Abstract: A sputtering system is suitable for sputtering a surface to be sputtered having sections. Each section has a projection height. The sputtering system includes a supporting plate, a sputtering array, and a controller. The sputtering array is arranged on the supporting plate. The sputtering array includes sputtering units. Each section corresponds to at least one of the sputtering units. Each sputtering unit has a driving shaft and a target. The target faces the surface to be sputtered. The controller is electrically connected the driving shaft. The driving shaft drives the target to move relative to the surface to be sputtered. The controller controls a distance between each sputtering unit and the corresponding section of the sections in the direction of the projection height to satisfy a given condition.

Abstract: A sputtering system is suitable for sputtering a surface to be sputtered having sections. Each section has a projection height. The sputtering system includes a supporting plate, a sputtering array, and a controller. The sputtering array is arranged on the supporting plate. The sputtering array includes sputtering units. Each section corresponds to at least one of the sputtering units. Each sputtering unit has a driving shaft and a target. The target faces the surface to be sputtered. The controller is electrically connected the driving shaft. The driving shaft drives the target to move relative to the surface to be sputtered. The controller controls a distance between each sputtering unit and the corresponding section of the sections in the direction of the projection height to satisfy a given condition.

Abstract: A display apparatus includes a panel, a backlight module, a cover, an integrated plastic frame and an optical adhesive. The panel is disposed over the backlight module. The cover is disposed over the panel, which is located between the cover and the backlight module. The integrated plastic frame includes a first accommodating portion, a second accommodating portion and an adhesive-restricting portion. The second accommodating portion is coupled between the first accommodating portion and the adhesive-restricting portion. The combination of the first accommodating portion, the second accommodating portion and the adhesive-restricting portion is integrally formed. The first accommodating portion accommodates at least a portion of the backlight module, the second accommodating portion accommodates the panel, and the adhesive-restricting portion is coupled between the second accommodating portion and the cover to define an accommodating space together with the cover and the panel.

Abstract: A display apparatus includes a display module, a cover, a connecting element and an optical adhesive. The cover is disposed over the display module, and includes a cover portion and an adhesive-restricting portion. The adhesive-restricting portion is protruded from a periphery of a bottom side of the cover portion. The adhesive-restricting portion includes a lower surface facing a surface of the display module. The connecting element is connected between the lower surface of the adhesive-restricting portion and the surface of the display module, and defines an accommodating space together with the cover and the display module. The optical adhesive is disposed in the accommodating space.

Abstract: A low-stress line workpiece and a method for integrally forming the same is disclosed. Firstly, an in-mold injection molding mold is provided, wherein a function film, a 3D curved-surface plastic material, and an anti-rainbow stripe combination layer are placed in the in-mold injection molding mold. The in-mold injection molding mold is used to mold the function film, the plastic material and the combination layer into a low-stress line workpiece integrally formed by in-mold forming. The low-stress line workpiece includes the function film, the plastic layer and the combination layer, wherein the plastic layer is located between the function film and the combination layer. The present invention provides a low-stress line workpiece with high surface hardness and a method for forming the same to reduce lamination fabrication processes and improve lamination yield.

Abstract: A phase-locked loop circuit is disclosed. The circuit includes a digital bang-bang phase-locked loop (PLL) electrically connected to an input clock signal connection and an output clock signal connection, and a down-sampling circuit connected to the input clock signal connection. The circuit also includes a digitally-controlled delay line receiving an output of the down-sampling circuit, and an injection pulser receiving an output of the digitally-controlled delay line and connected to provide an injection pulse to a portion of the digital bang-bang phase-locked loop (PLL). The circuit further includes an injection timing calibration circuit connected to a control input of the digitally-controlled delay line. The circuit provides calibration of injection timing and bandwidth optimization, thereby reducing jitter in an output signal from the PLL.

