An eye imaging apparatus can include a housing, an optical imaging system in the housing, and a light source in the housing to illuminate an eye. The optical imaging system can include an optical window at a front end of the housing with a concave front surface for receiving the eye as well as an imaging lens disposed rearward the optical window. The apparatus can comprise a light conditioning element configured to receive light from the light source and direct said light to the eye. The apparatus can further include an image sensor in the housing disposed to receive an image of the eye from the optical imaging system. In various embodiments, light conditioning element includes at least one multi-segment surface. In some embodiments, the housing is provided with at least one hermitic seal, for example, with the optical window. In some embodiments, time sequential illumination is employed.

A model eye is disposed on a reference light path of reference light in a reference optical system so as to reflect or scatter the reference light at a model retina in order to form an interference optical system used to obtain interference light from the reference light of the reference optical system and signal light illuminated onto an examined eye in a signal optical system.

A retinal imager for imaging a retina of an eye includes an illumination source operable to generate illumination light and a beam splitter operable to receive the illumination light and direct the illumination light along an optical axis. The retinal imager also includes a field lens disposed along the optical axis and an objective lens disposed along the optical axis and operable to contact a cornea of the eye. An aerial image is formed adjacent to the field lens. The retinal imager further includes an image sensor and one or more lenses disposed along the optical axis between the beam splitter and the image sensor. The one or more lenses are operable to form a sensor image at the image sensor.

A single imaging platform for making in vivo measurements of an individual's eye, where the measurements are sufficient to construct an optical model of the individual's eye. The platform includes a plenoptic opthalmic camera and an illumination module. In one configuration, the plenoptic opthalmic camera captures a plenoptic image of a corneal anterior surface of the individual's eye. In another configuration, the plenoptic opthalmic camera operates as a wavefront sensor to measure a wavefront produced by the individual's eye.

A method and system for correcting vision in an eye that uses a wavefront-customized phakic or pseudophakic Intraocular Lens (IOL), the method comprising: (1) measuring wavefront aberrations of the eye; (2) designing a wavefront-customized correction profile for an IOL; (3) creating a customized IOL with the customized correction profile; and (4) implanting the customized IOL in the eye, without having to remove the natural lens. Alternatively, an uncorrected IOL is implanted first, followed by scanning a femtosecond laser spot across the implanted IOL to locally change the Index of Refraction of the IOL material and create an in-situ customized IOL.

A retinal imager for imaging a retina of an eye includes an illumination source operable to generate illumination light and a beam splitter operable to receive the illumination light and direct the illumination light along an optical axis. The retinal imager also includes a field lens disposed along the optical axis and an objective lens disposed along the optical axis and operable to contact a cornea of the eye. An aerial image is formed adjacent to the field lens. The retinal imager further includes an image sensor and one or more lenses disposed along the optical axis between the beam splitter and the image sensor. The one or more lenses are operable to form a sensor image at the image sensor.

A photorefraction ocular screening device for assessing vision and corresponding disorders associated with the human ocular system is provided. More specifically, the present invention provides for a photorefraction ocular screening device employing advanced methods of pupil detection and refractive error analysis. The photorefraction ocular screening device is comprised of an LED arrangement configured with a plurality of irradiation sources serving as visual stimuli, wherein the visual stimuli may be presented in varying illumination patterns to the pupils of an examinee for expanding the range of ocular responses that can be used to determine refractive error.

An appliance for recording an image of an ocular fundus includes an irradiating device with a radiation source and optical components for generating an illumination strip. A scanning device is set up to cause a scanning movement of the illumination strip for the purpose of scanning the ocular fundus. An optoelectronic sensor senses detection light issuing from the ocular fundus. The optoelectronic sensor has a plurality of sensor rows and is set up such that charges contained in one sensor row are each shifted, with a time delay, into a further sensor row. A control means is connected to the scanning device and/or to the optoelectronic sensor and is set up to control the scanning movement and/or the time delay.

Disclosed are example embodiments of a system of retinal three-dimensional (3D) imaging. The system of retinal 3D imaging includes an image sensor within a light path and a reimaging corrective optics module within the light path. The system of retinal 3D imaging also includes an objective lens in the light path and a baffle-and-illumination module in the light path. In an aspect, the reimaging corrective optics module is in front of the image sensor, the objective lens is in front of the reimaging corrective optics module, and the baffle-and-illumination module is between the objective lens and the reimaging corrective optics module.

A method for controlling alignment of an eye in an ophthalmological imaging device that includes a formation, on a two-dimensional detection plane, of an image of an element located in a plane of the pupil of the eye using an imaging optical element. The method further includes a determination of a lateral position of the pupil of the eye with respect to a point of origin of a reference frame of an imaging system in the eye space based on the position of the image in the detection plane. The method further includes an analysis of a state of focus of the image in two regions of the detection plane. The method further includes a determination of an axial position of the pupil of the eye with respect to the point of origin of the reference frame based on the analysis of the state of focus.