Abstract: A visual function detection apparatus includes: a display controller configured to cause an image for determination to be displayed in a display region on a display screen of a display unit and move the image for determination within the display region; a gazing point detector configured to detect a position of a gazing point of a test subject observing the display screen; a relation detector configured to detect relation information among a position of the image for determination on the display screen, a moving direction of the image for determination, and a moving direction of the gazing point; and a visual function detector configured to detect a visual function of the test subject based on the relation information.

Abstract: A vision testing apparatus has a frame including a face plate with at least one eye shield having a viewing slot positioned in a viewing direction perpendicular to the face plate, at least one variable lens element including an outer rail and multiple regions of varying diopter power having a width that is equal to or greater than the width of the viewing slot of the eye shield, and adjustable controls for moving the variable lens element in a direction perpendicularly to the viewing direction along a plane of the face plate. The testing apparatus is portable and can be used in developing nations where visual acuity is not corrected because of lack of access to optometric care.

Abstract: Systems and methods for continuous objective assessment are discussed herein. The systems and methods may comprise sensor(s), a processor, a clock, data storage, and a power source. The sensor(s) may continuously monitor viewing distances, light exposure, or the like, and the system may log corresponding time and/or duration information. Also provided herein are methods of treating, preventing, and/or diagnosing vision impairment risk. These systems and methods may provide warns, such as when detecting the viewing of materials too closely (e.g. ?30 cm), near to near intermediate viewing (e.g. ?70 cm) exceeding a predetermined time (e.g. ?20 min.) without a break, and/or not getting enough outdoor light exposure (e.g. at least 75 minutes of exposure at >1000 lux) for the day.

Abstract: The present disclosure provides a gaming system including an application that can be implemented using a dynamic testing game, wherein the system does not require glasses, goggles, or any other headwear. The system enables a test subject to be screened and treated for vision dysfunctions while engaging with a dynamic video game.

Abstract: The invention relates to a method for examining an eye of a patient by the patient themselves by means of an ophthalmological apparatus, said apparatus having front optics and an apparatus pupil. According to said method, the patient positions the ophthalmological apparatus relative to the eye, a measure of the deviation of the pupil of the eye from the apparatus pupil is determined, and a pupil correction signal is produced depending on the measure of the deviation, said pupil correction signal specifying a direction and/or a degree of the deviation and being output to the patient. The patient can use the pupil correction signal for repositioning in relation to the ophthalmological apparatus with a smaller deviation.

Abstract: An analysis unit determines at least two boundaries by determining; in a coordinate system indicating a correlation between a luminance contrast value between a luminance of an attention portion and a luminance of a background portion, and a luminance average value of a visual target including the attention portion and the background portion; the boundary between a region where a subject has a visibility and a region where the subject does not have the visibility for each combination of stimulus values of a color stimulus of a visual target.

Abstract: System, devices and methods are provided for providing a resident of a controlled-environment facility with services via a communications device, where access to software components, software features and/or content on the communication device may be restricted based on the results of a mental health assessment administered via the communication device. The communication device utilized by the resident connects to a resident communications system that provides use of requested software elements. If a requested software element is determined to be restricted, the resident must complete a mental health assessment that determines a distress level of the resident. The distress level may be determined based on inputs provided by the resident and sensor inputs collected by the communication device. If the mental health assessment indicates the distress level of the resident is below a threshold, the resident is allowed to utilize the software element.

Abstract: Various methods and systems for autonomously upgrading deployed resources in a distributed computing environment are provided. An autonomous upgrade system identifies updates such as operating system image updates and virtual machine extension updates for deployment in the distributed computing environment. The autonomous upgrade system identifies eligible tenants, identifies deployed resources that may be impacted by the identified update, batches the resources and upgrades the batched resources. The autonomous upgrade system performs a diagnostic test on upgraded resources to determine whether an upgrade was successful. In some embodiments, the diagnostic test is performed by executing a diagnostic script that can be provided by a tenant. The autonomous upgrade system can stop or pause the upgrade if various success metrics are not satisfied. In some embodiments, the autonomous upgrade system tests and certifies newly published updates for deployment to the distributed computing environment.

