A method for improving stereoacuity; it includes presenting weak eye visual information to a weak eye of the patient and dominant eye visual information to a dominant eye of the patient, where a level of the weak eye visual information and a level of the dominant eye visual information are set to an initial ratio; gradually adjusting the initial ratio such that the level of the dominant eye visual information gradually approaches the level of the weak eye visual information; continuous after the previous period of time, setting the level of the weak eye visual information and the level of the dominant eye visual information to a second ratio and gradually adjusting the second ratio such that the level of the dominant eye visual information gradually approaches the level of the weak eye visual information.

A method for improving stereoacuity; it includes presenting weak eye visual information to a weak eye of the patient and dominant eye visual information to a dominant eye of the patient, where a level of the weak eye visual information and a level of the dominant eye visual information are set to an initial ratio; gradually adjusting the initial ratio such that the level of the dominant eye visual information gradually approaches the level of the weak eye visual information; continuous after the previous period of time, setting the level of the weak eye visual information and the level of the dominant eye visual information to a second ratio and gradually adjusting the second ratio such that the level of the dominant eye visual information gradually approaches the level of the weak eye visual information.

A vision training device includes a housing having at least one eyepiece unit corresponding to an eye of a user, a display that displays a target image in front of a fixation axis of the user, a lens arranged between the eyepiece unit and the display unit, a movable unit capable of moving at least one of the display and the lens along the fixation axis, and a control unit that sets at least one training range within a movable range of the display and the lens and controls the movable unit such that at least one of the display and the lens is moved within the training range.

A vision training device includes a housing having at least one eyepiece unit corresponding to an eye of a user, a display that displays a target image in front of a fixation axis of the user, a lens arranged between the eyepiece unit and the display unit, a movable unit capable of moving at least one of the display and the lens along the fixation axis, and a control unit that sets at least one training range within a movable range of the display and the lens and controls the movable unit such that at least one of the display and the lens is moved within the training range.

Exemplary light control devices and methods provide a regional variation of visual information and sampling (“V-VIS”) of an ocular field of view that improves or stabilizes vision, ameliorates a visual symptom, reduces the rate of vision loss, or reduces the progression of an ophthalmic or neurologic condition, disease, injury or disorder. The V-VIS devices and methods generate a moving aperture effect anterior to a retina that samples and delivers to the retina environmental light from an ocular field of view at a sampling rate between 50 hertz and 50 kilohertz. Certain of these V-VIS devices and methods may be combined with augmented or virtual reality, vision measurement, vision monitoring, or other therapies including, but not limited to, pharmacological, gene, retinal replacement and stem cell therapies.

A system for improving a patient's vision, comprising means for diagnosing and monitoring a deterioration in macular vision or macular vision loss in the patient's eye, and means for augmenting the use of a preferred retinal location (PRL) and eccentric fixation in case the deterioration in macular vision or macular vision loss was detected. A method for improving a patient's vision, comprising: diagnosing and monitoring a deterioration in macular vision or macular vision loss in the patient's eye; and augmenting the use of a preferred retinal location (PRL) and eccentric fixation in case the deterioration in macular vision or macular vision loss was detected.

An example apparatus for predicting eye fatigue includes an image receiver to receive an image of an eye. The apparatus also includes a fatigue predictor to predict eye fatigue in the eye based on a calculated blood vessel density score of the eye in the image. The apparatus further includes an alert generator to generate an alert in response to predicting the eye fatigue.

A wearable training apparatus has a vision-control assembly for engaging a user's face about the user's eyes. The vision-control assembly has a see-through area about the user's eyes and an opaque area surrounding the see-through area at least on a temporal side and an inferior side thereof. The opaque area is for substantially blocking at least major portions of the natural monocular vision-areas of a natural field of vision (FOV) of the user's eyes, said natural monocular vision-areas being peripheral to a natural binocular vision-area on respectively temporal sides. The see-through area is for forming a reduced FOV about a gaze direction. The reduced FOV has a span encompassing at least a major portion of the natural binocular vision-area of the natural FOV of the user's eyes about the gaze direction thereof, said natural binocular vision-area being at an angular center of the natural FOV.

A wearable training apparatus has a vision-control assembly for engaging a user's face about the user's eyes. The vision-control assembly has a see-through area about the user's eyes and an opaque area surrounding the see-through area at least on a temporal side and an inferior side thereof. The opaque area is for substantially blocking at least major portions of the natural monocular vision-areas of a natural field of vision (FOV) of the user's eyes, said natural monocular vision-areas being peripheral to a natural binocular vision-area on respectively temporal sides. The see-through area is for forming a reduced FOV about a gaze direction. The reduced FOV has a span encompassing at least a major portion of the natural binocular vision-area of the natural FOV of the user's eyes about the gaze direction thereof, said natural binocular vision-area being at an angular center of the natural FOV.

A system for testing and/or training the vision of a user is disclosed herein. The system includes at least one camera, a visual display device having an output screen, and a data processing device operatively coupled to the at least one camera and the visual display device. In one embodiment, the data processing device is programmed to determine a head position, head velocity, and/or head speed of a user during a vision test or vision training routine from a plurality of images of the head of the user captured by the at least one camera. In another embodiment, the data processing device is programmed to determine, based upon an input signal received from a user input device, a contrast display setting for a screen background relative to at least one visual target, the contrast display setting enabling the user to gradually adapt to increasing levels of visual stimulation.