Abstract: In a structure of a bridging electrode, the structure of a bridging electrode applied to a capacitive touchpad, the structure comprising: a substrate; a plurality of first electrode blocks disposed on the substrate and electrically connected together in series through a first wire; a plurality of second electrode blocks disposed on the substrate and respectively disposed on two sides of the first wire; and a bridging insulation unit, which is perpendicular to and disposed on the first wire and having a bridging groove; wherein the second electrode blocks connecting electrically together in series through the bridging insulation unit having a second wire.

Abstract: A layout method of a touch panel electrode includes the steps of: providing a substrate; forming a first electro-conductive layer, having pattern blocks disposed adjacently to one another, on one side of the substrate, wherein the first electro-conductive layer is transparent; forming an alignment film on the one side of the substrate; forming an second electro-conductive layer, having wires to be connected to at least one of the pattern blocks, on the one side of the substrate; and forming a protection layer on the second electro-conductive layer to protect the second electro-conductive layer. The present invention can reduce the processes of manufacturing the conventional electrode, especially do not needs to form another electro-conductive layer and another protection layer on the other side of the substrate, and can effectively prevent the electrostatic charge effect and increase the capacitance and sensitivity.

Abstract: A layout method of a touch panel electrode includes the steps of: providing a substrate; forming a first electro-conductive layer, having pattern blocks disposed adjacently to one another, on one side of the substrate, wherein the first electro-conductive layer is transparent; forming an alignment film on the one side of the substrate; forming an second electro-conductive layer, having wires to be connected to at least one of the pattern blocks, on the one side of the substrate; and forming a protection layer on the second electro-conductive layer to protect the second electro-conductive layer. The present invention can reduce the processes of manufacturing the conventional electrode, especially do not needs to form another electro-conductive layer and another protection layer on the other side of the substrate, and can effectively prevent the electrostatic charge effect and increase the capacitance and sensitivity.

Abstract: In a structure of a bridging electrode, the structure of a bridging electrode applied to a capacitive touchpad, the structure comprising: a substrate; a plurality of first electrode blocks disposed on the substrate and electrically connected together in series through a first wire; a plurality of second electrode blocks disposed on the substrate and respectively disposed on two sides of the first wire; and a bridging insulation unit, which is perpendicular to and disposed on the first wire and having a bridging groove; wherein the second electrode blocks connecting electrically together in series through the bridging insulation unit having a second wire.

Abstract: In a structure of a bridging electrode, the structure of a bridging electrode applied to a capacitive touchpad, the structure comprising: a substrate; a plurality of first electrode blocks disposed on the substrate and electrically connected together in series through a first wire; a plurality of second electrode blocks disposed on the substrate and respectively disposed on two sides of the first wire; and a bridging insulation unit, which is perpendicular to and disposed on the first wire and having a bridging groove; wherein the second electrode blocks connecting electrically together in series through the bridging insulation unit having a second wire.

Abstract: A layout method of a touch panel electrode includes the steps of: providing a substrate; forming a first electro-conductive layer, having pattern blocks disposed adjacently to one another, on one side of the substrate, wherein the first electro-conductive layer is transparent; forming an alignment film on the one side of the substrate; forming an second electro-conductive layer, having wires to be connected to at least one of the pattern blocks, on the one side of the substrate; and forming a protection layer on the second electro-conductive layer to protect the second electro-conductive layer. The present invention can reduce the processes of manufacturing the conventional electrode, especially do not needs to form another electro-conductive layer and another protection layer on the other side of the substrate, and can effectively prevent the electrostatic charge effect and increase the capacitance and sensitivity.