Abstract: Methods, devices, and systems are disclosed for determining refractive corrections of human eyes to reduce and eliminate image distortion associated with eyeglasses. In some embodiments, an objective refraction module is configured to measure refractive errors of an eye objectively, without subjective feedback from a tested subject. A computation module is configured to generate a plurality of objective prescriptions. A phoropter module is configured to perform a subjective refraction for determining a plurality of subjective spherical powers based on the plurality of objective prescriptions.

Abstract: A process for assessing at least one characteristic of a user's vision includes determining a characteristic of at least one camera of a mobile device; using the at least one camera, capturing at least one image of an object; determining, with reference to a portion of the at least one image composed of the object, a distance from the mobile device to the object at a time of capture of the at least one image; and receiving input from the user in response to material presented on the object.

Abstract: Described is a system that provides a vision test that may be implemented on various types of devices including a personal device such as a smartphone. The system may track potential vision abnormalities across an extended period of time by utilizing a comparison algorithm to compare results of vision tests to automatically determine whether the vision abnormality such as macular degeneration has progressed for a patient. Accordingly, the system provides an effective tool that may be deployed across a large portion of the population to provide early detection of potential vision loss.

Abstract: An ophthalmic instrument includes a carrier positionable relative to a test subject, and first and second measurement units mounted on the carrier by corresponding first and second parallelogram linkages. The first measurement unit, for example an autorefractor/keratometer, performs a first type of ophthalmic measurement, and is guided by the first parallelogram linkage to move relative to the carrier simultaneously in forward and downward directions from an idle position to a measurement position. The second measurement unit, for example a tonometer, performs a second type of ophthalmic measurement, and is guided by the second parallelogram linkage to move relative to the carrier simultaneously in forward and upward directions from an idle position to a measurement position. The first and second measurement units may each have a respective optical axis which aligns with a fixed measurement axis of the carrier when the measurement unit is in its measurement position.

Abstract: Methods, devices, and systems are disclosed for determining refractive corrections of human eyes to reduce and eliminate image distortion associated with eyeglasses. In some embodiments, an objective refraction module is configured to measure refractive errors of an eye objectively, without subjective feedback from a tested subject. A computation module is configured to generate a plurality of objective prescriptions. A phoropter module is configured to perform a subjective refraction for determining a plurality of subjective spherical powers based on the plurality of objective prescriptions.

Abstract: A vision testing apparatus is disclosed. The apparatus has a frame comprising a face plate with at least one eye shield having a viewing slot positioned in a viewing direction perpendicular to the face plate, at least one variable lens element including an outer rail and multiple regions of varying diopter power having a width that is equal to or greater than the width of the viewing slot of the eye shield, and adjustable controls for moving the variable lens element in a direction perpendicularly to the viewing direction along a plane of the face plate. The testing apparatus is portable and can be used in developing nations where visual acuity is not corrected because of lack of access to optometric care.

Abstract: 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.

Abstract: A system for use in performing ocular examinations, such as convergence and accommodation useful in diagnosing traumatic brain injury (including concussion), includes an assessment device. The assessment device includes a portable carrier having a visual target and a distance measurement component. The system may further include a communications channel and a companion device. The distance measurement component communicates via the communication channel with the companion device. The companion device stores one or more distances measured by the distance measurement component.

Abstract: A server in communication with a first device capable of receiving input from a camera attached to the first device, and a second device capable of displaying output, is provided. The server is configured to receive, from the first device, data relating to characteristics of the camera and characteristics of an image obtained by the camera of a screen of the second device; determine a screen pixel length of the screen; and provide instructions to the second device to display on the screen an object at a desired visual angle in response to the data received from the second device and the screen pixel length, while the first device is positioned at an arbitrary distance from the screen.

