The visual function test device of an embodiment comprises a test subject display device and an operator display device. A target display portion displays a target image to be viewed by the test subject onto the test subject display device. A visual axis estimation portion estimates a visual axis of the test subject when the target image is viewed. A position display portion displays a display position of the test target image and a viewpoint position that corresponds to the estimated visual axis, onto the operator display device, and thus a tester can objectively recognize a gazing state of the test subject and surely perform the test, which enhances the reliability of the test.

A subjective and objective integrated precise optometry device, and an optometry method are provided. The device has a left eye optical path and a right eye optical path. Each of the single eye optical paths comprises a human eye refraction objective measurement subsystem, a human eye refraction correction subsystem, an eyeball positioning subsystem, and a subjective visual function testing subsystem. The device has functions such as objective measurement for monocular and binocular refraction, continuous subjective optometry, interpupillary distance measurement, and monocular and binocular visual function measurement (comprising, but not limited to, vision and stereopsis), and can implement subjective and objective integrated precise monocular and binocular optometry. Additionally, the device has such functions as rapid measurement and screening of human eye refraction, and preliminary screening of human eye diseases (except for ametropia), and can be used for optometry, ophthalmological clinical triage, population ametropia screening and monitoring, etc.

An ophthalmological measuring device including an ocular measuring unit including a front face provided with a frame encircling a translucent plate the size and curvature of which are suitable for covering the ocular field of said patient, a device for providing uniform backlighting of the translucent plate, located behind the translucent plate, at least one camera equipped with an objective placed in line with a hole in the translucent plate, one or more point light sources in apertures on the edges of the translucent plate, for illuminating the eyes of the patient, and means for fastening one or more additional ophthalmological measuring devices to the translucent plate.

A vision screening device, a vision screening system, a vision impairment screening device, vision impairment screening system, processes, method of assessments, and methods of use are presented. The present disclosure provides a vision screening system and device, including obtaining flash imagery in order to be used for analysis of visual function. More specifically, and without limitation, the present disclosure provides the state of the art with a system for attracting the gaze of a user and controlling accommodation for obtaining proper imagery as is needed for visual analysis. Furthermore, and without limitation, the present disclosure provides a vision system for capturing visual performance of a user.

An ophthalmic device including an illumination module which scans light across a region of the retina of an eye when the pupil is disposed at a focal point of the illumination module. The ophthalmic device further comprises components (2, 3-1, 4-1) for: aligning the pupil with the focal point; monitoring a position of the pupil relative to the focal point and maintaining the alignment based on the monitored position; aligning a scan location of the illumination module on the retina to a target scan location while the alignment of the pupil with the focal point is being maintained, wherein the illumination module performs a scan at the target scan location. The ophthalmic device further maintains the scan location at the target scan location while the alignment of the pupil with the focal point is being maintained, using scan location correction information based on retinal feature information.

Apparatus and method for imaging fundus of eye. The apparatus (100) includes an optical system (116), an image sensor (114) to capture a still image or a video through the optical system (116), a user interface (102) including a display (104) to display data to a user of the apparatus, and one or more processors (106). The one or more processors (106) cause performance of at least the following: setting the image sensor (114) to capture an aiming video; detecting a retina of the eye in the aiming video; setting the display (104) to display the aiming video with a highlight of the detected retina; and setting the image sensor (114) to capture one or more final still images of the fundus or a final video of the fundus.

The invention provides methods and kits for detecting, screening, quantifying or localizing the etiology for reduced or impaired cranial nerve function or conduction; localizing a central nervous system lesion; detecting, diagnosing or screening for increased intracranial pressure, pressure or disruption of central nervous system physiology as seen with concussion; or detecting, diagnosing, monitoring progression of or screening for a disease or condition featuring increased intracranial pressure or concussion by tracking eye movement of the subject. The invention also provides methods and kits useful for detecting, screening for or quantitating disconjugate gaze or strabismus, useful for diagnosing a disease characterized by disconjugate gaze or strabismus in a subject, useful for detecting, monitoring progression of or screening for a disease or condition characterized by disconjugate gaze or strabismus in a subject or useful for quantitating the extent of disconjugate gaze or strabismus. Further, the invention provides methods for assessing or quantifying structural and non-structural traumatic brain injury or diagnosing a disease characterized by or featuring structural and non-structural traumatic brain injury.

A retinal imaging system includes an image sensor for acquiring a retinal image and an illuminator for illuminating a retina to acquire the retinal image. The illuminator surrounds an aperture through which an image path for the retinal image passes before reaching the image sensor. Illumination sources surround the aperture.

A method to optimize learning based upon ocular information of a subject includes providing a video camera for recording a close-up view of a subject's eye. A first electronic display shows a plurality of educational subject matter to the subject. A second electronic display shows an output to an instructor. Changes in ocular signals of the subject are processed through the use optimized algorithms. A cognitive state model determines a low to a high cognitive load experienced by the subject. The cognitive state model is evaluated based on the changes in the ocular signals for determining a probability of the low to the high cognitive load experienced by the subject. The probability of the low to the high cognitive load experienced by the subject is displayed to the instructor.

An evaluation device includes an image data acquisition unit that acquires image data on eyeballs of a subject, a point-of-gaze detector that detects positional data on a point of gaze of the subject based on the image data, a display controller that causes a display unit to display a plurality of routes that connect a start point and an end point and a plurality of target subjects that are arranged along the routes, an area setting unit that sets a route area corresponding to each of the routes and a target area corresponding to each of the target subjects on the display unit, a determination unit that determines whether a point of view of the subject is present in the route area and the target area based on the positional data on the point of gaze, and an evaluation unit.