Illumination can be evaluated for patient using a system including a housing, an adjustable light source mechanically coupled to the housing and configured to illuminate an object for viewing by the patient on an axis substantially perpendicular to a surface of the object. A user-adjustable input coupled to the adjustable light source is to obtain information from a user indicative of a calibrated illuminance and a color property to be provided by the adjustable light source including providing a range of adjustable illuminance and color properties selectable by the user. The adjustable light source can be configured to provide light having an illuminance in excess of 300 lux, and the housing can be configured to provide a first specified distance between the adjustable light source and the object for viewing and to obstruct viewing of the light source directly by the patient.

A method includes obtaining spatial information indicating positions of electronic displays relative to a wearable device and selecting a first display location on an electronic display other than a wearable display of the wearable device based on the spatial information indicating that the first display location on the electronic display corresponds to a first field location of a visual field. The method further includes selecting a second display location on the wearable device based on the spatial information indicating that the second display location on the wearable display corresponds to a second field location of the visual field. The method further includes causing presentation of (i) a first stimulus at the first display location on the electronic display and (ii) a second stimulus at the second display location on the wearable device and generating ocular anomaly information based on feedback information related to the presented stimuli.

When displaying visual targets on a planar display element and performing vision examinations, the size of the visual target visible to the subject changes according to the position at which the visual target is displayed. This vision examination device includes: a planar display element that displays visual targets to a subject of a vision examination; and a display optical system provided upon an optical axis between an eyeball position at which an eyeball of the subject is arranged and a display screen of the planar display element. The display optical system includes an f-θ optical system having a proportional relationship between an image height on the display screen of the planar display element and the angle of incidence θ for the main light rays when the subject views the visual target through the display optical system from the eyeball position.

A system for eyesight diagnosis may include a vision test unit and a controller. The vision test unit may include at least one eye movement tracking unit configured to track the movement of a portion of the eye, at least one screen for visual stimulation and a shuttering unit configured to controllably block the field of view (FOV) of each eye separately. The controller may be configured to: display to a patient a first visual stimulation on the at least one screen, cause the shuttering unit to block the FOV of a first eye of the patient while unblocking the FOV of a second eye, receive a first signal indicative of the second eye movement of the patient from the at least one eye movement tracking unit and diagnose the patient's eyesight based on the received first signal.

Configurations are disclosed for a health system to be used in various healthcare applications, e.g., for patient diagnostics, monitoring, and/or therapy. The health system may comprise a light generation module to transmit light or an image to a user, one or more sensors to detect a physiological parameter of the user's body, including their eyes, and processing circuitry to analyze an input received in response to the presented images to determine one or more health conditions or defects.

A device may include a display screen and a generally triangular shaped body with first, second, and third sides, where the display screen may be generally parallel with the first side. The device may be configured such that either of the second side and third side may be oriented generally upwards during operation. The device may also include a sensor configured to detect whether the second or the third side is oriented generally upwards, and a computing device configured to orient an image to be displayed on the display screen based on whether the second or the third side is oriented generally upwards.

A system and a method for holographic eye testing device are disclosed. The system renders one or more three dimensional objects within the holographic display device. The system updates the rendering of the one or more three dimensional objects within the holographic display device, by virtual movement of the one or more three dimensional objects within the level of depth. The system receives input from a user indicating alignment of the one or more three dimensional objects after the virtual movement. The system determines a delta between a relative virtual position of the one or more three dimensional objects at the moment of receiving input and an optimal virtual position and generates prescriptive remedy based on the delta.

Systems and methods are provided for post-hoc correction of calibration errors in eye tracking data, which take into consideration calibration errors that result from changes in user position during a user session in which the user's fixations on a display screen are captured and recorded by an eye tracking system, and which take into consideration errors that occur when the user looks away from a displayed target item before selecting the target item.

Systems and methods for imaging tissue are described. Particularly, systems and methods of imaging an inner limiting membrane, epi-retinal membrane, or posterior vitreous cortex of a patient's eye are disclosed. Imaging an inner limiting membrane, epi-retinal membrane, or posterior vitreous cortex may include applying a stain to the inner limiting membrane, epi-retinal membrane, or posterior vitreous cortex of the patient's eye, causing the stain to produce fluorescent light having a wavelength within a near-infrared range, capturing the fluorescent light, and producing an Optical Coherence Tomography (OCT) image of the inner limiting membrane, epi-retinal membrane, or posterior vitreous cortex with an OCT imaging system that is configured to detect light within the near-infrared range.

A Progressive Lens Simulator comprises an Eye Tracker, for tracking an eye axis direction to determine a gaze distance, an Off-Axis Progressive Lens Simulator, for generating an Off-Axis progressive lens simulation; and an Axial Power-Distance Simulator, for simulating a progressive lens power in the eye axis direction. The Progressive Lens Simulator can alternatively include an Integrated Progressive Lens Simulator, for creating a Comprehensive Progressive Lens Simulation. The Progressive Lens Simulator can be Head-mounted. A Guided Lens Design Exploration System for the Progressive Lens Simulator can include a Progressive Lens Simulator, a Feedback-Control Interface, and a Progressive Lens Design processor, to generate a modified progressive lens simulation for the patient after a guided modification of the progressive lens design. A Deep Learning Method for an Artificial Intelligence Engine can be used for a Progressive Lens Design Processor. Embodiments include a multi-station system of Progressive Lens Simulators and a Central Supervision Station.