Abstract: A viewing target for a visual acuity and refraction measurement includes at least one line comprising a width dimension that is below a resolution limit width (hereinafter “RLW”) of a test subject visual acuity, and an adjustable length dimension that is initially set at greater than the RLW of the test subject visual acuity. A base, at least approximately intersecting the line, has a thickness along the direction of the length of the line that is greater than the RLW of the test subject visual acuity. The length dimension of the line is adjustable in increments small enough to effectively approximate the visual acuity of the test subject by determining a shortest resolvable line and a next smaller line that is not resolvable by the test subject.

Abstract: An eye examination device may include a body defining a handle and a retainer for a mirror. The device may further include a projection having a predefined length from the body. The predefined length of the projection is defined by a focal length of the mirror. The device may further include a light integrated in the retainer adjacent to the mirror.

Abstract: A solution for targeting a visual function of an observer is provided. The solution presents an animation for display to an observer. The animation includes a background and at least a portion of the animation also includes one or more foreground areas, each of which is located in a portion of the background. The background and the foreground area(s) include a set of common attributes substantially continuously changing during the animation and at least one different attribute between the background and the foreground area. At least one attribute of the background changes randomly during the animation. The at least one different attribute targets the visual function.

Abstract: An ophthalmic technician is present with a patient in an exam room to operate eye examination equipment and transmit patient information to remote location. At that remote location, a skilled technician is present to provide the necessary optical care, and may operate the phoropter from the remote location. Using video and/or teleconferencing equipment and a phoropter located in the patient examination room along with management software, the system works to determine the final optical prescription for the patient. That information, coupled with findings from other devices which are integrated with the management software, and that the patient uses locally, are reviewed by a remote-based optometrist or ophthalmologist.

Abstract: Safety of ophthalmologic laser treatment is improved. A laser treatment apparatus of an embodiment includes: a photographing system that photographs an eye; an irradiation system that irradiates aiming light of a preset pattern and treatment laser light onto a fundus of the eye; an irradiation-pattern determining part that determines an irradiation pattern of the treatment laser light based on a photograph image of the eye acquired by the photographing system and the preset pattern; and a controller that controls the irradiation system so as to irradiate the treatment laser light of the determined irradiation pattern.

Abstract: Technologies are generally described for generating depth data based on a spatial light pattern. In some examples, a method of generating depth data includes obtaining an image of one or more objects on which a spatial light pattern is projected, wherein blurring of the spatial light pattern in the image monotonously increases or decreases in a depth direction, calculating a value of a spatial frequency component of the image in a local image area around a pixel of interest, and determining depth data corresponding to the calculated value of the spatial frequency component by utilizing a preset relationship between depths and values of the spatial frequency component.

Abstract: A viewing target for a visual acuity and refraction measurement includes at least one line comprising a width dimension that is below a resolution limit width (hereinafter “RLW”) of a test subject visual acuity, and an adjustable length dimension that is initially set at greater than the RLW of the test subject visual acuity. A base, at least approximately intersecting the line, has a thickness along the direction of the length of the line that is greater than the RLW of the test subject visual acuity. The length dimension of the line is adjustable in increments small enough to effectively approximate the visual acuity of the test subject by determining a shortest resolvable line and a next smaller line that is not resolvable by the test subject.

Abstract: Medical tests and examinations are performed with consumer computing devices. The medical tests and examinations are selected and customized in accordance with conditions present in the testing environment, as well as physical characteristics of a user taking the test. The tests can include visual acuity tests, colorblindness tests and other medical tests, such as hearing tests.

Abstract: A visual function evaluation is performed using a sequence of interactions with a mobile device. A patient user may perform a variety of visual tests using the mobile device. The mobile device transmits the test results to a remote server implementing analysis of the visual function results using network service. The network service receives the test results, processes the results, and provides the processed results to a healthcare provider. The processed results may include trends of the user's visual function test performance. The healthcare provider, such as a physician, may optimize and administer treatment based on the data. Early detection of changes in visual function can enable the healthcare provider to individualize treatment, helping to prevent vision loss while minimizing visits to the office, discomfort, and expense.

