An eyeglass frame 12 for a head mounted display 10 comprises a lens supporting member 28a, 28b that supports eyeglasses 26a, 26b and is mounted on a mount portion 16 of the head mounted display 10; and plurality of engaging portions 38a˜38d, 42a˜42d, 44a, 44b, 48a, 48b that are formed on positions corresponding to various shapes of the mount portion 16 on outer circumferential portion of the lens supporting member 28a, 28b and engage with an internal wall surface 36 of the mount portion 16, wherein the engaging portions 38a˜38d include elastic members slidable along the internal wall surface.

An AR optical system includes a depth-of-field separation structure corresponding to an image source, configured to convert light rays emitted from the image source into a plurality of light beams with different depths of field; a convergent lens located on an emergent light path of the depth-of-field separation structure, and configured to receive and shape the plurality of light beams with different depths of field; a first semi-transmitting semi-reflecting mirror located on a side, away from the depth-of-field separation structure, of the convergent lens, and configured to reflect the plurality of shaped light beams with different depths of field towards a set direction; a concave mirror having a preset transmission-reflection ratio configured to reflect and converge the plurality of light beams with different depths of field and then make the light beam incident to a set observation position after passing through the first semi-transmitting semi-reflecting mirror.

A reprojection unit executes reprojection processing for converting an image including depth value information to align with a viewpoint position or a line of sight direction according to a plurality of different depth values, and generates a composite image by compositing a plurality of images subjected to the reprojection processing according to the plurality of different depth values. A distortion processing unit executes distortion processing for transforming the composite image in alignment with distortion arising in a display optical system.

Provided is an optical glass plate having a high refractive index and excellent visible light transmittance. An optical glass plate characterized by containing as a glass composition at least one selected from Nb.sub.2O.sub.5, La.sub.2O.sub.3, and Gd.sub.2O.sub.3, the optical glass plate having a refractive index (nd) of 1.90 to 2.30 and an internal transmittance τ.sub.450 of 75% or greater for a thickness of 10 mm at a wavelength of 450 nm.

Provided is an optical glass plate having a high refractive index and excellent visible light transmittance. An optical glass plate characterized by containing as a glass composition at least one selected from Nb.sub.2O.sub.5, La.sub.2O.sub.3, and Gd.sub.2O.sub.3, the optical glass plate having a refractive index (nd) of 1.90 to 2.30 and an internal transmittance τ.sub.450 of 75% or greater for a thickness of 10 mm at a wavelength of 450 nm.

A method for rendering data of a three-dimensional image adapted to an eye position and a display system are provided. The method is used to render the three-dimensional image to be displayed in a three-dimensional space. In the method, a three-dimensional image data used to describe the three-dimensional image is obtained. The eye position of a user is detected. The ray-tracing information between the eye position and each lens unit of a multi-optical element module forms a region of visibility (RoV) that may cover a portion of the three-dimensional image in the three-dimensional space. When coordinating the physical characteristics of a display panel and the multi-optical element module, a plurality of elemental images can be obtained. The elemental images form an integral image that records the three-dimensional image data adapted to the eye position, and the integral image is used to reconstruct the three-dimensional image.

An optical system for displaying a magnified virtual image of an image emitted by a display to a viewer. The optical system includes first and second lenses facing each other and spaced apart by an air gap to define an optical cavity therebetween. The optical cavity includes a reflective polarizer disposed on a major surface of the first lens, and an optical stack disposed on a major surface of the second lens. The optical stack includes an absorbing polarizer, a first retarder layer, a partial reflector, and a second retarder layer disposed between the absorbing polarizer and the partial reflector. The first and/or second lenses is/are birefringent lens provided outside the optical cavity to control polarization.

A head-mounted display achieves both miniaturization and high efficiency of an optical system and expansion of an eye box. In order to achieve the above-described object, a head-mounted display that displays an image within a visual field of a user is provided. The head-mounted display includes: an image display unit that generates an image to be displayed; a projection unit that projects image light from the image display unit; an image rotation and replication unit that expands an eye box of projection light from the projection unit; and a waveguide unit that transmits image light from the image rotation and replication unit to a pupil of the user. The image rotation and replication unit includes an incidence surface, an emission surface, and at least two reflection surfaces, and an angle formed by the incidence surface and the emission surface is greater than 90°.

An information processing apparatus according to the present technology includes: a control unit. The control unit causes a first display unit of a head-mounted display to display a virtual object in an augmented reality (AR) manner, detects a user interaction with regard to the virtual object, the interaction being performed with an interaction device, and causes a second display unit of the interaction device to display an image relating to the virtual object in accordance with the interaction.

If a distance from a current position to a guide point is less than a predetermined distance, a normal output process and a stop process of a guide image are repeatedly performed. If a priority display request for a guide image is performed, a priority output process of the guide image is performed prior to the stop process. If an interval between the priority output process and the normal output process performed after the priority output process is short, the priority output process continues until the normal output process starts.