A headset for use as part of an Augmented Reality apparatus comprises a headband arranged to secure the headset to a user's head; and a mount connected to the headband and arranged to detachably receive a display device in a position arranged to be in front of a user's eyes in use. The headset is arranged, insofar as possible, not to block a user's peripheral vision. The mount may comprise a pair of arms arranged to support the display device. The headset may comprise a pair of lenses connected to the headband and arranged to be located between the user's eyes and the display device, wherein the lenses are double convex lenses with a flat lower edge, the flat lower edge of each lens being arranged to fall on a plane extending between a user's expected pupil location and a lower edge of the mount. The mount may be transparent.

A head-up display for a vehicle having a window. The head-up display comprises a picture generating unit and a projection engine. The picture generating unit is arranged to output pictures. Each picture comprises a first picture component and a second picture component. The projection engine is arranged to receive the pictures output by the picture generating unit and project the pictures onto the window of the vehicle in order to form a first virtual image of the first picture component at a first virtual image distance and a second virtual image of the second picture component at a second virtual image distance. Light of the first picture component is polarised in a first polarisation direction and light of the second picture component is polarised in a second polarisation direction perpendicular to the first polarisation direction. The projection engine comprises an optical element having first optical power in the first polarisation direction and second optical power in the second polarisation direction such that the first virtual image distance is not equal to the second virtual image distance. The projection engine is further arranged such that the first virtual image and second virtual image at least partially overlap.

A head-up display system of a vehicle visually transmits information to eyes of an occupant. The head-up display system comprises an illumination device configured to emit a display light and a windshield spaced from the illumination device and extending transverse to the display light. The head-up display system comprises a holographic panel coupled to and extending with the windshield and arranged to diffract the display light toward the eyes of the occupant. The display light emits toward the holographic panel in an entrance direction at an entrance angle relative to an axis normal to the holographic panel and diffracts away from the holographic panel in an exit direction at an exit angle relative to the axis, which is different than the entrance angle.

The present disclosure provides a method comprising detecting an event in connection with an autonomous vehicle, wherein the detected event comprises at least one of a current state of the autonomous vehicle, an impending state of the autonomous vehicle, and an intent of the autonomous vehicle; generating an image in connection with the detected event, wherein the image comprises at least one of text information and graphics information; and displaying the generated image on at least one window of the autonomous vehicle for conveying information about the detected event to at least one user located outside the autonomous vehicle.

A near-eye display (NED), comprising a frame comprising an outer lens, a micro-display panel coupled to the frame and comprising a processor configured to process content for display to a user wearing the NED, an augmented reality (AR) lens comprising a main prism lens, wherein the outer lens comprises at least one of a display corrector lens or a see-through corrector lens.

A display device includes light sources that emit light, a display panel that displays an image, and a light guide panel that guides the light emitted from the light sources to the display panel. The light guide panel includes an incident surface facing the light sources, an emission surface facing the display panel, a first reflective surface facing the incident surface, and a second reflective surface facing the emission surface. The first reflective surface has a concave shape that reflects light so that the reflected light becomes closer to parallel light when viewed in a facing direction of the display panel and the light guide panel in the light guide panel, is tilted at an angle larger than 0 degrees with respect to the incident surface, and intersects the second reflective surface at an angle smaller than 90 degrees.

A head worn display (HWD) includes a head attachment region, an internal display and a controller. The internal display is viewable by a user and includes variable transparency areas. The internal display is arranged to display at least a portion of an external region external to the HWD. The controller is configured to control the variable transparency areas to block view of a region of the external region and to control the internal display to overlay information in a region of the internal display corresponding to the region of the external region which is blocked.

A multi-focal plane head-up display includes a main body, a projector, a first reflective element, a second reflective element, a polarizing element and a third reflective element. The polarization direction of a first image light in the first region of the projection image projected by the projector and the polarization direction of a second image light in the second region of the projection image are orthogonal to each other. The first image light passes through the first reflective element and the polarizing element to form a first virtual image. The second image light passes through the second reflective element, the polarizing element and the third reflective element to form a second virtual image. This can not only provide two virtual images with different focal planes, but also reduce the volume occupied by the head-up display and reduce manufacturing costs.

A virtual image is superimposed on a foreground scenery of an occupant. It is determined whether a road condition, for associating a display position of the virtual image with a position of an object in the foreground scenery with respect to a road on which the vehicle travels, is satisfied. The virtual image is generated as a superposing virtual image that presents information by associating the display position with the position of the object when the road condition is satisfied. At least a part of the virtual image is generated as a non-superimposing virtual image that presents the information without associating the display position with the position of the object when the road condition is not satisfied.

A wedge-shaped interlayer having reduced dynamic ghosting is provided, wherein the interlayer comprises at least one polymer layer comprising a poly(vinyl acetal) resin and at least one plasticizer, wherein said wedge-shaped interlayer defines a head-up display (HUD) region having a target vertical wedge angle, an actual vertical wedge angle and an absolute wedge angle rate of change, wherein the absolute wedge angle rate of change is less than 3.0 prad/mm throughout the entire HUD region.