Abstract: A method and apparatus for self-examination of the interior space of an individual's eye is disclosed.

Abstract: A visual distortion test is disclosed using a sequence of binary interactions with a mobile device, in which segments of the grid having no distortions are eliminated, and the segments with distortions are divided into smaller segments for further analysis. The test can quantify the visual distortion using a decreased number of steps, compared to sequential analysis of all the segments of the grid. The binary interaction or input to the mobile device is also easier for patients than graphic interactions with a conventional Amsler Grid. Early detection of changes in the visual distortion can enable the healthcare provider to individualize treatment, helping to prevent vision loss while minimizing visits to the office, discomfort, and expense.

Abstract: In an optometry apparatus controller provided in an electric optometry apparatus including an optical element disposed in front of an examinee's eye and a switch mechanism that electrically switches the optical element, for instructing the switching of the optical element, the controller includes a touchscreen configured to display an operation screen for operating the electric optometry apparatus main body, displays, as the operation screen, a graphic image of a manual optometry apparatus as viewed from an operator side, the manual optometry apparatus including a plurality of operating units and being configured to switch the optical element disposed in front of the eye by an operation with respect to the operating units, and outputs a control signal to the electric optometry apparatus main body based on a touch input with respect to the graphic image on the touchscreen.

Abstract: Medical tests and examinations are performed with consumer computing devices. The medical tests and examinations are selected and customized in accordance with conditions present in the testing environment, as well as physical characteristics of a user taking the test. The tests can include visual acuity tests, colorblindness tests and other medical tests, such as hearing tests.

Abstract: A visual function evaluation is performed using a sequence of interactions with a mobile device. A patient user may perform a variety of visual tests using the mobile device. The mobile device transmits the test results to a remote server implementing analysis of the visual function results using network service. The network service receives the test results, processes the results, and provides the processed results to a healthcare provider. The processed results may include trends of the user's visual function test performance. The healthcare provider, such as a physician, may optimize and administer treatment based on the data. Early detection of changes in visual function can enable the healthcare provider to individualize treatment, helping to prevent vision loss while minimizing visits to the office, discomfort, and expense.

Abstract: A viewing target for a visual acuity and refraction measurement includes at least one line comprising a width dimension that is below a resolution limit width (hereinafter “RLW”) of a test subject visual acuity, and an adjustable length dimension that is initially set at greater than the RLW of the test subject visual acuity. A base, at least approximately intersecting the line, has a thickness along the direction of the length of the line that is greater than the RLW of the test subject visual acuity. The length dimension of the line is adjustable in increments small enough to effectively approximate the visual acuity of the test subject by determining a shortest resolvable line and a next smaller line that is not resolvable by the test subject.

Abstract: A method, a system, and an information handling system dynamically provide individualized dynamic digital display correction for users of an electronic device. An information handling system detects a login of a first user profile that is associated with a first user. The information handling system then determines whether the first user profile has an associated first vision profile. In response to the first user profile having an associated first vision profile, a vision correction value associated with the first user is identified and a first change in image characteristics which may be applied to a graphical user interface (GUI) in order to achieve the vision correction value is calculated. A size of the display of the information handling system is detected and the first change in image characteristics is further adjusted based on this size before the adjusted image characteristic in image characteristics is applied.

Abstract: A binocular viewer, a method of measuring and training vision that uses a binocular viewer and a vision measurement and training system that employs a computer to control the binocular viewer. In one embodiment, the binocular viewer has left and right display elements and comprises: (1) a variable focal depth optical subsystem located in an optical path between the display elements and a user when the user uses the binocular viewer and (2) a control input coupled to the left and right display elements and the variable focal depth optical subsystem and configured to receive control signals operable to place images on the left and right display elements and vary a focal depth of the variable focal depth optical subsystem. In another embodiment, the binocular viewer lacks the variable focal depth optical subsystem, but the images include at least one feature unique to one of the left and right display elements.

