calculation. RESUMEN OBJETIVO:Describir el ojo virtual individualizado, que es un modelo computacional de ojo humano con respecto a sus propiedades ópticas. Está basado en las medidas realizadas en cada persona, de manera individual. Una de sus principales aplicaciones es el cálculo de lentes intraoculares (LIO) para cirugía de cataratas. MÉTODOS:El modelo está construido a partir de datos de geometría ocular; en particular, la longitud axial y las medidas topográficas de la cara anterior de la córnea. Todos los componentes ópticos de un ojo pseudofáquico se modelan por medio de métodos computacionales científicos. El método de interpolación por splines permite incluir de manera eficiente los datos obtenidos en las medidas de topografía corneal. Las propiedades relacionadas con la óptica geométrica, como el patrón de aberración del frente de onda, se obtienen a partir de la simulación de un trazado de rayos reales, el cual emplea la ley de Snell. Los componentes ópticos se pueden calcular empleando procedimientos computacionales de optimización. Para 32 ojos distintos, se calculó la geometría de la c...

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Fundamentals of Head‐Mounted Displays for Virtual and Augmented Reality

2020

Introduction to Flat Panel Displays

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The Optical Design of the Human Eye: a Critical Review

Cited by 100 publications

References 94 publications

Assessment of minimum permissible geometrical parameters of a near-to-eye display

Assessment of minimum permissible geometrical parameters of a near-to-eye display

The Individual Virtual Eye: a Computer Model for Advanced Intraocular Lens Calculation

Fundamentals of Head‐Mounted Displays for Virtual and Augmented Reality

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