Abstract: A phase-locked loop circuit is disclosed. The circuit includes a digital bang-bang phase-locked loop (PLL) electrically connected to an input clock signal connection and an output clock signal connection, and a down-sampling circuit connected to the input clock signal connection. The circuit also includes a digitally-controlled delay line receiving an output of the down-sampling circuit, and an injection pulser receiving an output of the digitally-controlled delay line and connected to provide an injection pulse to a portion of the digital bang-bang phase-locked loop (PLL). The circuit further includes an injection timing calibration circuit connected to a control input of the digitally-controlled delay line. The circuit provides calibration of injection timing and bandwidth optimization, thereby reducing jitter in an output signal from the PLL.

Abstract: A low-stress line workpiece and a method for integrally forming the same is disclosed. Firstly, an in-mold injection molding mold is provided, wherein a function film, a 3D curved-surface plastic material, and an anti-rainbow stripe combination layer are placed in the in-mold injection molding mold. The in-mold injection molding mold is used to mold the function film, the plastic material and the combination layer into a low-stress line workpiece integrally formed by in-mold forming The low-stress line workpiece includes the function film, the plastic layer and the combination layer, wherein the plastic layer is located between the function film and the combination layer. The present invention provides a low-stress line workpiece with high surface hardness and a method for forming the same to reduce lamination fabrication processes and improve lamination yield.

Abstract: A one glass solution touch screen panel includes a substrate, a shielding layer, an indium tin oxide film layer, a soft circuit board, an infiltrate layer, and a plurality of conducting connectors. The shielding layer is formed on a first portion of the substrate. The indium tin oxide film layer is formed on a second portion of the substrate and has a plurality of indium tin oxide film connecting portions. The soft circuit board is formed on the shielding layer. The infiltrate layer is formed on the connecting portions and defines a plurality of infiltrate gaps within the infiltrate layer. The conducting connectors are formed on the infiltrate layer. The conducting connectors are electrically connected to the soft circuit board. The conducting connectors extend into the infiltrate layer substantially filling a substantial portion of the plurality of infiltrate gaps and electrically connecting to the connecting portions.

Abstract: A transparent conductive film includes a transparent substrate. A support layer is formed on one surface of the substrate. A surface of the support layer away from the substrate defines grooves formed in a mesh pattern. An ink layer is formed at a bottom of the grooves. A conductive layer is formed on the ink layer and in a mesh pattern. A top of the conductive layer protrudes out of the grooves.

Abstract: A transparent conductive film includes a transparent substrate. A support layer is formed on one surface of the substrate. A surface of the support layer away from the substrate defines grooves formed in a mesh pattern. The grooves include a first groove portion and a second groove portion communicating with the first groove portion. A depth of the first groove portion is less than that of the second groove portion. An ink layer is formed at a bottom of the first groove portion and the second groove portion. A conductive layer is formed on the ink layer and in a mesh pattern. A top of the conductive layer formed in the first groove portion protrudes out of the first groove portion, and the conductive layer formed in the second groove portion is totally received in the second groove portion.

Abstract: A conductive laminate includes a base layer, an insulative layer on the base layer, an ink layer having a latticed structure on the insulative layer, and a conductive metal layer having a latticed structure on the ink layer. The insulative layer contains a transparent and insulative adhesive.

Abstract: A method for manufacturing a touch panel includes the following procedures. A first conductive layer and a shielding layer surrounding the first conductive layer are formed on a base plate. The first conductive layer is etched to form a plurality of first and second sensing pads alternatively arranged according to columns. The first sensing pads in a column along a first direction are electrically coupled to each other to form a first sensing electrode column. The second sensing pads in a column along a second direction are electrically coupled to each other to form a second sensing electrode column. A second conductive layer is formed on the shielding layer via an ink jet printing method, and is etched to form a plurality of first and second sensing lines to be respectively electrically coupled to the first and second sensing electrode columns.

