Abstract: A touch panel and a manufacturing method thereof are provided. The touch panel includes a substrate, a plurality of conductive patterns, a plurality of signal transmitting lines, a plurality of first pad portions, a plurality of second pad portions and at least one auxiliary pattern. The first pad portions are separately arranged along a first path. The second pad portions are insulated from the first pad portions. The second pad portions are separately arranged along a second path. At least one auxiliary pattern is disposed between two adjacent first pad portions, between two adjacent second pad portions, or between one of the first pad portions and one of the second pad portions which are adjacent. The insulating intervals are disposed between adjacent first pad portions and between adjacent second pad portions.

Abstract: The present invention to provide methods and related controllers that manage HARQ processes in a wireless communications system. The present invention provides a method and related controller to map data units (e.g. PDU) of importance that is to be transmitted to a HARQ process having a higher transmission success rate to prevent the data units from being transmitted via a HARQ process having more transmission failures. In addition, the present invention also provides a method and a related controller to force a HARQ process to retransmit a data unit that has been correctly received by a receiving end to reduce the latency of retransmission caused by a possible transmission failure occurring between a MAC layer and a RLC layer at the receiving end.

Abstract: The disclosure provides a Ni—Mn composite oxalate powder, including a plurality of biwedge octahedron particles represented by the general formula: NiqMnxCoyMzC2O4.nH2O, wherein q+x+y+z=1, 0<q, x<1, 0?y<1, 0?z<0.15, 0?n?5, and M is at least one of Mg, Sr, Ba, Cd, Zn, Al, Ga, B, Zr, Ti, Ca, Ce, Y, Nb, Cr, Fe and V. The above powder may be further calcined with a lithium salt to form a lithium transition metal oxide powder for use as a positive electrode material in lithium ion-batteries.

Abstract: A touch panel includes a substrate, a plurality of first conductive elements, and a plurality of second conductive elements. Each of the first conductive elements includes a plurality of first conductive patterns and a plurality of first connection portions alternately connected with each other. The first conductive elements and the second conductive elements are intersected with each other and electrically insulated. Each of the second conductive elements includes a plurality of intersection portions respectively intersected with the first connection portions of each of the first conductive elements. A linewidth of the intersection portions is W1, and 100 ?m<W1?300 ?m.

Abstract: A device for adjusting gap between platen and print head includes a base, a printing unit, a platen and a pair of adjusting elements. The printing unit is located on the base and includes a print head. The platen is located between the printing unit and the base, in which the platen has a platen-portion and a pair of adjusting-portions, the adjusting-portions are disposed at opposite sides of the platen-portion, and each of the adjusting-portions has a step-guiding-surface. The adjusting elements are disposed beside the platen and correspondingly contact the step-guiding-surfaces of the adjusting-portions, in which the distance between the platen and the print head is varied with positions of the adjusting elements relative to the step-guiding-surfaces.

Abstract: A touch panel and a manufacturing method thereof are provided. The touch panel includes an insulating layer, a plurality of first conductive electrodes, a plurality of second conductive electrodes, a plurality of first auxiliary electrodes and a plurality of second auxiliary electrodes. The insulating layer has a plurality of through holes. The first conductive electrodes are arranged along a first direction and electrically connected with each other. The second conductive electrodes are arranged along a second direction and electrically connected with each other. The first auxiliary electrodes and the first conductive electrodes are electrically connected via part of the though holes. The second auxiliary electrodes and the second conductive electrodes are electrically connected via another of the though holes.

Abstract: A touch panel includes a substrate, first conductive series, second conductive series, and insulation patterns. Each of the first conductive series includes first conductive patterns arranged in a first direction and first narrow portions, and each first narrow portion is connected to two adjacent first conductive patterns. The second conductive series are insulated from the first conductive series. Each of the second conductive series extends in a second direction and includes a plurality of intersections intersected with the first narrow portions. The insulation patterns are located between the first narrow portions and the intersections, so that one of the first narrow portions and a respective one of the intersections intersected with the one of the first narrow portions are separate. An edge of each of the insulation patterns and one of the first conductive patterns of each of the first conductive series partially overlap.

Abstract: A touch panel is provided. The touch panel includes multiple sensing units, multiple connecting wires and multiple bridge wires. A part of the sensing units are arranged along a first direction, and another part of the sensing units are arranged along a second direction. A part of the connecting wires and a part of the bridge wires are connected to the part of the sensing units along the first direction. Another part of connecting wires and another part of bridge wires are connected to the another part of the sensing units along the second direction. The impedance value of each bridge wire is different from that of each connecting wire.

Abstract: A touch apparatus and a driving method thereof are provided. The touch apparatus includes a plurality of firs electrodes, a plurality of second electrodes, a first driving sensing unit, a second sensing driving unit and a control unit. The first electrodes are disposed sequentially along a first direction, and each second electrode is adjacent to the corresponding first electrode sequentially along a second direction. In a first touch mode, the control unit controls the first sensing driving unit to provide a first driving signal to the first electrodes, and controls the second sensing driving unit to receive a plurality of first touch signal from the second electrodes. In a second touch mode, the control unit controls the second driving sensing unit to provide a second driving signal to the second electrodes, and controls the first sensing driving unit to receive a plurality of second touch signal from the first electrodes.

