Abstract: A touch sensor device includes a touch sensing area including touch sensors sequentially disposed in a first direction extending away from an imaginary central point, in which an area of each touch sensors gradually increases as a distance thereof away from the imaginary center point increases, at least one of the touch sensors includes a first touch electrode and a second touch electrode adjacent to each other, a width of the first touch electrode decreases along a second direction, and a width of the second touch electrode increases along the second direction.

Abstract: A touch display panel and a method for driving the same are provided. The touch display panel includes a first substrate; a plurality of electrode units, a plurality of switches, a touch display circuit and a common lead disposed on the first substrate, wherein the common lead is adapted for transmitting a common signal, each electrode unit is connected with the touch display circuit through one of a plurality of first leads, each of the plurality of electrode units is connected with the common lead through one of a plurality of second leads, and each of the plurality of switches is disposed between one of the plurality of second leads and the common lead, so as to disconnect the common lead and the plurality of second leads during a touch sensing period, and connect the common lead and the plurality of second leads during a display period.

Abstract: The present specification provides a conductive structure body and a method for manufacturing the same.

Abstract: A touch panel includes a transparent substrate, a decorative layer formed on the transparent substrate, a first hard coat layer covering the transparent substrate and the decorative layer, a second hard coat layer formed on a surface of the transparent substrate, the surface being opposite to the first hard coat layer, and a plurality of first electrodes formed on a surface of the second hard coat layer. Electrodes and wirings are formed without being affected by unevenness caused by the decorative layer, so that pattern precision of the electrodes and the wirings is high.

Abstract: A touch panel, a method for fabricating the same and a touch display device are disclosed. The touch panel includes touch units, each of which includes: a capacitor having a first terminal connected to a first bias voltage; a first transistor having an amorphous silicon active layer, one of a source and a drain of the first transistor is connected to a third bias voltage and the other is connected to a second terminal of the capacitor; a second transistor having an oxide semiconductor active layer, a gate of the second transistor is connected to a scan line, one of a source and a drain of the second transistor is connected to the second terminal of the capacitor and the other is connected to a data line. The touch panel further includes a light-shielding layer; an aperture portion is disposed on a part of the light-shielding layer.

Abstract: A curved display apparatus providing an air touch input function including: a curved display including a concavely curved monitor to display a three-dimensional image; a three-dimensional filter unit having the same radius of curvature as the curved monitor and disposed in front of the curved monitor; a position input unit disposed in front of the three-dimensional filter unit and configured to detect a three-dimensional position according to a user's non-touch motion in a predetermined sensing region; and an image control unit configured to control a three-dimensional image displayed on the curved monitor by transmitting position information sensed through position input unit to the curved display, wherein air touch input through a user's non-touch motion is performed in a concave region of the curved display.

Abstract: An apparatus for determining location of a moveable object in relation to an input device includes an array of one or more piezoelectric micromachined ultrasonic transducer (pMUT) elements and a processor. The array is formed from a common substrate. The one or more pMUT elements include one or more transmitters and one or more receivers. The processor configured to determine a location of a moveable object in relation to an input device using sound waves that are emitted from the one or more transmitters, reflected from the moveable object, and received by the one or more receivers.

Abstract: The present invention provides a mutual capacitance multi-touch control electrode structure using single layer metal mesh, comprises: a metal conducting mesh layer; the metal conducting mesh layer comprises a plurality of driving line areas a plurality of sensing line areas and a plurality of shielding line area; the driving line areas are located at one sides of the shielding line areas, and the sensing line areas are located at the other sides of the shielding line areas; the driving line area, sensing line area and shielding line area respectively comprise a plurality of mesh units, and in each of the areas, the mesh units are mutually electrically connected, and one mesh unit adjacent to another mesh unit in adjacent areas are mutually electrically connected; one mesh unit comprises a plurality of mesh edges and nodes formed by two adjacent and connected mesh edges.

Abstract: An input device for capacitive touch sensing includes: a plurality of sensor electrodes, the plurality of sensor electrodes comprising: a plurality of receiver electrodes, a plurality of transmitter electrodes, and a reference receiver electrode; and a processing system. The processing system is configured to: drive a first transmitter electrode of the plurality of transmitter electrodes with a transmitter signal, receive a resulting signal via a receiver electrode of the plurality of receiver electrode, the resulting signal comprising effects corresponding to the transmitter signal, receive a reference signal via the reference receiver electrode, and determine a modified resulting signal based on the resulting signal received via the receiver electrode and the reference signal received via the reference receiver electrode.

