A device is provided. The device includes a reflective polarizer configured to selectively reflect or transmit a polarized light based on a polarization of the polarized light. The device also includes a display element disposed at a first side of the reflective polarizer, and configured to output a first image light representing a virtual image. The device also includes a polarization switch disposed between the display element and the reflective polarizer, and configured to switch or maintain a polarization of the first image light. The device further includes an active dimming device disposed at a second side of the reflective polarizer, and configured to provide an adjustable transmittance of an input light.

Aspects of the present disclosure relate to modular expansion systems for use in head-worn computing systems. In an head-worn computer, an electrical connector is adapted to electrically connect with a modular expansion module, wherein the modular expansion module adds a capability to the head-worn computer and is removeably mounted to the head-worn computer, and a mount is adapted to physically secure the modular expansion module to the head-worn computer

Aspects of the present disclosure relate to solid optical systems and methods for use in head-worn computing systems. An optical assembly may include multiple elements that are aligned relative to one another and then adhesively bonded together to preserve the alignment in an adhesively bonded optic, wherein the adhesively bonded optic includes at least one internal refractive surface and two or more internal reflective surfaces, and wherein the internal partially reflective surfaces comprise partially reflective surfaces that are protected by other elements in the adhesively bonded optic

A head-up display including a display screen including an array of display pixels arranged in rows and in columns, where the display screen is pivoted, around an axis perpendicular to the screen, by an inclination angle between 10 and 80 degrees, with respect to the position of the display screen for which a group of adjacent activated display pixels of a same row appears to an observer as being directed along the horizontal or vertical direction.

The present invention addresses the problem of providing a head-up display device with which the display quality of a display object can be improved. A mirror holder 30 supporting a concave mirror is equipped with a protruding piece that protrudes from the approximate center of the holder width, which is defined along a rotational axis, and this protruding piece is moved by a position adjustment means. Stress acting on the mirror holder from the protruding piece is uniform in the left and right directions from the center of the mirror holder. Consequently, twisting at the location of the mirror holder is significantly reduced, so the driver is able to view a display object for which distortion has been suppressed, and the display quality of the display object is improved.

Disclosed are an apparatus and method for reducing ghost image effects and rainbow effects in a near-eye display device. The near-eye display device includes an imager to generate an image based on light from a light source. The near-eye display device further includes at least one planar waveguide. The waveguide inputs light representing the image from the imager at an input surface and outputs the light representing the image toward an optical receptor of a user from an output surface. The waveguide is mounted in an opposite tilt angle. The tilt angle of the waveguide and grating periods of diffraction optical elements of the waveguide serve to reduce ghost image effects and rainbow effects.

An image display device includes a transparent plate which may be disposed in an inclined manner with respect to a display section of a portable terminal provided with the display section. A display displayed on the display section may be reflected on the transparent plate. A space behind the transparent plate may be viewed through the transparent plate and, at the same time, an image on the display section of the portable terminal may also be viewed while being reflected on the transparent plate.

Embodiments described herein may provide a configuration of input interfaces used to perform multi-touch operations. An example device may involve: (a) a housing arranged on a head-mountable device, (b) a first input interface arranged on either a superior or an inferior surface of the housing, (c) a second input interface arranged on a surface of the housing that is opposite to the first input interface, and (d) a control system configured to: (1) receive first input data from the first input interface, where the first input data corresponds to a first input action, and in response, cause a camera to perform a first operation in accordance with the first input action, and (2) receive second input data from the second input interface, where the second input data corresponds to a second input action(s) on the second input interface, and in response, cause the camera to perform a second operation.

A first light blocking portion and a second light blocking portion are formed in at least one of the side surfaces of a light guide prism. The first light blocking portion and the second light blocking portion are arranged so that a shaded area and an invisible area overlap each other at least partly and cover an inter-groove area between the first light blocking portion and the second light blocking portion, where the shaded area is an area shadowed from image light due to the first light blocking portion, and the invisible area is an area invisible during virtual image observation by the observer due to the second light blocking portion.

A tilt platform for use in an HMD comprises a monolithic spring structure including a first outer planar structure, a second outer planar structure, a middle planar structure disposed between the first and second outer planar structures, a first hinge structure coupling the first outer planar structure and the middle planar structure to each other, and a second hinge structure coupling the second outer planar structure and the middle planar structure to each other. The first and second hinge structures have respective first and second hinge axes that are orthogonal to each other. The tilt platform further comprises a first adjustment mechanism configured for tilting the first outer planar structure and the middle planar structure relative to each other about the first hinge axis, and a second adjustment mechanism configured for tilting the second outer planar structure and the middle planar structure relative to each other about the second hinge axis.