Abstract: A touch panel including a substrate, first electrodes, second electrodes, first wires, second wires and a means for shortening a gap between the second electrodes in a third direction is provided. The first electrodes are arranged sequentially in a first direction. Each first electrode has openings arranged in a second direction intersecting the first direction. The second electrodes are located in the openings. Each first electrode and the second electrodes surrounded by the first electrode constitute a sensing unit. The first wires and the second wires connect the first electrodes and the second electrodes to a driving circuit. The means for shortening the gap between the second electrodes in the third direction renders a ratio of the gap between the second electrodes in the third direction to that in the second direction to be smaller than 1:3.4, where the third direction intersects either the first direction or the second direction.

Abstract: A touch-sensing electrode structure includes multiple first electrodes and multiple second electrodes. Each of the first electrodes includes at least a first major part and a second major part, the first major part and the second major part cross over each other to form at least one interconnect section, the interconnect section includes a first connecting line extending in a first direction and a second connecting line extending in a second direction different to the first direction. Each of the second electrodes includes a plurality of electrode sections and third connecting lines, each of the third connecting lines is connected between two adjacent electrode sections, the third connecting lines extend in a third direction different to the first direction and the second direction, and at least one of the third connecting lines overlaps the interconnect section.

Abstract: A touch panel, having a viewing region and a peripheral region adjacent to at least one edge of the viewing region, includes a plurality of first axis electrodes, a plurality of second axis electrodes, and a plurality of first traces. The first axis electrodes are disposed in the viewing region and extend along a first direction. The second axis electrodes are disposed in the viewing region and extend along a second direction. The first direction is not parallel to the second direction. The first traces are at least partially disposed in the viewing region. Each of the first traces is electrically connected to at least one of the first axis electrodes. The first traces extend from the viewing region to the peripheral region.

Abstract: A touch panel, having a center region and a peripheral region disposed on at least one side of the center region, includes a first electrode. The first electrode includes a plurality of first sub-electrodes and a plurality of second sub-electrode. The first sub-electrodes are disposed in the center region, and the second sub-electrodes are disposed on the peripheral region. A pattern density of the second sub-electrodes in the peripheral region is higher than a pattern density of the first sub-electrodes in the center region.

Abstract: An active device and an active device array substrate are provided, wherein the active device array substrate includes a substrate and a plurality of active devices being located on the substrate, and at least one of the active devices includes a first thin film transistor and a second thin film transistor. The first thin film transistor is located on the substrate and has a first channel layer. The second thin film transistor stacks on the first thin film transistor, wherein the second thin film transistor has a second channel layer. The first thin film transistor and the second thin film transistor share a common gate electrode and the common gate electrode is located between the first channel layer and the second channel layer.

Abstract: A liquid crystal display (LCD) panel is provided. The LCD panel includes a plurality of pixel units each having a storage capacitor, a plurality of scan lines coupled to the pixel units, and a plurality of storage capacitor charge transistors each respectively coupled to the storage capacitors of the corresponding pixel units and further coupled to two of the scan lines. The storage capacitor charge transistors are used for charging the storage capacitors of the pixel units.

Abstract: In one embodiment of the disclosure, a composite raw material and a method for forming the same are provided. The method includes sulfonating a polycyclic aromatic compound to form a polycyclic aromatic carbon sulfonate (PCAS); and mixing the polycyclic aromatic carbon sulfonate and a polyacrylonitrile (PAN) to form a composite raw material. In another embodiment of the disclosure, a carbon fiber containing the composite raw material described above and a method for forming the same are provided.

Abstract: A touch panel including a carrier component, a plurality of first electrode series and a plurality of second electrode series is provided. Each first electrode series includes a plurality of first electrodes connected in series in a first direction. Each second electrode series includes a plurality of second electrodes connected in series in a second direction. In a unit sensing area arbitrarily selected on the touch panel, a ratio of the unit sensing area occupied by each of the first electrodes to the unit sensing area occupied by each of the second electrodes is 1:1.2 to 1:1.4, wherein a length and a width of the unit sensing area are equal to pitches of the first electrodes in the first direction and the second direction respectively.

Abstract: In one embodiment of the disclosure, a copolymer and method for manufacturing the same are provided. The copolymer is copolymerized from a composition including: (a) a first hydrophilic monomer, including itaconamic acid, itaconamic salt, or combinations thereof; and (b) a second hydrophilic monomer, including acrylic acid, acrylic salt, acrylamide, or combinations thereof.

Abstract: A precursor raw material for the PAN-based carbon fibers represented by Formula (I) is provided. In Formula (I), R is methyl, ethyl or propyl, x+z=0.5-20.0 mol %, z?0.5 mol %, y=99.5-80.0 mol % and x+y+z=100 mol %. The invention also provides a PAN-based oxidized fiber and a PAN-based carbon fiber prepared by the precursor raw material for the PAN-based carbon fibers.

Abstract: A touch panel including a substrate, a decoration layer, and conductive elements is provided. The decoration layer has an outer margin adjacent to an edge of the substrate and an inner margin opposite to the outer region. A reference line is away from the inner margin with a distance of at least 20 ?m towards a direction away from the outer margin. At least one of the conductive elements includes a cross-interface portion which covers the decoration layer and a region of the substrate without the decoration layer. A first distance and a second distance between two adjacent cross-interface portions are provided in a region outward of the reference line to the outer margin of the decoration layer, and in a region inward of the reference line, respectively. The first distance is greater than the second distance. The conductive elements construct touch sensing units for forming a capacitance coupling.