Abstract: A method for manufacturing a touch panel includes the following procedures. A base plate is provided. A conductive layer is formed on the base plate. The conductive layer is etched to form a plurality of first and second electrodes which are alternatively arranged according to columns on the base plate and insulated from each other, and the first electrodes in a column along a first direction are electrically coupled to each other. A plurality of insulated layers is formed on the first and second electrodes. A plurality of conductive rings coupled to each other in an order are formed on each insulated layer via an ink jet printing method to electrically interconnect with each neighboring second electrodes in a column along the second direction intersecting the first direction. The present disclosure further provides a touch panel manufactured by the method.

Abstract: A method for manufacturing a touch panel includes the following procedures. A base plate is provided. An indium tin oxide film is formed on the base plate. The indium tin oxide film is etched to form a plurality of first and second electrodes which are alternatively arranged according to columns on the base plate and insulated from each other, and the first electrodes in a column along a first direction are electrically coupled to each other. A plurality of insulated layers is formed on the first and second electrodes. A plurality of conductive connectors are formed on the plurality of insulated layers via an ink jet printing method to electrically interconnect with the second electrodes in a column along the second direction intersecting the first direction. The widths of the conductive connectors are reduced below 10 ?m via a laser processing method.

Abstract: A method for manufacturing a touch panel includes the following procedures. A first conductive layer and a shielding layer surrounding the first conductive layer are formed on a base plate. The first conductive layer is etched to form a plurality of first and second sensing pads alternatively arranged according to columns. The first sensing pads in a column along a first direction are electrically coupled to each other to form a first sensing electrode column. The second sensing pads in a column along a second direction are electrically coupled to each other to form a second sensing electrode column. A second conductive layer is formed on the shielding layer via an ink jet printing method, and is etched to form a plurality of first and second sensing lines to be respectively electrically coupled to the first and second sensing electrode columns.

Abstract: A glass sheet includes a base plate, a first coating layer, a second coating layer, and a shielding layer. The base plate includes a display area, and a non-display area surrounding the display area. The first coating layer is formed on the non-display area of the base plate, includes a first bright colored ink, and defines a number of wiredrawing finishing textures separated from each other. The second coating layer is filled in the number of wiredrawing finishing textures, includes a second bright colored ink, and is darker in color than the first coating layer. The shielding layer is formed on the first coating layer and the second coating layer, and completely covers the non-display area. The present disclosure further provides a method for manufacturing the glass sheet.

Abstract: A one glass solution touch screen panel includes a substrate, a shielding layer, an indium tin oxide film layer, a soft circuit board, an infiltrate layer, and a plurality of conducting connectors. The shielding layer is formed on a first portion of the substrate. The indium tin oxide film layer is formed on a second portion of the substrate and has a plurality of indium tin oxide film connecting portions. The soft circuit board is formed on the shielding layer. The infiltrate layer is formed on the connecting portions and defines a plurality of infiltrate gaps within the infiltrate layer. The conducting connectors are formed on the infiltrate layer. The conducting connectors are electrically connected to the soft circuit board. The conducting connectors extend into the infiltrate layer substantially filling a substantial portion of the plurality of infiltrate gaps and electrically connecting to the connecting portions.

Abstract: A touch screen panel includes a substrate, a plurality of first electrodes formed on the substrate and extending along a first axis direction, a plurality of second electrodes formed on the substrate and extending along a second axis substantially perpendicular to the first axis; and a plurality of conducting connectors. Each conducting connector electrically couples with two neighboring second electrodes among the plurality of second electrodes in a same row without contacting the first electrodes.

Abstract: A touch screen panel includes a substrate, a plurality of first electrodes formed on the substrate and extending along a first direction, a plurality of second electrodes formed on the substrate and extending along a second direction substantially perpendicular to the first direction; and a plurality of conducting connectors. The conducting connectors are made of a metallic material. A surface of each conducting connector is processed by oxidation treatment for forming oxides, or treated by sulfidizing.