Disclosed herein are display devices having a left projector and a right projector. According to certain embodiments, a display device includes a first display package having a first LED die, a second LED die, a third LED die, and a first backplane die that is electrically connected to the first LED die, the second LED die, and the third LED die. Each of the first LED die, the second LED die, and the third LED die is symmetric about a first plane that is parallel to an emission direction of the first LED die and perpendicular to a longitudinal direction of the first LED die. The first backplane die is symmetric about a second plane that is parallel to the emission direction of the first LED die and parallel to the longitudinal direction of the first LED die.

A light projection system, including a light source to provide an output beam of light, an angular light modulator (ALM) comprising a plurality of pixels, each pixel having an ON state and an OFF state, the ALM positioned to receive output beam on the plurality of pixels, and a processor coupled to the ALM. The processor is programmed to control a first set of the pixels to transition between the OFF state and the ON state while the beam is incident on the pixels. An amount of light is selectively directed in a direction by the first set. The processor is also programmed to control a second set of the plurality of pixels to remain in the OFF state while the beam is incident on the plurality of pixels. As a result, the ALM operates as a spatial light modulator and an angular light modulator of the beam of light.

Disclosed herein are display systems with multiple display packages. In some examples, a first display package includes a first LED die and a first backplane die. The first LED die includes a wire interface that is symmetric about a first plane. The first backplane die includes input/output (I/O) pads that are electrically connected to the wire interface and symmetric about a second plane, perpendicular to the first plane. A similarly configured second display package includes a second LED die with a wire interface identical in layout to that of the first LED die, and a second backplane die with I/O pads identical in layout to that of the first backplane die. The second LED die can be positioned with respect to the second backplane die as a mirror reflection across the second plane of the position of the first LED die with respect to the first backplane die.

A projection device according to the present disclosure includes a light emission display panel in which a plurality of pixels including a light emission element are arranged in a matrix shape, a scanning mirror configured to reflect, toward a scanned surface, imaging light emitted from the light emission display panel and performs two-dimensional scanning of the reflected imaging light on the scanned surface, and a projection optical system configured to guide the imaging light from the light emission display panel to the scanning mirror.

The present invention provides a display device having a display panel. The display panel has a display surface and a plurality of pixels. At least some of the pixels include: an illumination unit and a display unit. The illumination unit has at least one illumination sub-pixel and at least one light orientation element respectively and correspondingly disposed on the at least one illumination sub-pixel, and illumination light from the illumination sub-pixel is directly or indirectly emitted from the display surface through the light orientation element. The display unit has at least one display sub-pixel, and display light from the display sub-pixel is directly or indirectly emitted from the display surface.

A projector assembly includes a light emitting diode (LED) array, wherein the LED array has an array axis, wherein the LED array includes a plurality of LEDs arranged along the array axis, and wherein the plurality of LEDs are individually addressable. The projector assembly includes a rotatable actuator supporting the LED array, wherein the rotatable actuator has a rotation axis, and wherein the rotation axis and the array axis are parallel. The projector assembly includes a collimator positioned in optical communication with the LED array for collimating light emitted from the plurality of LEDs and a set of imaging optics positioned in optical communication with the collimator for focusing collimated light and forming a first image of the LED array at a distance, wherein the first image includes a first axis corresponding to the array axis and a second axis orthogonal to the rotation axis.

A projector includes a first light source that emits a first light beam from a first light-emitting region including first light-emitting elements, and a second light source that emits a second light beam from a second light-emitting region including second light-emitting elements emitting light. Projector includes optical system that aligns traveling directions of first and second light beams, optical modulation device that adjusts first and second light beams based on image information, projection optical device, and control unit. The control unit changes a light-emitting position of the first light beam in the first light-emitting region to move an illumination region on an image forming region of the optical modulation device, and changes a light-emitting position of the second light beam in the second light-emitting region to move a second illumination region on the image forming region of the optical modulation device in the same direction as the first illumination region.

A method for processing video data by a system, including a recording device configured to generate video data; a projection screen having a front side facing the recording device and a rear side facing away from the recording device, and a plurality of light sources is provided. The method includes: providing background data which indicate a video background with a first resolution, and determining image signals from the background data in such a way that the image signals indicate the video background with a second resolution that is lower than the first resolution; transmitting the image signals to the light sources and irradiating the rear side by the light sources; and recording first video data by the recording device, wherein the first video data indicate a video of the front side and of a foreground object arranged between the projection screen and the recording device. A system is also provided.

The disclosure relates to a retinal display apparatus for generating an image on the retina of an eye of a user, wherein the retinal display apparatus is configured to generate multiple light beams, each light beam conveying an instance of the image, wherein the multiple light beams correspond one-to-one to multiple potential orientations of the eye of the user. Moreover, the disclosure relates to a corresponding method.

A three-dimensional display device includes a display panel, a controller, and a communication unit. The display panel is configured to display an image. An optical element is configured to define a propagation direction of image light emitted from the display panel. The communication unit is configured to receive a captured image of first eye and second eye different from the first eye, of a user. The controller causes the display panel to display a calibration image. The controller is configured so that, based on cornea images of different parts of the calibration image in the captured image that are viewed with the first eye and the second eye of the user, respectively, a parallax image is displayed on the display panel.