Abstract: The present disclosure relates to a touch technology, and more particularly, to a touch panel and a manufacturing method the same. A touch panel is provided, comprising an inductive electrode layer and a patterned protective layer covering the inductive electrode layer; wherein formative pattern of the patterned protective layer is identical to that of the inductive electrode layer. The present disclosure also provides a manufacturing method for touch panels. A touch panel and a manufacturing method the same are provided in the present disclosure, in which the patterned protective layer is used for covering the inductive electrode layer to isolate the inductive electrode layer from oxygen and overcome the influence of oxygen on the diamond resistance changes of conductive materials under the condition of high-temperature baking, thereby enhancing the accuracy of touch positions recognized by touch panel.

Abstract: The present disclosure relates to a touch technology, and more particularly, to a touch panel and a manufacturing method the same. A touch panel is provided, comprising an inductive electrode layer and a patterned protective layer covering the inductive electrode layer; wherein formative pattern of the patterned protective layer is identical to that of the inductive electrode layer. The present disclosure also provides a manufacturing method for touch panels. A touch panel and a manufacturing method the same are provided in the present disclosure, in which the patterned protective layer is used for covering the inductive electrode layer to isolate the inductive electrode layer from oxygen and overcome the influence of oxygen on the diamond resistance changes of conductive materials under the condition of high-temperature baking, thereby enhancing the accuracy of touch positions recognized by touch panel.

Abstract: The present invention relates to a touch panel. The touch panel includes a substrate, a plurality of first traces, a plurality of second traces, and a plurality of sensing pads. The first traces are disposed on the substrate and are parallel to each other along a first direction. The second traces are disposed on the substrate and are parallel to each other along a second direction. The first traces and the second traces interlace with each other to form a plurality of sensing pad areas. Each sensing pad is disposed in each sensing pad area, and is electrically connected to each first trace and each second trace. The present invention further provides a method of operating the same. In the present invention, the thickness of the touch panel is decreased, and the material for the electrodes is economized. Consequently, the costs of the touch panel can be reduced.

Abstract: The present disclosure provides a touch device comprising at least one first conductive axis, a plurality of second conductive units, a plurality of bridging structures and an insulating layer. The first conductive axis has a plurality of openings in which the second conductive units are located respectively. There is a space existed between each of the second conductive units and the corresponding first conductive axis. Each of the majority of the bridging structures are electrically connected to every two adjacent second conductive units in two adjacent first conductive axes. The insulating layer is located between the bridging structure and the first conductive axis. The insulating layer has a plurality of holes exposing the second conductive units respectively, and the bridging structures connect to the second conductive through the holes. In addition, the disclosure also provides an electrostatic shielding method of touch device.

Abstract: A touch panel having a shielding layer and a manufacturing method thereof is provided. A manufacturing method of the touch panel comprises the steps of forming a plurality of first conductive axes and a plurality of second conductive units on a substrate; covering the first conductive axes and the second conductive units with an insulating layer and exposing at least a partial set of second conductive units; and forming a plurality of bridging structures and a shielding layer on the insulating layer simultaneously, wherein the bridging structures electrically connect to the second conductive units. The proposed method allows the shielding layer to be formed during the formation of the bridging structures, thereby eliminating the step of forming the shielding layer separately through an independent process, which saves costs and time.

Abstract: The present disclosure relates to a touch display device. The touch display device comprises a pixel control layer having a plurality of pixel electrodes, a touch sensing layer disposed corresponding to the pixel control layer, wherein the touch sensing layer comprises a plurality of sensing pads and each sensing pad corresponds to each pixel electrode, and a liquid crystal layer disposed between the pixel control layer and the touch sensing layer.

Abstract: The present disclosure relates to a touch technology, and more particularly, to a touch panel and a manufacturing method the same. A touch panel is provided, comprising an inductive electrode layer and a patterned protective layer covering the inductive electrode layer; wherein formative pattern of the patterned protective layer is identical to that of the inductive electrode layer. The present disclosure also provides a manufacturing method for touch panels. A touch panel and a manufacturing method the same are provided in the present disclosure, in which the patterned protective layer is used for covering the inductive electrode layer to isolate the inductive electrode layer from oxygen and overcome the influence of oxygen on the diamond resistance changes of conductive materials under the condition of high-temperature baking, thereby enhancing the accuracy of touch positions recognized by touch panel.

Abstract: The present disclosure provides a touch device comprising at least one first conductive axis, a plurality of second conductive units, a plurality of bridging structures and an insulating layer. The first conductive axis has a plurality of openings in which the second conductive units are located respectively There is a space existed between each of the second conductive units and the corresponding first conductive axis. Each of the majority of the bridging structures are electrically connected to every two adjacent second conductive units in two adjacent first conductive axes. The insulating layer is located between the bridging structure and the first conductive axis. The insulating layer has a plurality of holes exposing the second conductive units respectively, and the bridging structures connect to the second conductive through the holes. In addition, the disclosure also provides an electrostatic shielding method of touch device.

Abstract: The present disclosure relates to a touch panel and a manufacturing method thereof, and more particularly, relates to a touch panel having a shielding layer. A manufacturing method of the touch panel provided in the present disclosure comprises of the steps of forming a plurality of first conductive axes and a plurality of second conductive units on a substrate; covering the first conductive axes and the second conductive units with an insulating layer and exposing at least a partial set of second conductive units; and forming a plurality of bridging structures and a shielding layer on the insulating layer simultaneously, wherein the bridging structures electrically connect to the second conductive units. The proposed method allows the shielding layer to be formed during the formation of the bridging structures, thereby eliminating the step of forming the shielding layer separately through an independent process, which saves costs and time.

Abstract: The present disclosure relates to a touch display device. The touch display device comprises a pixel control layer having a plurality of pixel electrodes, a touch sensing layer disposed corresponding to the pixel control layer, wherein the touch sensing layer comprises a plurality of sensing pads and each sensing pad corresponds to each pixel electrode, and a liquid crystal layer disposed between the pixel control layer and the touch sensing layer.

Abstract: The present invention relates to a touch panel. The touch panel includes a substrate, a plurality of first traces, a plurality of second traces, and a plurality of sensing pads. The first traces are disposed on the substrate and are parallel to each other along a first direction. The second traces are disposed on the substrate and are parallel to each other along a second direction. The first traces and the second traces interlace with each other to form a plurality of sensing pad areas. Each sensing pad is disposed in each sensing pad area, and is electrically connected to each first trace and each second trace. The present invention further provides a method of operating the same. In the present invention, the thickness of the touch panel is decreased, and the material for the electrodes is economized. Consequently, the costs of the touch panel can be reduced.