Abstract: A touch panel with a fingerprint identification function includes a cover plate, a mask layer, a flexible substrate, and a fingerprint sensing array. The mask layer is disposed on the cover plate for defining an operating, region and a non-operating, region of the touch panel. The flexible substrate is disposed on the mask layer and at least in the non-operating region. The fingerprint sensing array is directly disposed on the flexible substrate in the non-operating region. Through the configuration that the fingerprint sensing array is disposed on the flexible substrate, the distance between the fingerprint sensing array and a user's fingers is reduced, thereby increasing the sensitivity of fingerprint identification.

Abstract: The disclosure provides a sensing structure of a touch panel, which includes a shielding layer and a sensing layer. The shielding layer is provided with one hollow portion, and the sensing layer is arranged under the shielding layer and located around the hollow portion. The disclosure further provides a cover plate structure of a touch panel and the touch panel. In the touch panel, the cover plate structure of the touch panel and the sensing structure of a touch panel provided by the disclosure, the sensing layer is located under the shielding layer and around the hollow portion. Thus, the sensing layer is covered by the shielding layer and avoids the hollow portion of a pattern zone, so that the sensing layer cannot be seen through the hollow portion, and the appearance quality of the touch panel is improved.

Abstract: The disclosure provides a touch device, including a protection cover, a pressure-sensing layer and a flat touch-sensing electrode layer. The protection cover is used as an outer protection shield, and an upper surface of the protection cover is provided to users for pressing action. The pressure-sensing layer is disposed under the protection cover to detect touch strength. The flat touch-sensing electrode layer is disposed between the pressure-sensing layer and the protection cover to detect the position of the user's touch.

Abstract: A touch control apparatus with fingerprint identification function includes a substrate body with a visible region, a plurality of first primary electrodes, a plurality of second primary electrodes, and a fingerprint identification region located in the visible region. The first primary electrodes and the second primary electrodes are mounted in the visible region for sensing a touch coordinate when an object touches on the visible region. The first secondary electrodes are crossly arranged and insulated from the second secondary electrodes in the fingerprint, identification region. Further, a part of the first primary electrodes and the second primary electrodes are extended to the fingerprint identification region. When a user performs a fingerprint identification function, all electrodes in the fingerprint identification region are used to detect and identify the user's fingerprint.

Abstract: A touch panel comprises a substrate, a first mask structure and a dense structure. The first mask structure is disposed on a surface of the substrate and divides the substrate into a mask area and a visible area disposed adjacent to the mask area. The first mask structure is disposed in the mask area. The dense structure at least masks a surface of the first mask structure farther from the substrate.

Abstract: The present disclosure provides a manufacturing method of a touch panel that comprises of: simultaneously baking a sensing electrode layer and a protective layer that covers the sensing electrode layer. The present disclosure solves the issue of the sensing electrode layer being easily oxidized or corroded when baked alone. The present disclosure also simplifies the manufacturing process of the touch panel. The present disclosure also provides a touch panel on the basis of the manufacturing method.

Abstract: The present invention is to provide a method for transmitting information between multiple electronic pages. The method is applicable to an information transmission system, which includes at least one terminal device, a web server, a toolbar server and an application server. The terminal device obtains a background page from the web server and a toolbar page from the toolbar server and embeds the toolbar page into the background page. When a user clicks on any of at least one application linking object on the toolbar page through the terminal device, the terminal device is able to obtain a status page from the toolbar server and then store page information on the background or toolbar page into the status page and connect to the application server for obtaining an application page corresponding to the application linking object clicked on, so as to enable the application page to access the page information.

Abstract: A touch panel comprises a flexible touch sensor and a cover plate. The cover plate and the flexible touch sensor are attached to each other by an adhesive layer. The flexible touch sensor at least comprises a sensing electrode structure disposed on a flexible substrate. The sensing electrode structure comprises a first insulating layer and a first patterned conductive layer formed on the first insulating layer. The first insulating layer is disposed between the flexible substrate and the first patterned conductive layer and directly contacts the flexible substrate.

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 provides a touch panel which at least comprises a sensing area, a conductive wire area, and earthing lines. The conductive wire area surrounds the sensing area and is electrically connected to the sensing area, and the conductive wire area comprises a first conductive wire area and a second conductive wire area. The earthing lines are set between the first conductive wire area and the second conductive wire area. The touch panel can efficiently shield signal crosstalk between the first conductive wire area and the second conductive wire area by setting the earthing lines between the first conductive wire area and the second conductive wire area, thereby reducing the influence of signal crosstalk on efficiency of the touch panel.

Abstract: A touch panel comprises a transparent substrate and a non-transparent insulation layer disposed on the transparent substrate. The non-transparent insulation layer has a first opening, and a second opening corresponding to a graphic region. The touch panel further comprises transparent conductive patterns disposed in the first opening and the second opening, and non-transparent conductive patterns disposed on the non-transparent insulation layer outside of the graphic region. The non-transparent conductive patterns electrically connect the transparent conductive pattern in the second opening.