Abstract: An input device includes an input surface and a first substrate mechanically coupled to the input surface. The first substrate includes a first plurality of sensor electrodes configured to detect an input force applied by an input object to the input surface. The input device further includes a conductive material disposed between the input surface and the first plurality of sensor electrodes. The conductive material shields the first plurality of sensor electrodes from effects of the input object in a sensing region of the input device. The input device further includes a second substrate mechanically coupled to the first substrate. The second substrate includes a second plurality of sensor electrodes configured to detect a location of an input object at the input surface.

Abstract: A mobile terminal device 1 includes a touch panel display that displays an image and receives an input operation of information by a user's finger, an operation lock control unit that controls stop of the display of an image and the receipt of an input operation on the touch panel display, and a coordinates and distance detection unit that detects proximity coordinates of the finger to the touch panel display and a level of a proximity distance in the proximity coordinates, and the operation lock control unit performs control to release the stop when a combination of the proximity coordinates and the level of the proximity distance is approximate to prestored pattern information.

Abstract: Disclosed herein include an input device, processing system and methods for touch sensing. In one embodiment, an input device is provided that includes a plurality of sensing elements arranged in a sensor pattern and a plurality of conductive routing traces. Each conductive routing trace is conductively paired with a respective one of the plurality of sensing elements. The sensor routing traces are configured to reduce an RC load of the corresponding paired sensing elements compared to a base RC load of a plurality of base electrodes arranged in a base pattern that is identical to the sensor pattern. Each base sensor electrode is conductively paired with a base routing trace. The base sensor electrode and paired base routing trace have a size that is identical to a size of the paired sensing elements and conductive routing trace. The base routing trace terminates at the base sensor electrode to which the base routing trace is paired.

Abstract: An array substrate, a display panel, and a display device are disclosed. The array substrate includes: multiple gate lines, multiple data lines and multiple touch lines. The multiple data lines and multiple touch lines are insulated from each other, and extend in parallel directions. Each of the touch lines includes multiple line conductive portions and multiple connectors. The line conductive portions are located in the same layer with the gate lines and each of the line conductive portions is located between two adjacent gate lines. The connectors are located in a different conductive layer from the line conductive portions and the connectors connect two adjacent line conductive portions through a via hole. The coupling capacitance between the line conductive portions and the touch electrode positionally corresponding thereto may be reduced, to ensure a high accuracy of a touch operation for the display device.

Abstract: [Problem] To prevent detachment of overcoat layer which covers at least a part of a terminal formed on a substrate. [Measure to solve the problem] According to one embodiment, a detection device includes a substrate, detection electrode, terminal formed of a metal material, lead, coating layer, conductive adhesion layer, and circuit board. The lead connects the electrode and the terminal. The coating layer covers the electrode and the lead, and partly covers the terminal. The adhesion layer covers a part of the terminal exposed from the coating layer and covers a part of the coating layer. The circuit board is connected to the terminal with the adhesion layer interposed therebetween. At least in an overlapping area where the conductive adhesion layer covers the coating layer, the metal material that forms the terminal includes a shape that the metal material is partly removed.

Abstract: A self-capacitive touch display panel and an array substrate thereof are provided in the disclosure. The array substrate includes a substrate, where gate lines, data lines, and a common electrode layer are provided on the substrate, and the gate lines and the data lines are insulated from each other and cross each other to define a plurality of pixel units arranged in an array; the pixel unit includes a pixel thin film transistor and a pixel electrode; the common electrode layer includes a plurality of touch-control units; a plurality of touch-control-driving thin film transistors are further provided on the substrate; and the touch-control unit is connected to drains of at least two touch-control-driving thin film transistors, the gates of the two touch-control-driving thin film transistors are connected to different gate lines, and the sources of the two touch-control-driving thin film transistors are connected to different data lines.

Abstract: A touch display panel is provided. The touch display panel includes a touch electrode layer and a plurality of first signal lines, where the touch electrode layer includes a plurality of first electrode blocks, and each of the first electrode blocks is electrically connected to a corresponding first signal line. The touch display panel further includes a plurality of second signal lines, where a projection region of the first electrode block in a direction perpendicular to the touch display panel includes at least one second signal line, and the second signal line is insulated from the first electrode block.

