Abstract: A substrate structure is provided, in which an insulating protection layer is formed on a substrate body having a plurality of electrical contact pads, and the insulating protection layer has a plurality of openings corresponding to the plurality of exposed electrical contact pads, and the insulating protection layer is formed with a hollow portion surrounding a partial edge of at least one of the electrical contact pads at at least one of the openings, so as to reduce the barrier of the insulating protection layer.

Abstract: An expansion card frame assembly is configured to support a riser card and an expansion card. The expansion card frame assembly includes a frame, a pivotable component and a stopper. The frame is configured to support the riser card, and the expansion card is configured to be inserted into the riser card. The pivotable component is pivotably disposed on the frame and configured to be located aside the expansion card. The stopper is movably disposed on the pivotable component and configured to be located at one side of the expansion card which is located farther away from the riser card.

Abstract: Systems and methods of automatically extracting summaries of video content are described herein. A data processing system can access, from a video database, a first video content element including a first plurality of frame. The data processing system can select an intervallic subset of the first plurality of frames of the first video content element. The data processing system can calculate, for each of a plurality of further subsets comprising a predetermined number of frames from the intervallic subset, a score for the further subset. The data processing system can identify, from the plurality of further subsets, a further subset having a highest score. The data processing system can select a portion of the first video content element comprising the frames of the further subset having the highest score. The data processing system can generate a second video content element comprising the selected portion of the first video content element.

Abstract: An engineered DNA polymerase, with increased property for single molecule sequencing compared to a wild-type DNA polymerase, comprising a combination of mutation sites and functional domains, wherein the combination of mutation sites and functional domains includes thermostable mutation sites, low Kd mutation sites, exonuclease-deficient sites and DNA binding domains.

Abstract: In an embodiment, a method includes forming a first semiconductor fin and a second semiconductor fin over a front-side of a substrate; etching a first recess in the first semiconductor fin and a second recess in the second semiconductor fin; forming a first epitaxial region in the first recess and first epitaxial nodules along sidewalls of the first recess; forming a second epitaxial region in the second recess and second epitaxial nodules along sidewalls of the second recess; flowing first precursors to remove the first epitaxial nodules; depositing an interlayer dielectric over the first epitaxial region and the second epitaxial region; etching a first opening in the interlayer dielectric to expose the first epitaxial region; forming a first epitaxial cap on the first epitaxial region and third epitaxial nodules over the interlayer dielectric; and flowing second precursors to remove the third epitaxial nodules.

Abstract: A transparent display includes a transparent substrate, a wiring layer, a plurality of light-emitting package units, and a plurality of connecting elements. The wiring layer is disposed on a surface of the transparent substrate. Each of the light-emitting package units includes a micro-substrate, frontward light-emitting elements, backward light-emitting elements, and a sealant. The micro-substrate has a first surface facing away from the transparent substrate and a second surface facing the transparent substrate. The frontward light-emitting elements are disposed on the first surface of the micro-substrate, in which the micro-substrate is configured to block the light from the frontward light-emitting elements toward the transparent substrate. The backward light-emitting elements are disposed on the second surface of the micro-substrate. The sealant covers the micro-substrate, the frontward light-emitting elements, and the backward light-emitting elements.

Abstract: A conductive laminated structure includes a conductive layer and a thickening layer. The conductive layer extends in a first direction. The thickening layer is disposed over or under the conductive layer. The conductive laminated structure can withstand more than 40,000 folding times without breakage when a radius of curvature R is equal to 3 mm, a folding direction is perpendicular or parallel to the first direction, and a folding angle is 180°. A foldable electronic device is also provided herein.

Abstract: A millimeter wave radar apparatus determining a vital sign includes a microprocessor, a millimeter wave radar and an electrocardiogram machine. The millimeter wave radar is configured to detect a human body to obtain a plurality of wireless vital-sign signals. The microprocessor is configured to receive the wireless vital-sign signals. The electrocardiogram machine is configured to detect the human body to obtain a plurality of wired vital-sign signals. The microprocessor is configured to receive the wired vital-sign signals. After the microprocessor receives the wireless vital-sign signals and the wired vital-sign signals, the microprocessor is configured to output the wireless vital-sign signals and the wired vital-sign signals.

Abstract: An operation method of a remote laser projection device includes emitting multiple first lights to an optical transmission module through multiple light source modules, the optical transmission module includes multiple optical fibers, and each of the light source modules includes to a plurality of optical fibers; and transmitting the first lights to the projection head through the optical fiber of the corresponding optical transmission module.

Abstract: A method for preparing stacking structure includes providing a substrate; disposing a metallic layer and a silver nanowire layer on the substrate; applying flexographic printing technology to print an anti-etching layer on a surface of the metallic layer or the silver nanowire layer so that the anti-etching layer partially covers the metallic layer or the silver nanowire layer; applying an etching technology to remove a part of the metallic layer or the silver nanowire layer that is not covered by the anti-etching layer and the metallic layer or the silver nanowire layer disposed therebelow with an etching liquid so that the metallic layer comprises: metallic wires; a metallic grid; and a metallic plate; and removing the anti-etching layer. A stacking structure comprises: the substrate; the metallic layer; and the silver nanowire layer. The method for preparing stacking structure and the stacking structure can be applied to a touch sensor.

Abstract: An operation method of a remote laser projection device includes emitting a first light to an optical transmission module through at least one light source module; transmitting the first light to at least one projection head through the optical transmission module, wherein total light energy of the first light is allocated to the projection head through the optical transmission module, such that energy of a light transmitted to the projection device is E/N, and wherein E is total light energy of the at least one light module, and N is a number of the at least one projection device.

