A flexible display device and an electronic device are provided. The flexible display device includes: a flexible display panel; a plurality of functional members on a side of the flexible display panel, including a first functional member, a second functional member, and a third functional member; a back film on the other side of the flexible display panel; a supporting member on a side of the back film away from the flexible display panel; and a plurality of adhesive layers, including a first adhesive layer, a second adhesive layer, a third adhesive layer, a fourth adhesive, and a fifth adhesive layer. The third functional member includes a touch module including a touch substrate, a sensor layer, and an adhesive material layer between the sensor layer and the touch substrate, the modulus of the adhesive material layer is not less than the modulus of each of five adhesive layers.

According to an embodiment of the disclosure, an electronic device may include: a housing, a sliding plate configured to slide-out from the housing, a flexible display including a first section coupled to overlap the sliding plate, and a bendable section extending from the first section and configured to be pulled out from an inner space of the housing during the slide-out, a support sheet disposed on a rear surface of the flexible display, a first curved portion located inside the housing to correspond to the bendable section, a belt connecting the support sheet and the sliding plate to each other, and a second curved portion located inside the housing to correspond to the belt and spaced apart from the first curved portion in a slide-out direction.

A printer deposits material onto a substrate as part of a manufacturing process for an electronic product; at least one transported component experiences error, which affects the deposition. This error is mitigated using transducers that equalize position of the component, e.g., to provide an ideal conveyance path, thereby permitting precise droplet placement notwithstanding the error. In one embodiment, an optical guide (e.g., using a laser) is used to define a desired path; sensors mounted to the component dynamically detect deviation from this path, with this deviation then being used to drive the transducers to immediately counteract the deviation. This error correction scheme can be applied to correct for more than type of transport error, for example, to correct for error in a substrate transport path, a printhead transport path and/or split-axis transport non-orthogonality.

A cushion sheet including: a cushion film, the cushion film defining a first surface of the cushion sheet; and an adhesive layer deposited on at least one surface of the cushion film, the adhesive layer defining a second surface of the cushion sheet, wherein the cushion film and the adhesive layer include a plurality of bubble discharge members inclined with respect to the first and second surfaces, the plurality of bubble discharge members including openings extending through the cushion film and the adhesive layer for removing air bubbles generated at adhesion, the openings having a first end in the adhesive layer and a second end in the cushion film; and each of the plurality of bubble discharge members are inclined at a penetrating angle within the cushion sheet, the penetrating angle being an angle formed between a respective one of the bubble discharge members and a line perpendicular to a plane of the cushion sheet, the line extending from the first end of the respective bubble discharge member to the first surface of the cushion sheet.

Embodiments of the present invention disclose an array substrate comprising a base substrate and a plurality of pixel units disposed on the base substrate, the pixel unit comprising a transflective layer formed on the base substrate; a thin film transistor structure formed over the transflective layer; an organic light-emitting diode disposed in a pixel region of the pixel unit and driven by the thin film transistor structure, and in a direction away from the base substrate, the organic light-emitting diode sequentially comprising a first electrode that is transparent, an organic light-emitting layer and a second electrode for reflecting light; and a color filter, disposed between the second electrode of the organic light-emitting diode and the transflective layer; wherein the second electrode of the organic light-emitting diode and the transflective layer constitute a microcavity structure. Embodiments of the present invention also disclose a method for manufacturing the array substrate and a display device including the above array substrate.

A rollable display device includes a rollable structure including a plurality of unit structures, the rollable structure being configured to be rolled and unrolled based on the unit structures, and a display panel structure attached to the rollable structure, wherein respective widths of the unit structures increase in a first direction from a first side of the rollable structure to an opposite second side of the rollable structure.

A printer deposits material onto a substrate as part of a manufacturing process for an electronic product. At least one mechanical component experiences mechanical error, which is mitigated using transducers that equalize position of a transported thing, e.g., to provide an ideal conveyance path; a substrate conveyance system and/or a printhead conveyance system can each use transducers in this manner to improve precise droplet placement. In one embodiment, errors are measured in advance, with corrections being played back during production runs to mitigate repeatable transport path error. In a still more detailed embodiment, the transducers can be predicated on voice coils, which cooperate with a floatation table and floating, mechanical pivot assembly to provide frictionless, but mechanically-supported error correction.

A display device is disclosed. In one aspect, the display device includes a substrate including a display area configured to display an image and a peripheral area surrounding the display area. The display device also includes a plurality of signal lines provided in the display area, an encapsulation layer provided over the signal lines and a pad portion provided in the peripheral area. The display device further includes a plurality of connection wires connecting the signal lines and the pad portion, wherein each of the connection wires includes a first portion provided in the peripheral area and a second portion provided in the display area. A portion of the encapsulation layer provided on the display area extends to the peripheral area and placed over the first portions of the connection wires.

Provided is a light extraction substrate capable of achieving both light extraction efficiency and preservability. Before forming a cap layer, a step of reducing in-membrane water content such that the in-membrane water content of a layer formed between a gas barrier layer and the cap layer is less than 1.0?10.sup.15/mg is performed. The in-membrane water content of less than 1.0?10.sup.15/mg is maintained until at least a step of forming the cap layer after the step of reducing the in-membrane water content, and the cap layer is then formed through a dry process.

A display device according to the present disclosure includes: a drive circuit array substrate including drive circuits arranged in an array pattern on a semiconductor substrate; and light emitting elements arranged in an array pattern over the drive circuits and driven by the drive circuits, in which in a drive circuit group including a plurality of the drive circuits that are adjacent to each other, a well tap is provided in a part of the drive circuits of the plurality of the drive circuits included in the drive circuit group.