Abstract: For a touch panel module, a first sensing unit is disposed on a viewing area of a substrate and includes a first electrode, a second sensing unit corresponds in position to a non-viewing area of the substrate and includes a first sub-electrode, an attaching portion corresponds in position to the non-viewing area and includes a first contact, and a first conducting wire, two ends of which are respectively connected to the first electrode and the first contact to form an electrical connection therebetween, and a connecting portion corresponds in position to the non-viewing area and includes a first conducting sub-wire for forming electrical connection between the first electrode and the first sub-electrode.

Abstract: The present invention is to provide a method applicable to a network system for automatically inserting an embedded toolbar into a web browser directly by way of a gateway device, wherein a toolbar request instruction written in a dynamic scripting language is inserted into a web page message by the gateway device while the web page message is transmitted from a web server to a terminal device (e.g., a personal computer, personal digital assistant, etc.) through the gateway device, so as to enable the web browser of the terminal device to request an embedded toolbar serve for providing an embedded toolbar message according to the toolbar request instruction and then show an embedded toolbar corresponding to the embedded toolbar message on a web page received from the web server according to the web page message. Thus, a user of the terminal device doesn't have to install the embedded toolbar additionally.

Abstract: A touch panel and a touch electrode structure thereof are provided. The touch electrode structure defines position units and includes electrodes electrically insulated from each other. Each of the electrodes covers more than one of the position units and comprises a plurality of sub-electrodes electrically insulated from each other. Each of the sub-electrodes includes sub-electrode units. Each of the position units is corresponding to at least one of the sub-electrode units of at least one of the sub-electrode, and combinations of the sub-electrode units of the different sub-electrodes in the respective position units are different. In the touch electrode structure, each electrode can be electrically independent without needing to dispose a jumper and an insulating layer, thus simplifying process steps and improving a yield rate at the same time.

Abstract: A touch panel includes a plurality of first electrodes arranged along a first direction and parallel to each other, wherein each first electrode includes a plurality of first electrode blocks and a plurality of first connection traces. A plurality of second electrodes arranged along a second direction and parallel to each other, wherein each second electrode includes a plurality of second electrode blocks and a plurality of second connection traces. And a plurality of insulating blocks, wherein each insulating block includes a main portion and at ;east one extending portion, the main portion is disposed between each first connection trace and each second connection trace, the extending portion extends from the main portion to the space between the first electrode block and the second electrode block. The present invention further provides a method for forming the touch panel mentioned above.

Abstract: A control server is electronically connected with a number of test servers via a number network interfaces. The control server records a network interface number and an IP address of a baseboard management controller (BMC) of each test server, sets an IP address of a network card of the control server, and generates a test command. The test command comprises information in relation to a number of times for powering on a test server, a number of times for powering off the test server, and a time interval between a power-on operation and a power-off operation. The test command is sent to each test server by the control server according to the network interface number and the IP address of the test server. After receiving the test command, the BMC of the test server performs power-on/power-off operations of the test server according to the test command.

Abstract: The present disclosure relates to an input interface and particularly to a novel touch panel which includes a plurality of first axial electrodes and a plurality of second axial electrodes. Each of the first axial electrodes is extended in a first direction. Each of the first axial electrodes includes a plurality of first inductive electrodes, a plurality of second inductive electrodes, and a plurality of first connecting lines. The first inductive electrodes and the second inductive electrodes are disposed alternatively along a first direction. Each of the first connecting lines is disposed between the first inductive electrodes and the second inductive electrodes. Each of the second axial electrodes is extended in a second direction. Each of the second axial electrodes has a plurality of hollow areas arranged along the second direction, and each of the first inductive electrodes is disposed within said hollow areas.

Abstract: The present disclosure provides a touch panel. The touch panel comprises a plurality of first electrode axes, a plurality of second electrode axes, and a plurality of traces. The first electrode axes and the corresponding second electrode axes are disposed at a same level, intertwined, and electrically isolated from each other. The traces connect to the first electrode axes and the second electrode axes from one direction. The present disclosure further provides a manufacturing method of a touch panel. The traces electrically connect to the electrode axes along only one direction, thereby effectively decreasing the area needed to form the traces surrounding the active region and increasing the active region area.

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 &closure provides a touch screen, wherein the touch screen includes: a protecting cover comprising a touch area and a border area surrounding the touch area; a black mask layer farmed on the border area; and a conductive assembly formed in the touch area, Wherein the conductive assembly is isolated from the black mask layer. By using the touch screen provided in the present disclosure, the problem of easy breaking of the conductive assembly Which leads to functional failure of a touch screen in the conventional technology can be solved. In addition, the present disclosure also provides a manufacturing method of the foregoing touch screen.