Abstract: A layout method for a bridging electrode capable of shielding a bright spot includes the steps of: providing a substrate; forming a transparent electroconductive layer, having neighboring pattern blocks, on the substrate; forming an alignment film layer, having bridging grooves for crossing between the pattern blocks, over the substrate; forming an electroconductive layer, having wires respectively correspondingly disposed over the bridging grooves, over the substrate; forming an electroconductive correspondence layer on one side of the electroconductive layer to shield the wires; and forming a protection layer over the substrate to enhance optical transmission and protect the substrate, the transparent electroconductive layer, the alignment film layer and the electroconductive layer. Meanwhile, the invention also provides a structure of the bridging electrode capable of shielding the bright spot and corresponding to the layout method.

Abstract: In a layout method of a bridging electrode, the method includes the steps of: providing a substrate; forming a transparent electro-conductive layer on the substrate and the transparent electro-conductive layer having a plurality of neighboring patterned blocks; forming an alignment film layer on the substrate and the alignment film layer having a plurality of bridging grooves of a bridging insulation unit crossing between the patterned blocks; forming an electro-conductive layer on the substrate and the electro-conductive layer having a plurality of wires respectively disposed on the bridging grooves, wherein the wires of the electro-conductive layer being formed through an optical compensation mask in conjunction with at least one of over-exposure and over-development; and forming a protection layer on the substrate to enhance optical transmission and to protect the substrate, the transparent electro-conductive layer, the alignment film layer and the electro-conductive layer.

Abstract: A layout method of a touch panel electrode includes the steps of: providing a substrate; forming a first electro-conductive layer, having pattern blocks disposed adjacently to one another, on one side of the substrate, wherein the first electro-conductive layer is transparent; forming an alignment film on the one side of the substrate; forming an second electro-conductive layer, having wires to be connected to at least one of the pattern blocks, on the one side of the substrate; and forming a protection layer on the second electro-conductive layer to protect the second electro-conductive layer. The present invention can reduce the processes of manufacturing the conventional electrode, especially do not needs to form another electro-conductive layer and another protection layer on the other side of the substrate, and can effectively prevent the electrostatic charge effect and increase the capacitance and sensitivity.

Abstract: A layout method for a bridging electrode capable of shielding a bright spot includes the steps of: providing a substrate; forming a transparent electroconductive layer, having neighboring pattern blocks, on the substrate; forming an alignment film layer, having bridging grooves for crossing between the pattern blocks, over the substrate; forming an electroconductive layer, having wires respectively correspondingly disposed over the bridging grooves, over the substrate; forming an electroconductive correspondence layer on one side of the electroconductive layer to shield the wires; and forming a protection layer over the substrate to enhance optical transmission and protect the substrate, the transparent electroconductive layer, the alignment film layer and the electroconductive layer. Meanwhile, the invention also provides a structure of the bridging electrode capable of shielding the bright spot and corresponding to the layout method.

Abstract: In a layout method of a bridging electrode, the method includes the steps of: providing a substrate; forming a transparent electro-conductive layer on the substrate and the transparent electro-conductive layer having a plurality of neighboring patterned blocks; forming an alignment film layer on the substrate and the alignment film layer having a plurality of bridging grooves of a bridging insulation unit crossing between the patterned blocks; forming an electro-conductive layer on the substrate and the electro-conductive layer having a plurality of wires respectively disposed on the bridging grooves, wherein the wires of the electro-conductive layer being formed through an optical compensation mask in conjunction with at least one of over-exposure and over-development; and forming a protection layer on the substrate to enhance optical transmission and to protect the substrate, the transparent electro-conductive layer, the alignment film layer and the electro-conductive layer.

Abstract: In a structure of a bridging electrode, the structure of a bridging electrode applied to a capacitive touchpad, the structure comprising: a substrate; a plurality of first electrode blocks disposed on the substrate and electrically connected together in series through a first wire; a plurality of second electrode blocks disposed on the substrate and respectively disposed on two sides of the first wire; and a bridging insulation unit, which is perpendicular to and disposed on the first wire and having a bridging groove; wherein the second electrode blocks connecting electrically together in series through the bridging insulation unit having a second wire.