A display device includes: a first closed-bottom lens tube including a first display part on the closed bottom for displaying a first image; a second closed-bottom lens tube including a second display part on the closed bottom for displaying a second image; an adjustment mechanism including a first rod that extends from the first lens tube and a second rod that extends from the second lens tube and is rotatably connected to the first rod; and an image outputter that outputs the first and second images to the first and second display parts, respectively. The image outputter, in accordance with the angle of rotation of the first and second rods of the adjustment mechanism, controls and outputs the first and second images to bring the horizontal directions thereof closer to the arrangement direction of the first and second lens tubes.

The disclosed head-mounted display assemblies may include a first eyecup and a second eyecup that are configured for positioning in front of intended locations of a user's eyes. The first eyecup and the second eyecup may be movable relative to each other to adjust for an interpupillary distance of the user's eyes. The head-mounted display assemblies may also include a single near-eye display screen configured for displaying an image to the user through the first eyecup and the second eyecup. A flexible shroud may be positioned to provide a seal between a first interior volume of the first eyecup, a second interior volume of the second eyecup, and the single near-eye display screen. Various other methods, devices, systems, and assemblies are also disclosed.

A wearable image display device includes: a wearing member worn on a head of a user; a supporting member configured to support a display device that displays video; a coupling member that is coupled to the wearing member and the supporting member and that is configured to move the display device and the like from a first position enabling the user to visually recognize the video to a second position; and a control device configured to control an output of sound output from a speaker disposed at the supporting member. The control device makes the sound output from the speaker when the display device and the like are located in the second position louder than the sound output from the speaker when the display device and the like are located in the first position.

Head-mounted virtual and augmented reality display systems include a light projector with one or more emissive micro-displays having a first resolution and a pixel pitch. The projector outputs light forming frames of virtual content having at least a portion associated with a second resolution greater than the first resolution. The projector outputs light forming a first subframe of the rendered frame at the first resolution, and parts of the projector are shifted using actuators, such that physical positions of light output for individual pixels occupy gaps between the old locations of light output for individual pixels. The projector then outputs light forming a second subframe of the rendered frame. The first and second subframes are outputted within the flicker fusion threshold. Advantageously, an emissive micro-display (e.g., micro-LED display) having a low resolution can form a frame having a higher resolution by using the same light emitters to function as multiple pixels of that frame.

A near eye display system including a display screen, a graphic processing unit, a lens group, a focal length adjustment device, an interpupillary distance adjustment device, a detection unit, and a control unit is provided. Positions of a left-eye image and a right-eye image to be displayed on the display screen may be adjusted based on lateral displacement amounts of a left-eye lens and a right-eye lens, such that centers of the left-eye image and the right-eye image are respectively aligned with centers of the left-eye lens and the right-eye lens. Sizes (magnification) of the left-eye image and the right-eye image to be displayed on the display screen may be adjusted based on longitudinal displacement amounts of the left-eye lens and the right-eye lens, such that sizes of a visual left-eye image and a visual right-eye image seen by a user are identical. Operation methods thereof are also provided.

A head up display mirror mounting arrangement for a motor vehicle includes a mirror positioned to reflect an image such that the image is again reflected by a windshield of the vehicle. A mirror holder includes two opposite ends each having a respective pivot. The pivots define an axis of rotation of the mirror. The mirror holder holds the mirror. A housing includes two opposite ends each having a respective bearing support. Two rotation mechanisms each pivotably couple a respective pivot to a respective bearing support.

Described are headrests with integrated entertainment systems. The headrest includes a shell that is coupled to a seat through a headrest mount that has at least one degree of freedom of movement. The headrest shell also supports a visor with at least one side arm and a display span that may rotate between stowed and deployed positions. A neutral position mechanism supports the headrest in a neutral position and provides resistance to movement between the headrest and the passenger seat. The attachment of the visor to the headrest shell may also include an adjustment slot to allow fore and aft translation of the visor with respect to the headrest shell. The fore and aft translation of the visor allows for positioning the visor at different focal lengths, and provides extra clearance for the visor as it moves between stowed and deployed positions.

Techniques and mechanisms for fabricating an eyepiece from a lens blank including blank bodies that are bonded to each other. In an embodiment, the blank bodies are formed by injection molding and adhered to one another. Fabrication of the eyepiece includes variously machining the blank bodies to shape respective lens bodies of the eyepiece. One or more blocking structures are coupled to reinforce the lens blank during at least part of such machining. In another embodiment, any blocking structures that are to resist forces of a particular machining process are coupled only indirectly to one of the blank bodies.

A virtual-reality (VR) system includes a head-mounted display (HMD) to receive video input from a stationary computer in a first mode of operation and from a mobile computer in a second mode of operation, and to display images corresponding to the video input. The VR system also includes a headband to secure the HMD on a user's head and a holder mounted on the headband to detachably support the mobile computer.

An optical see-through glass type display device comprises: an image projector projecting a virtual image; a first optical element configured to guide light of the virtual image; and a second optical element having a first reflection surface for reflecting back light coming through the front surface of the second optical element and a second reflection surface for retro-reflecting light coming through the rear surface of the second optical element. The second optical element is switchable between a first state in which the reflection on the first and second reflection surfaces is enabled and a second state in which the reflection on the first and second reflection surfaces is disabled.