Abstract: The present invention provides systems and methods for receiving an input to a sensory test or training activity by way of a touch-screen device. The touch-screen device receives instructions by way of a wireless communication protocol from a sensory testing and training device. The instructions may be comprised of a command to display a graphical element on the touch-screen device. As a result, the touch-screen device displays the graphical element on a display surface of the touch-screen device. Further, an input may be received from a subject in the form of a physical contact between the subject and the display surface of the touch-screen device. The input may be in response to a sensory test or a sensory training activity. Additionally, the touch-screen device communicates the input to the sensory training device utilizing a wireless communication protocol. In an additional embodiment, the touch-screen device provides feedback to a user.

Abstract: In one aspect, there is provided a handheld vision tester comprising a display, cursor control, interface port, and camera. The display delivers a series of images making up vision tests to a user who interacts with the vision tests by using the display and cursor control of the handheld vision tester. The camera verifies the user is taking the vision tests. The results of the vision tests are stored in the handheld communication device. The interface port allows for communication of the stored results of the vision tests with external devices. In another aspect, there is provided a calibration system for the handheld vision tester. The calibration system includes a stand to hold the handheld vision tester and a reflective surface substantially parallel to a display of the handheld vision tester.

Abstract: Systems and methods are disclosed for evaluating human eye tracking. One method includes receiving data representing the location of and/or information tracked by an individual's eye or eyes before, during, or after the individual performs a task; identifying a temporal phase or a biomechanical phase of the task performed by the individual; identifying a visual cue in the identified temporal phase or biomechanical phase; and scoring the tracking of the individual's eye or eyes by comparing the data to the visual cue.

Abstract: Methods and systems are disclosed for performing an assessment of vision-related health conditions for a user. A questionnaire regarding a user's identity and health history is displayed on a display mounted to a station. At least one interactive test image for assessing visual acuity is displayed on the display mounted to a station. An assessment is performed of vision-related health conditions for the user based on the user's response to the at least one interactive test image. At least one professional services and one marketing option is displayed. Instructions to the user for obtaining a copy of the assessment of vision-related health conditions for the user are displayed.

Abstract: The invention relates to a stereovision optometry apparatus comprising: a 3D display unit for displaying 3D image; a reference 2D display unit for displaying reference 2D image; an eyepiece in opposite side of the 2D display unit configured to view the images; a reflective mirror in opposite side of the 3D display unit configured to move toward and away from the 3D display unit; and a half mirror arranged between the 3D display and the reflective mirror and disposed at a point where propagation paths of the 2D image and the 3D image intersect; wherein the 2D image penetrates through the half mirror to reach the eyepiece; wherein the 3D image penetrates the half mirror to be reflected on the reflective mirror and then the reflected image is reflected on the half mirror to reach the eyepiece.

Abstract: Medical tests and examinations are performed with consumer computing devices. The medical tests and examinations are selected and customized in accordance with conditions present in the testing environment, as well as physical characteristics of a user taking the test. The tests can include visual acuity tests, colorblindness tests and other medical tests, such as hearing tests.

Abstract: Provided is a personal computer-based visual field self-testing system of increasing an opportunity of a glaucoma early diagnosis through a self-testing together with improvement of a size reduction, installation, and easiness in movement of a visual field testing system by using a personal computer. The personal computer-based visual field self-testing system includes a computer monitor presenting a visual field measurement region and a visual field measurement result, an attachable and detachable light blocking unit equipped on a front side of the computer monitor to provide a visual field testing environment, an eye selection unit equipped on a rear side of the attachable and detachable light blocking unit to block external light and select an examination eye, a face support unit including the eye selection unit and supporting a face of an examinee, and a visual stimulus confirmation unit operated by the examinee according to a visual stimulus of the visual field measurement region.

