A optical system of a head mounted display (HMD) system that includes a lens assembly comprising a first lens element and a second lens element that are directly or indirectly coupled together, for example, via a suitable optically clear adhesive. The lens assembly may include a quarter-wave plate disposed between the first and second lens elements. The first lens element may include a surface with an anti-reflective coating thereon, and the second lens element may include a surface with a partially reflective coating thereon. The optical system may include a reflective polarizer that, together with the lens assembly, focuses light from a display system to an eye of a user of the head mounted display system.

A optical system of a head mounted display (HMD) system that includes a lens assembly comprising a first lens element and a second lens element that are directly or indirectly coupled together, for example, via a suitable optically clear adhesive. The lens assembly may include a quarter-wave plate disposed between the first and second lens elements. The first lens element may include a surface with an anti-reflective coating thereon, and the second lens element may include a surface with a partially reflective coating thereon. The optical system may include a reflective polarizer that, together with the lens assembly, focuses light from a display system to an eye of a user of the head mounted display system.

An apparatus that supplies multi-plane images for viewing by a user includes an image generator, an image director, and a first output port. The image generator generates a first image to be seen by the user as being a first distance from a user point of view, and a second image to be seen by the user as being a second distance from the user point of view The first image is comprised of a number of optical wavelength components, and the second image is comprised of the number of optical wavelength components. The image director is configured to direct the first image to traverse a first optical path to the first output port of the apparatus, and to direct the second image to traverse a second optical path to the first output port of the apparatus. The first optical path corresponds to the first distance and the second optical path corresponds to the second distance. The first optical path and the second optical path have different lengths. The first output port is configured to connect to a first optical waveguide that is configured to guide the number of optical wavelength components to a user display device.

Provided is an information processing apparatus that includes a line-of-sight information acquisition unit which acquires line-of-sight information related to a line-of-sight direction of a user, a movement information acquisition unit which acquires a center-of-gravity movement information related to a center-of-gravity movement direction of a body of the user, and a display control unit which performs a first display control for controlling a display device by moving a viewpoint of the imaging unit in the center-of-gravity movement direction while substantially maintaining the imaging posture of the imaging unit when the line-of-sight direction and the center-of-gravity movement direction are substantially parallel and performs a second display control for controlling the display device by rotating the imaging posture of the imaging unit and moving the viewpoint of the imaging unit in the center-of-gravity movement direction when the line-of-sight direction and the center-of-gravity movement direction are not substantially parallel.

A stereoscopic vision system uses at least two cameras having different parameters to image a scene and create stereoscopic views. The different parameters of the two cameras can be intrinsic or extrinsic, including, for example, the distortion profile of the lens in the cameras, the field of view of the lens, the orientation of the cameras, the positions of the cameras, the color spectrum of the cameras, the frame rate of the cameras, the exposure time of the cameras, the gain of the cameras, the aperture size of the lenses, or the like. An image processing apparatus is then used to process the images from the at least two different cameras to provide optimal stereoscopic vision to a display.

A stereoscopic vision system uses at least two cameras having different parameters to image a scene and create stereoscopic views. The different parameters of the two cameras can be intrinsic or extrinsic, including, for example, the distortion profile of the lens in the cameras, the field of view of the lens, the orientation of the cameras, the positions of the cameras, the color spectrum of the cameras, the frame rate of the cameras, the exposure time of the cameras, the gain of the cameras, the aperture size of the lenses, or the like. An image processing apparatus is then used to process the images from the at least two different cameras to provide optimal stereoscopic vision to a display.

A switchable optical assembly comprises a switchable waveplate configured to be electrically activated and deactivated to selectively alter the polarization state of light incident thereon. The switchable waveplate comprises first and second surfaces and a liquid crystal layer disposed between the first and second surfaces. The first liquid crystal layer comprises a plurality of liquid crystal molecules. Said first and second surfaces may be curved. Said plurality of liquid crystal molecules may vary in tilt with respect to said first and second surfaces with outward radial distance from an axis through said first and second surfaces and said liquid crystal layer in a plurality of radial directions. The switchable waveplate additionally comprises a first plurality of electrodes to apply an electrical signal across said first liquid crystal layer.

The present disclosure relates to a surgical navigation system for the alignment of a surgical instrument and methods for its use, wherein the surgical navigation system may comprise a head-mounted display comprising a lens. The surgical navigation system may further comprise tracking unit, herein the tracking unit may be configured to track a patient tracker and/or a surgical instrument. Patient data may be registered to the patient tracker. The surgical instrument may define an instrument axis. The surgical navigation system may be configured to plan one or more trajectories based on the patient data. The head-mounted display may be configured to display augmented reality visualization, including an augmented reality position alignment visualization and/or an augmented reality angular alignment visualization related to the surgical instrument on the lens of the head-mounted display.

Aspects of the present disclosure are directed to setting a display mode for a virtual object based on a display mode timer that is controlled by context factors. An artificial reality system can associate one or more virtual objects with a corresponding display mode timer. Various ranges on the display mode timer can be mapped to different display modes that the virtual object can assume. The display mode timer can be adjusted to add time based on a determination of a user focusing on the virtual object or other context factors. Display mode timers can also have rules for setting other display mode timer properties, such as how quickly the display mode timer runs down, that are evaluated based on context factors.

Aspects of the present disclosure are directed to setting a display mode for a virtual object based on a display mode timer that is controlled by context factors. An artificial reality system can associate one or more virtual objects with a corresponding display mode timer. Various ranges on the display mode timer can be mapped to different display modes that the virtual object can assume. The display mode timer can be adjusted to add time based on a determination of a user focusing on the virtual object or other context factors. Display mode timers can also have rules for setting other display mode timer properties, such as how quickly the display mode timer runs down, that are evaluated based on context factors.