Abstract: The present disclosure provides a capacitive touch control sensor, comprising a plurality of first electrodes, a plurality of first electrode wires, a plurality of second electrodes and a plurality of second electrode wires. The first and second electrodes are aligned at predetermined gaps. Each of the first electrode wires connects to one of the first electrode. Each of the second electrode wires connects to more than one of the second electrodes in a same column. Each of the plurality of second electrodes encloses one of the first electrodes by preset separation.

Abstract: A capacitive touch control sensor includes a plurality of first electrodes, a plurality of first electrode wires, a plurality of second electrodes, a plurality of second electrode wires. The first and second electrodes are disposed at predetermined interval. The first electrodes have two opposite sensor units and a connecting unit which bridges there-between. Each of the first electrode wires connects one of the first electrodes. Each of the second electrode wires connects more than one of the second electrodes in a same column. The first and second electrodes are arranged alternatively and the neighboring second electrodes are disposed respectively at either side of the connecting unit of the first electrodes.

Abstract: A capacitive touch control sensor includes a plurality of first electrodes, a plurality of first electrode wires, a plurality of second electrodes, a plurality of second electrode wires. The first and second electrodes are disposed at predetermined interval. The first electrodes have two opposite sensor units and a connecting unit which bridges there-between. Each of the first electrode wires connects one of the first electrodes. Each of the second electrode wires connects more than one of the second electrodes in a same column. The first and second electrodes are arranged alternatively and the neighboring second electrodes are disposed respectively at either side of the connecting unit of the first electrodes.

Abstract: The present disclosure provides a capacitive touch control sensor, including a plurality of first and second electrodes, a plurality of first and second electrode wires. The first and second electrodes are aligned at predetermined interval. Each of the first electrode wires connects to one of the first electrodes while each of the second electrode wires connects to more than one of the second electrodes. The first and second electrodes are alternatively disposed so as to reduce manufacturing cost and achieve lower structural profile.

Abstract: The present disclosure provides a capacitive touch control sensor, comprising a plurality of first electrodes, a plurality of first electrode wires, a plurality of second electrodes and a plurality of second electrode wires. The first and second electrodes are aligned at predetermined gaps. Each of the first electrode wires connects to one of the first electrode. Each of the second electrode wires connects to more than one of the second electrodes in a same column. Each of the plurality of second electrodes encloses one of the first electrodes by preset separation.

Abstract: The disclosure is related to a method for manufacturing touch-sensitive element on a polarizer, and a polarization device made by the method. In one of the embodiments of the invention, a polarizing substrate is firstly prepared. The method then coats first transparent conductive material onto the substrate, and uses a patterning process to form multiple sensing areas and wiring areas. There are continuous paths and adjacent non-continuous paths are existed in between the sensing areas. A bridged insulating layer is formed as processing the step for spray-coating or inject-printing insulating material upon the areas of the non-continuous pads. A bridged conductive layer is formed upon the insulation layer as spray-coating or inject-printing a second transparent conductive material there-on. The bridged conductive layer is to electrically connect the non-continuous pads. The method is therefore forming the polarization device with the touch-screen elements.

Abstract: A method for packaging organic electroluminescent (EL) components with polymer passivation layer and structure thereof is developed on the basis of a multi-layer passivation concept to form a wet-adsorption polymer passivation layer for packaging and separating the EL components from moisture and oxygen by a coating or plating process, wherein a surface structure of cathode separators is also put into consideration for enhancement of the passivation layer which is then sealed to substitute for the conventional package-can design.

Abstract: A method for forming electrically conductive bumps on a semiconductor substrate, or a semiconductor wafer and devices formed by the method are disclosed. In the method, a wafer that has an active surface, a plurality of conductive elements formed on the active surface and a passivation layer insulating the plurality of conductive bumps from each other is first provided. A first metal layer is then sputter deposited on top of the plurality of conductive elements and the passivation layer, followed by stencil printing a plurality of bumps of an insulating material on top of each one of the plurality of conductive elements. The plurality of bumps may be heat treated to a temperature of at least 100° C. for a period of at least 10 minutes for stress relief. A second metal layer is then sputter deposited on top of the plurality of bumps and the first metal layer.

Abstract: A method for packaging organic electroluminescent (EL) components with polymer passivation layer and structure thereof is developed on the basis of a multi-layer passivation concept to form a wet-adsorption polymer passivation layer for packaging and separating the EL components from moisture and oxygen by a coating or plating process, wherein a surface structure of cathode separators is also put into consideration for enhancement of the passivation layer which is then sealed to substitute for the conventional package-can design.

Abstract: An anti-static resinous composition with permanent anti-static property is provided. The anti-static resinous composition comprises from 5 to 50 percent by weight of hydrophilic copolymer and from 50 to 95 percent by weight of thermoplastic. The hydrophilic copolymer is formed by self-emulsion polymerization. The monomer mixture used in the reaction comprises from 10 to 70 percent by weight of vinyl or propenyl macromonomer containing a polyethylene oxide chain and from 30 to 90 percent by weight of ordinary vinyl monomer. The thermoplastic is compatible with the hydrophilic copolymer. The resultant resinous composition has permanent anti-static properties.