Embodiments related to emissive devices for displays are discussed. Some embodiments include light emitting diodes including an electron transport layer core having a tube shape with an inner and an outer sidewall, an emission layer on the inner and outer sidewalls, and a hole transport layer on the emission layer, displays and systems including such light emitting diodes, and methods for fabricating them. Other embodiments include emissive laser devices having an emission layer between a hole transport layer and an electron transport layer and first and second metasurface mirrors adjacent to the hole transport layer and the electron transport layer, respectively, displays and systems including such emissive laser devices, and methods for fabricating them.

Embodiments related to emissive devices for displays are discussed. Some embodiments include light emitting diodes including an electron transport layer core having a tube shape with an inner and an outer sidewall, an emission layer on the inner and outer sidewalls, and a hole transport layer on the emission layer, displays and systems including such light emitting diodes, and methods for fabricating them. Other embodiments include emissive laser devices having an emission layer between a hole transport layer and an electron transport layer and first and second metasurface mirrors adjacent to the hole transport layer and the electron transport layer, respectively, displays and systems including such emissive laser devices, and methods for fabricating them.

An ultra-compact optical receiver supporting the laser scanning of objects in three-dimensions is disclosed. The receiver's narrow field-of-view may track the movement of a transmit beam, allowing isolation of a reflected receive signal from sensitivity reducing solar background and interfering signals. Small portions of a full receive field may be selected using a Digital Light Projector (DLP) micromirror array by placing a small portion of the mirror array elements into a pass-state allowing light to be directed towards the optical detector. The remaining mirror elements can be placed into a dump state where light is directed away from the detector. Furthermore, a unique total internal reflection (TIR) prism configuration may be used to allow the incoming receive signal to pass directly to the DLP mirror array while directing the light from pass and dump state DLP mirror orientations to the detector or optical absorbing regions of the receiver respectively.

An optical switch for optical fiber large-capacity stored program control exchanges. Optical transmission among optical fibers is performed through the reflection of lasers by a lens part of DMD chips. The lens part of the DMD chips consists of at least two single lenses (1) or at least two lens basic units (2) arranged in an one-dimensional array. The lens basic units (2) are formed by arranging a number of single lenses (1) in an nn matrix, wherein 2n10. The one-dimensional array is arranged in such a direction that lasers do not interfere with each other after reflection. The area of the single lenses (1) or that of the lens basic units (2) is no less than the cross-sectional area of a single optical fiber. In the optical switch, the DMD imaging technology in the non-communication field is applied to the communication field. The one-dimensional array technology is applied to butt-join the DMD and optical fibers and realize a large-capacity optical switch with the optical fiber switching >5.

A head-up display device includes a display element, a beam splitter, a movable mirror, first and second mirrors, and a movable unit. The display element emits light to form a display image. The beam splitter being an optical member that reflects light or through which light is transmitted, reflects light emitted from the display element. The movable mirror reflects light reflected off the beam splitter. The first and second mirrors that reflect light movable mirror, or through which the light transmitted through the beam splitter is transmitted, project a virtual image. The movable unit adjusts a distance between the movable mirror and the beam splitter to adjust a projection distance of the virtual image.

One example includes an optical port-shuffling module. The module includes a plurality of inputs to receive a respective plurality of optical signals. The module also includes a plurality of outputs to provide the respective plurality of optical signals from the optical port-shuffling module. The module further includes a plurality of total-internal-reflection (TIR) mirrors arranged in optical paths of at least a portion of the plurality of optical signals to reflect the at least a portion of the plurality of optical signals to at least a portion of the plurality of outputs to shuffle the plurality of optical signals between the plurality of inputs and the plurality of outputs.

Embodiments related to emissive devices for displays are discussed. Some embodiments include light emitting diodes including an electron transport layer core having a tube shape with an inner and an outer sidewall, an emission layer on the inner and outer sidewalls, and a hole transport layer on the emission layer, displays and systems including such light emitting diodes, and methods for fabricating them. Other embodiments include emissive laser devices having an emission layer between a hole transport layer and an electron transport layer and first and second metasurface mirrors adjacent to the hole transport layer and the electron transport layer, respectively, displays and systems including such emissive laser devices, and methods for fabricating them.

A beam distributor includes a beam entrance and multiple beam exits. The beam distributor includes: a rotatable cylindrical member; at least two multiple reflectors shifted from each other; a rotation mechanism that rotates the multiple reflectors; a fixing mechanism that fixes the reflectors; a reflector position sensing mechanism; a light absorber; and a control unit. The control unit controls the rotation mechanism to rotationally move a rotational position about the cylindrical member to a position where a laser beam is to be reflected on the reflector toward a selected beam exits, a position where the laser beam is to pass through between adjacent reflectors to be absorbed by the light absorber, or a position where the laser beam is to be reflected on the reflector and absorbed by the light absorber. The control unit controls the fixing mechanism so as to fix rotational movements of the reflectors.

A beam distributor includes a beam entrance and multiple beam exits. The beam distributor includes: a rotatable cylindrical member; at least two multiple reflectors shifted from each other; a rotation mechanism that rotates the multiple reflectors; a fixing mechanism that fixes the reflectors; a reflector position sensing mechanism; a light absorber; and a control unit. The control unit controls the rotation mechanism to rotationally move a rotational position about the cylindrical member to a position where a laser beam is to be reflected on the reflector toward a selected beam exits, a position where the laser beam is to pass through between adjacent reflectors to be absorbed by the light absorber, or a position where the laser beam is to be reflected on the reflector and absorbed by the light absorber. The control unit controls the fixing mechanism so as to fix rotational movements of the reflectors.