Abstract: A method of producing a stacking structure includes providing a substrate; printing, by flexography, a catalyst layer onto the substrate, wherein the catalyst layer includes a grid pattern and a conducting wire pattern connected to the grid pattern; plating, by chemical plating, a metal layer onto the catalyst layer, wherein the metal layer includes a metal grid corresponding in position to the grid pattern of the catalyst layer and a metal conducting wire corresponding in position to the conducting wire pattern of the catalyst layer; and printing, by flexography, a silver nanowire layer onto the metal layer, wherein the silver nanowire layer at least partially overlaps the metal grid. A stacking structure includes a substrate; a catalyst layer; a metal layer; and a silver nanowire layer. The method of producing a stacking structure and the stacking structure are applicable to a touch sensor.

Abstract: A projecting method includes: outputting, by a projection display apparatus, a projected image to a projection screen through a shifting device, wherein the projected image includes multiple frames; outputting, by a processing circuit, a control signal to drive the shifting device to rotate multiple first angles along a first axis or to rotate multiple second angles along a second axis, wherein combination of the first and the second angles corresponds to multiple projected positions; and when the projection display apparatus outputs multiple frames sequentially, rotating the shifting device sequentially according to the control signal to make multiple frames projected to the corresponding one of projected positions, wherein a number of the first angles or the second angles is at least four.

Abstract: A stacking structure preparation method includes the steps of providing a substrate; printing a silver nanowire layer on the substrate using a flexographic printing process; and printing a meal layer on the substrate and the silver nanowire layer also using the flexographic printing process. The metal layer includes a metal mesh that covers at least a part of the substrate and the silver nanowire layer, and a plurality of metal traces that is connected to the metal mesh. A stacking structure formed through the above preparation method is also disclosed. The stacking structure includes, from bottom to top, a substrate, a flexo printed silver nanowire layer, and a flexo printed metal layer partially covering the substrate and the silver nanowire layer. The above preparation method and stacking structure can be applied to the manufacturing of a touch sensor.

Abstract: A method for preparing stacking structure includes providing a substrate; disposing a metallic layer and a silver nanowire layer on the substrate; applying flexographic printing technology to print an anti-etching layer on a surface of the metallic layer or the silver nanowire layer so that the anti-etching layer partially covers the metallic layer or the silver nanowire layer; applying an etching technology to remove a part of the metallic layer or the silver nanowire layer that is not covered by the anti-etching layer and the metallic layer or the silver nanowire layer disposed therebelow with an etching liquid so that the metallic layer comprises: metallic wires; a metallic grid; and a metallic plate; and removing the anti-etching layer. A stacking structure comprises: the substrate; the metallic layer; and the silver nanowire layer. The method for preparing stacking structure and the stacking structure can be applied to a touch sensor.

Abstract: A method of producing a stacking structure includes providing a substrate; printing, by flexography, a catalyst layer onto the substrate, wherein the catalyst layer includes a grid pattern and a conducting wire pattern connected to the grid pattern; plating, by chemical plating, a metal layer onto the catalyst layer, wherein the metal layer includes a metal grid corresponding in position to the grid pattern of the catalyst layer and a metal conducting wire corresponding in position to the conducting wire pattern of the catalyst layer; and printing, by flexography, a silver nanowire layer onto the metal layer, wherein the silver nanowire layer at least partially overlaps the metal grid. A stacking structure includes a substrate; a catalyst layer; a metal layer; and a silver nanowire layer. The method of producing a stacking structure and the stacking structure are applicable to a touch sensor.

Abstract: A conductive laminated structure includes a conductive layer and a thickening layer. The conductive layer extends in a first direction. The thickening layer is disposed over or under the conductive layer. The conductive laminated structure can withstand more than 40,000 folding times without breakage when a radius of curvature R is equal to 3 mm, a folding direction is perpendicular or parallel to the first direction, and a folding angle is 180°. A foldable electronic device is also provided herein.

Abstract: A touch panel and a manufacturing method thereof are provided. The touch panel includes a substrate, peripheral leads, a touch sensing electrode, and first intermediate layers. The peripheral leads are disposed in a peripheral area of the substrate. The first intermediate layers are disposed between the peripheral leads and the substrate. The touch sensing electrode includes a plurality of modified metal nanowires. The modified metal nanowires have first surfaces in direct contact with each other at an intersection. The modified metal nanowires have second surfaces with covering structures, and the second surfaces are at a non-intersection.

Abstract: An operation method of a remote laser projection device includes emitting a first light to an optical transmission module through at least one light source module; transmitting the first light to at least one projection head through the optical transmission module, wherein total light energy of the first light is allocated to the projection head through the optical transmission module, such that energy of a light transmitted to the projection device is E/N, and wherein E is total light energy of the at least one light module, and N is a number of the at least one projection device.

Abstract: A method of manufacturing a touch panel including providing a substrate having a display area and a peripheral area is provided. A metal layer and a metal nanowire layer are disposed, wherein a first portion of the metal nanowire layer is disposed in the display area, and a second portion of the metal nanowire layer and the metal layer are disposed in the peripheral area. A patterned layer with a pattern is disposed. A patterning step is performed according to the patterned layer, wherein the patterning step includes forming the metal layer into multiple peripheral wires and simultaneously forming the second portion of the metal nanowire layer into multiple etching layers by using an etching solution configured to etch the metal layer and the metal nanowire layer. A touch panel is further provided.