Abstract: A self-capacitive touch display panel, an array substrate therefor and a touch device are provided. The array substrate includes: a substrate; gate lines, data lines, and pixel units each including a pixel electrode and a pixel thin film transistor; multiple touch-driven thin film transistors each having a gate connected to one gate line and a first electrode connected to one data line; a common electrode layer including multiple touch display electrodes each electrically connected to second electrodes of at least two touch-driven thin film transistors connected to different gate lines; and a data line gating circuit controlling a specified data line to provide a specified pixel unit with a display data signal in a display stage and provide a specified pixel unit with a touch detection data signal in a touch stage.

Abstract: An array substrate for a self-capacitive touch display panel is provided. The array substrate includes a common electrode layer, a wire layer; an insulating layer, a first electrode block, a plurality of first interconnection structures and a plurality of second interconnection structure. The common electrode layer includes a plurality of touch electrodes, the wire layer includes a plurality of touch wires, and the insulating layer is disposed between the common electrode layer and the wire layer. Each touch electrode is electrically connected with a corresponding touch wire through the first interconnection structure. The first electrode block is in the same layer as the common electrode layer, and is separated and insulated from the plurality of touch electrodes. The first electrode block is electrically connected with the touch wire through the second interconnection structure. Accordingly problems associated with low quality display in conventional display panels are solved.

Abstract: One embodiment of a capacitive sensor array comprises a plurality of row sensor elements including a first row sensor element, a plurality of column sensor elements including a first column sensor element, and a plurality of unit cells, wherein a first unit cell contains an intersection between the first row sensor element and the first column sensor element, and wherein a ratio between 1) a boundary length between the first row sensor element and the first column sensor element within the first unit cell and 2) a perimeter of the first unit cell is greater than ?{square root over (2)}/2.

Abstract: A touch panel includes a touch sensor having a dielectric core layer disposed between first and second piezoelectric layers. Each piezoelectric layer comprises a poled piezoelectric polymer. The touch sensor further includes at least a first set of individually addressable electrodes disposed over the first piezoelectric layer and at least one second electrode disposed over the second piezoelectric layer. Circuitry is coupled to the first set of electrodes and the second electrode. The circuitry is configured to detect a change in an electrical signal of at least one electrode of the first set of electrodes referenced to the second electrode in response to a touch applied to the touch surface of the touch sensor.

Abstract: The present invention relates to a device for a portable user apparatus, including a portion which can be folded over the user apparatus, said foldable portion including at least two detection layers, each kept at a guard potential and including at least one capacitive detection electrode: a first of said layers being arranged to carry out a function of capacitive detection of at least one control object located on one side of said foldable portion; a second of said layers being arranged so as to carry out a function of capacitive detection of at least one control object located on the other side of said foldable portion, with a view to triggering a function in the user apparatus. The invention also relates to an apparatus provided with such an accessory device.

Abstract: A device includes an enclosure and logic. The enclosure includes a plurality of capacitive touch sensor arrays disposed at least on two of a top side, a bottom side, a left side, a right side, a front side, and a back side of the device. The enclosure also includes a first display on the front side of the device. The logic receives touch interaction information from the plurality of capacitive touch sensor arrays and initiates an action based at least in part on the touch interaction information.

Abstract: The disclosure provides an array substrate and a method for forming the same, a method for detecting a touch-control operation of a touch-control display apparatus. The array substrate includes: a self-capacitance touch-control layer, which also serves as a common electrode layer; the self-capacitance touch-control layer includes multiple first electrodes and multiple second electrodes, where the first electrodes are smaller in area than the second electrodes; the multiple first electrodes form multiple electrode groups each of which includes at least two of the first electrodes, where the electrode groups and the second electrodes are same in external shape. Accordingly, touch resolution and touch sensitivity of the array substrate may both reach a high level.

Abstract: In one embodiment, an apparatus for detecting a touch. The apparatus includes a touch sensor that includes a first plurality of electrode lines and a second plurality of electrode lines. The apparatus also includes a touch sensor controller coupled to the touch sensor. The touch sensor controller is operable to apply a respective voltage pulse simultaneously to each of the first plurality of electrode lines, measure a respective signal at each of the second plurality of electrode lines, and detect a touch based on the measurement of the respective signals.

Abstract: The embodiments of the present invention provide a touch control unit and fabricating method thereof as well as a flexible touch control display device. The touch control unit comprises at least one layer of modified carbon nanotube film, wherein the modified carbon nanotube film is obtained from modification of a carbon nanotube by a strongly oxidizing material.

