A retinal imaging system includes an image sensor for acquiring a retinal image and a dynamic illuminator for illuminating a retina to acquire the retinal image. The dynamic illuminator includes a center baffle along with first and second illumination arrays. The center baffle extends from and surrounds an aperture through which an image path for the retinal image passes before reaching the image sensor. The first illumination array extends out from first opposing sides of the aperture along a first linear axis. The second illumination array extends out from second opposing sides of the aperture along a second linear axis that is substantially orthogonal to the first linear axis.

A mobile communication device-based corneal topography system includes an illumination system, an imaging system, a topography processor, an image sensor, and a mobile communication device. The illumination system is configured to generate an illumination pattern reflected off a cornea of a subject. The imaging system is coupled to an image sensor to capture an image of the reflected illumination pattern. A topography processor is coupled to the image sensor to process the image of the reflected illumination pattern. The mobile communications device includes a display, the mobile communications device is operatively coupled to the image sensor. The mobile communications device includes a mobile communications device (MCD) processor. A housing at least partially encloses one or more of the illumination system, the imaging system, or the topography processor.

An ophthalmic apparatus to examine an examinee's eye includes: a first optometry unit to perform a first examination of the examinee's eye; a second optometry unit to perform a second examination of the examinee's eye; a drive unit to cause relative movement of the first and second optometry units in three-dimensional manner relative to the examinee's eye; a controller to control the drive unit; a selection receiving unit to receive a selection signal representing at least one selected from the first second examinations; and a face photographing unit to photograph a face image including at least one of examinee's right and left eyes. The controller switches, according to the selection signal, between a first path for alignment of the first optometry unit with the eye detected from the face image and a second path for alignment of the second optometry unit with the eye detected from the face image.

Ophthalmic imaging devices and related methods employ self-alignment of a user with an optical axis of the imaging device. An ophthalmic imaging device includes a retinal imaging assembly, a housing assembly, and a viewer assembly. The retinal imaging assembly has an optical axis. The retinal imaging assembly is attached to the housing. The housing assembly is configured to rest on a horizontal surface during operation of the retinal imaging assembly. The optical axis is oriented at an angle from the horizontal surface when the housing assembly rests on the horizontal surface. The viewer assembly is coupled with the housing assembly. The viewer assembly includes an interface surface shaped for engagement with each head of a plurality of different user's and to accommodate repositioning of the head to align a pupil of the user with the optical axis.

A measuring method for measuring rotation characteristics of an eyeball of a subject includes: showing display information on a display screen, at a position separated from a reference position, the display screen being shown in front of the eyeball of the subject by a display device that is secured to a head of the subject, the reference position being where a front line of sight of the eyeball of the subject who looks forward straightly, crosses the display screen; changing a direction of a line of sight from the eyeball to the display information by switching the display information to other contents while changing a displayed position of the display information; and judging whether the subject can recognize the contents of the display information at the changed position, to measure the rotation characteristics of the eyeball.

An ophthalmologic apparatus includes: an objective lens that faces a subject's eye; an alignment light emitting unit that irradiates the subject's eye with alignment light to perform measurement of alignment between the objective lens and the subject's eye; an alignment reflection light receiving unit that receives alignment reflection light, which is a reflection of the alignment light from the subject's eye; an anterior segment camera that receives corneal reflection light; and a holder positioned between the anterior segment camera and the objective lens to hold the anterior segment camera, wherein the holder includes an imaging transmissive portion that transmits the corneal reflection light to the anterior segment camera, a first light-transmissive portion that transmits the alignment light from the alignment light emitting unit, and a second light-transmissive portion that transmits the alignment reflection light from the subject's eye.

An optical coherence tomography (OCT) system for imaging a retina applies a user specific focus correction to focus a sample arm light beam on the user’s retina. An OCT image detector generates an OCT signal. A control unit monitors the OCT signal, controls a reference arm optical path length adjustment mechanism to identify a length of the reference arm optical path for which the OCT signal corresponds to an OCT image of the retina, and varies an operational parameter of the sample arm light beam focus mechanism over a range, while maintaining the length of the reference arm optical path for which the OCT signal corresponds to the OCT image of the retina, to identify a focus correction for the user, based on the OCT signal, for application to the sample arm light beam.

This application relates to a fundus oculi imaging device and a fundus oculi imaging method including the same. In one aspect, the fundus oculi imaging device includes a housing and a first imaging module that is installed to be movable in the housing and captures a retinal image of an examinee. The fundus oculi imaging device may also include a light irradiation module moving along with the first imaging module in the housing and irradiating light to an eye of the examinee. The fundus oculi imaging device may further include a second imaging module installed on a side of the housing and capturing an image of a cornea or a pupil, to which light is irradiated from the light irradiation module, of the examinee.

A system for testing and/or training the vision of a user is disclosed herein. The system includes a motion sensing device, a visual display device having an output screen, and a data processing device operatively coupled to the motion sensing device and the visual display device. In one embodiment, the data processing device is programmed to generate and display a configuration of a visual object on the visual display device during the same cycle of rotational head displacement when the actual head velocity or speed for the user reaches or exceeds a prescribed threshold percentage of the target velocity or speed. In another embodiment, the data processing device is programmed to increase a value of a prescribed amplitude or period for the head rotational displacement of the user for a successive trial of a test or training routine when a peak head velocity or speed is determined to have increased.

An ophthalmological topographer is disclosed. The ophthalmological topographer includes a corneal topographer and a scleral measurement device including one or more scleral projection systems. Methods of determining topography are also disclosed.