A glasses-type mobile terminal includes a display configured to display a virtual reality image and a controller configured to acquire reality information from a mobile terminal connected to the glasses-type mobile terminal and controlling the virtual reality image if a reality returning time indicating that viewing of the virtual reality image should be finished is reached based on the acquired reality information.

A smartphone stereoscope including a receptacle for holding a smartphone in a wide-image format position. The receptacle includes magnifying lenses and a partition running parallel to the long sides of the smartphone and aligned with a dividing line between two stereoscopic images arranged side-by-side on the smartphone screen. The partition swivels or pivots on a base between use and folded positions. A lens holder including lens holders for accommodating magnifying lenses is provided on the base along with a support bar. The bar contacts a longitudinal edge of the smartphone and is provided at an upper end of the partition and, in the use position runs transversely to the partition. A clamping means holds a smartphone when the longitudinal edge is put against the support bar. In the folded position the partition, base, support bar and lens holder lie parallel to each other in a plane, or in adjacent planes.

Stereoscopic display systems and methods for displaying surgical data and information in a surgical microscope are disclosed herein. According to an aspect, a system includes first and second eyepieces. The system includes a display having first and second display portions, configured to display first images in the first display portion, and configured to display second images in the second display portion. The first image and the second image are projected along a first pathway and a second pathway. The system includes a first optical element positioned to relay the first images into the first eyepiece. The system includes a second optical element positioned to relay the second images into the second eyepiece.

A head mounted display system with video-see-through (VST) is taught. The system and method process video images captured by at least two forward facing video cameras mounted to the headset to produce generated images whose viewpoints correspond to the viewpoint of the user if the user was not wearing the display system. By generating VST images which have viewpoints corresponding to the user's viewpoint, errors in sizing, distances and positions of objects in the VST images are prevented.

A head mounted display system with video-see-through (VST) is taught. The system and method process video images captured by at least two forward facing video cameras mounted to the headset to produce generated images whose viewpoints correspond to the viewpoint of the user if the user was not wearing the display system. By generating VST images which have viewpoints corresponding to the user's viewpoint, errors in sizing, distances and positions of objects in the VST images are prevented.

A virtual or augmented reality display system can include a first sensor to provide measurements of a user's head pose over time and a processor to estimate the user's head pose based on at least one head pose measurement and based on at least one calculated predicted head pose. The processor can combine the head pose measurement and the predicted head pose using one or more gain factors. The one or more gain factors may vary based upon the user's head pose position within a physiological range of movement.

A virtual or augmented reality display system can include a first sensor to provide measurements of a user's head pose over time and a processor to estimate the user's head pose based on at least one head pose measurement and based on at least one calculated predicted head pose. The processor can combine the head pose measurement and the predicted head pose using one or more gain factors. The one or more gain factors may vary based upon the user's head pose position within a physiological range of movement.

According to one embodiment, an eye movement detecting device comprises first, second, third, fourth and fifth electrodes. A line connecting the first and the third electrodes passes through the right eye and a line connecting the second and the fourth electrodes passes through the left eye on at least one of a front view, a plan view or a side view. A distance between the fifth and the first electrodes is equal to a distance between the fifth and the second electrodes. A distance between the fifth and the third electrodes is equal to a distance between the fifth and the fourth electrodes. The detector respectively detects a horizontal movement of the right eye and a horizontal movement of the left eye.

According to one embodiment, an eye movement detecting device comprises first, second, third, fourth and fifth electrodes. A line connecting the first and the third electrodes passes through the right eye and a line connecting the second and the fourth electrodes passes through the left eye on at least one of a front view, a plan view or a side view. A distance between the fifth and the first electrodes is equal to a distance between the fifth and the second electrodes. A distance between the fifth and the third electrodes is equal to a distance between the fifth and the fourth electrodes. The detector respectively detects a horizontal movement of the right eye and a horizontal movement of the left eye.

Systems and methods for determining disparity between two images are disclosed. Such systems and methods include obtaining a first pixel image of a scene from a first viewpoint, obtaining a second pixel image of the scene from a second viewpoint (e.g., separate from the first viewpoint in a camera baseline direction such as horizontal or vertical), modifying the first and second pixel images using component-separated correction to create respective first and second corrected pixel images maintaining pixel scene correspondence in the camera baseline direction from between the first and second pixel images to between the first and second corrected pixel images, determining pixel pairs from corresponding pixels between the first and second corrected pixel images in the camera baseline direction, and determining disparity correspondence for each of the determined pixel pairs from pixel locations in the first and second pixel images corresponding to respective pixel locations of the pixel pairs in the first and second corrected pixel images.