Abstract: Novel vision monitoring, screening, and testing tools and help-seeking enablers that may be used individually as or in combination with other vision monitoring and screening testing systems that improves patients' ability to recognize the onset and progression of visual changes over time. Patients' ability to identify acute or chronic visual conditions on their own may drive earlier help-seeking behavior by the patient, enable earlier clinical diagnosis by an eye care specialist, and therefore resulting in earlier treatment and reduced likelihood of severe vision loss.

Abstract: Systems and methods are disclosed for evaluating human eye tracking. One method includes receiving data representing the location of and/or information tracked by an individual's eye or eyes before, during, or after the individual performs a task; identifying a temporal phase or a biomechanical phase of the task performed by the individual; identifying a visual cue in the identified temporal phase or biomechanical phase; and scoring the tracking of the individual's eye or eyes by comparing the data to the visual cue.

Abstract: A visual function evaluation is performed using a sequence of interactions with a mobile device. A patient user may perform a variety of visual tests using the mobile device. The mobile device transmits the test results to a remote server implementing analysis of the visual function results using network service. The network service receives the test results, processes the results, and provides the processed results to a healthcare provider. The processed results may include trends of the user's visual function test performance. The healthcare provider, such as a physician, may optimize and administer treatment based on the data. Early detection of changes in visual function can enable the healthcare provider to individualize treatment, helping to prevent vision loss while minimizing visits to the office, discomfort, and expense.

Abstract: Graphical first individual interfaces, systems and methods of implementing an adaptable, interactive educational tool that provides cognitive and social benefits. An embodiment can be configured to provide a graphical first individual interface for presenting text and related content associated with a predetermined general subject matter. The specific text and related content presented to the first individual may be determined after baseline tests and related use are recorded to calculate the first individual's cognitive wellness. The present invention also provides social benefit by integrating a first individual's social network for uses in communication with the first individual's social network and in recalling the first individual's social network. The present invention further includes a unique algorithm for personalizing information and methodologies of implementing and displaying the educational tool to a first individual thereof.

Abstract: A method and a device for ascertaining and mapping data representing the optical imaging properties of an eye of a person, in which n different test images are displayed individually in succession on an electronically controllable monitor unit, are seen by the person from a settable viewing angle and at a settable distance, and are identified by means of an input comprising: a) ascertaining a characteristic viewing angle value at a given distance, at which a first probability for correct identification of the test images is achieved, b) ascertaining a characteristic distance value while maintaining the ascertained characteristic viewing angle value, at which a second probability for correct identification is achieved which is greater than the first probability, c) repeating steps a) and b).

Abstract: An inexpensive, easy-to-use self-refracting device which adjusts to continuously variable prescription corrections for a patient. In preferred embodiments specially designed gear arrangements, controlled by control knobs, moves one lens relative to the other or both lenses relative to each other in directions perpendicular to the viewing direction. The patient turns the device's knobs until vision is clearest. Once the patient adjusted the device for best vision, the patient's prescription can be read off various scales on the device. The diopter meter, therefore, can be used to easily and quickly screen for refractive error problems by allowing patients to self-adjust power and, if refractive error is present, see for themselves how much better they could see with corrective glasses.

Abstract: Medical tests and examinations are performed with consumer computing devices. The medical tests and examinations are selected and customized in accordance with conditions present in the testing environment, as well as physical characteristics of a user taking the test. The tests can include visual acuity tests, colorblindness tests and other medical tests, such as hearing tests.

Abstract: A method for screening vision using a kiosk comprising: requesting, using the kiosk, user information; performing objective visual acuity tests using the kiosk, wherein said visual acuity tests determine: sphere, cylinder, cylinder axis, or corneal curvature, or any combination thereof; and reporting visual acuity results, wherein said method does not require assistance from another person.

Abstract: Medical tests and examinations are performed with consumer computing devices. The medical tests and examinations are selected and customized in accordance with conditions present in the testing environment, as well as physical characteristics of a user taking the test. The tests can include visual acuity tests, colorblindness tests and other medical tests, such as hearing tests.