An organic electronic material containing a charge transport compound having at least one of the structural regions represented by formulas (1), (2) and (3) shown below. In the formulas, Ar represents an arylene group or heteroarylene group of 2 to 30 carbon atoms, a represents an integer of 1 to 6, b represents an integer of 2 to 6, c represents an integer of 2 to 6, and X represents a substituted or unsubstituted polymerizable functional group.
—Ar—O—(CH.sub.2).sub.a—O—CH.sub.2—X  (1)
—Ar—(CH.sub.2).sub.b—O—CH.sub.2—X  (2)
—Ar—O—(CH.sub.2).sub.c—X  (3)

An information panel or display panel suitable for mounting onto the top of a vehicle is disclosed. Information such as advertisement can be change automatically. Change of advertisement content is responsive to the speed of the vehicle.

An information handling system display monitor transitions between flat and curved configurations by actuation of a shaped memory alloy wire within the display monitor housing. For example, a nickel titanium wire is heated by application of current across the wire to transition its crystalline form, thereby shortening the wire to adjust the configuration of a foldable display film, such as an OLED display film. Separate shaped memory alloy wires may be used to achieve foldable display film movement in each direction, or actuation of a shaped memory alloy wire in one direction may generate bias in a spring in the opposite direction that is released when a change in foldable display film configuration is desired.

A display module comprises light-emitting elements coupled to one or more mounting structures and grouped into a pixels in a pixel array on a display face to display textual, graphical, or video information, with each pixel comprising a grouping of one or more light-emitting elements. A face cover is mounted to the mounting structure and is positioned in front of at least a portion of the display face. The face cover comprises a plurality of moguls arranged in a mogul array with each mogul positioned in front of and proximate to a corresponding one of the pixels so that the mogul covers at least a portion of the corresponding pixel, and one or more light-emitting openings in each mogul, each positioned relative to one or more corresponding light-emitting element of the pixel to permit light emitted from the corresponding one or more light-emitting elements to pass through the mogul.

A method for producing a polarizing plate including a polarizer and a substrate film is provided. The method comprises: stretching a primary film to obtain a polarizer material film; providing an unstretched substrate film on the polarizer material film to obtain a layered body; and stretching the layered body to obtain the polarizing plate. The polarizer includes a dichroic material and has a thickness T of 20 μm or less. A phase difference Re in an in-plane direction of the substrate film in the polarizing plate is 20 nm or less.

A display assembly includes electronic displays secured to a structural framework at an elevated position, the structural framework including one or more members and configured for attachment to a surface. Solar panels are secured to the structure framework at a location above the electronic displays, and bulk energy storage devices are secured to the structure framework and electrically connected with the electronic displays and the solar panels.

A display assembly includes electronic displays secured to a structural framework at an elevated position, the structural framework including one or more members and configured for attachment to a surface. Solar panels are secured to the structure framework at a location above the electronic displays, and bulk energy storage devices are secured to the structure framework and electrically connected with the electronic displays and the solar panels.

A solar powered display assembly and systems and methods for the same are provided. An electronic display portion comprising an electronic display within a housing is secured to a structural framework at a position elevated above a ground surface. A solar energy harvesting device is connected to the structure framework at a position above, and spaced apart from, said electronic display portion, wherein said solar energy harvesting device is electrically connected to the electronic display portion. A bulk energy storage device is located below the electronic display portion. A footprint of the solar energy harvesting device is smaller than footprints for the electronic display portion and bulk energy storage device.

A solar powered display assembly and systems and methods for the same are provided. An electronic display portion comprising an electronic display within a housing is secured to a structural framework at a position elevated above a ground surface. A solar energy harvesting device is connected to the structure framework at a position above, and spaced apart from, said electronic display portion, wherein said solar energy harvesting device is electrically connected to the electronic display portion. A bulk energy storage device is located below the electronic display portion. A footprint of the solar energy harvesting device is smaller than footprints for the electronic display portion and bulk energy storage device.

According to one embodiment, a display device includes a first display panel including a first and second transparent substrate, a first liquid crystal layer, and a first light-emitting element, a second display panel including a third and fourth transparent substrate, a second liquid crystal layer and a second light emitting element, a filling member provided between the first and second display panel and having a refractive index equal to that of the first to fourth transparent substrates, a first light guide bonded to the first and second display panel, and a first adhesive member provided between the first display panel and the first light guide and between the second display panel and the first light guide.