Abstract: An input device includes a first substrate, a first light-emitting element unit, and a third electrode unit. The first substrate has a first surface and a second surface. The first light-emitting element includes a first electrode unit formed on the second surface, a second electrode unit formed in a layer different from that of the first electrode unit, and a luminescent layer electrically in contact with at least a part of the first electrode unit and a part of the second electrode unit, and formed between the first electrode unit and the second electrode unit. The third electrode unit is insulated from the first electrode unit and detects a change in an electric field between the first electrode unit and the third electrode unit depending on coordinates of a proximity object present at a position overlapping with the first surface in planar view.

Abstract: An input device includes a first substrate, a light-emitting element, and a third electrode unit. The first substrate has first and second surfaces. The light-emitting element unit includes: a first conductive electrode unit including first conductive layers; a second conductive electrode unit including second conductive layers each having a size overlapping with the first conductive layer in planar view; and luminescent layers conducted with at least a part of the first electrode unit, each provided between the first and second electrode units and conducted with the first conductive layer and the second conductive layer overlapping with the first conductive layer in planar view. The third electrode unit is insulated from the first conductive layers and detects a change in an electric field between the first conductive layers and the third electrode unit depending on coordinates of a proximity object at a position overlapping with the first surface in planar view.

Abstract: A touch sensing system includes a capacitive sense array. Each sensor has a unique location type. The system includes a capacitance measurement circuit coupled to the array, which measures capacitance changes at each sensor. The system also includes a memory device that stores three or more adjustment parameters. Each parameter corresponds to one or more location types, and is used in computing virtual sensor values. The system receives measured capacitance changes corresponding to a touch on the array and identifies a first sensor whose measured capacitance change is a local maximum. The system determines a location type of the first sensor. According to the location type, the adjustment parameters corresponding to the location type, and the measured capacitance changes, the system computes virtual sensor measurements. The system then computes a centroid of the touch using the measured capacitance changes and the virtual sensor measurements.

Abstract: According to one embodiment, a lateral-electric-field liquid crystal display device includes a light-emitting display layer including OLEDs and a driving circuit controlling light emission of the OLEDs, a moisture impermeable film provided to be laminated on the light-emitting display layer to prevent infiltration of moisture into the light-emitting display layer, an optical substrate provided separately from the moisture impermeable film and subjecting light from the light-emitting display region to optical processing, a first touch electrode group serving as one electrode group of touch electrodes and provided on a back surface of the optical substrate, and an extraction electrode group formed to be laminated on the moisture impermeable film, the extraction electrode group and the optical substrate have an overlapping part in plan view, and electrodes of the first touch electrode group being electrically connected to electrodes of the extraction electrode group in the overlapping part.

Abstract: A touch panel including upper and lower electrode substrates including upper and lower conductive layers, respectively; first and second electrodes respectively provided at both ends of the upper conductive layer in a first direction for causing an electric potential distribution in the first direction; third and fourth electrodes respectively provided at both ends of the lower conductive layer in a second direction perpendicular to the first direction for causing an electric potential distribution in the second direction; a flexible substrate provided to be connected to the lower electrode substrate or the upper electrode substrate; a first resistor portion electrically connected to either of the first or second electrode and formed at the upper electrode substrate or the flexible substrate; and a second resistor portion connected to either of the third or fourth electrode and formed at the lower electrode substrate or the flexible substrate.

Abstract: An electromagnetic touch three-dimensional grating comprising: an upper substrate and a lower substrate opposite to each other; a plurality of first strip electrodes located on a side of the lower substrate facing the upper substrate; and a plurality of second strip electrodes located on a side of the upper substrate facing the lower substrate and intersected with the first strip electrodes; wherein, during a touching period, the plurality of first strip electrodes are used as first electromagnetic touch electrodes, and the plurality of second strip electrodes are used as second electromagnetic touch electrodes; and during a three-dimensional displaying period, the plurality of first strip electrodes are used as first three-dimensional driving electrodes, and the second strip electrodes are used as a surface electrode, or, the plurality of second strip electrodes are used as second three-dimensional driving electrodes, and the first strip electrodes are used as a surface electrode.

Abstract: There are provided an array substrate, a touch display panel and a touch display device. The array substrate includes a common electrode layer and a driver circuit. The common electrode layer is divided into multiple self-capacitive electrodes that are connected to the driver circuit through multiple touch leads. Each touch lead is electrically connected to one of the self-capacitive electrodes via a via hole. The array substrate also includes a first groove or gap formed in the self-capacitive electrode in a region where a self-capacitive electrode overlaps a touch lead, and at least one of the self-capacitive electrodes corresponding to the via hole has at least a predetermined thickness.

Abstract: A fabrication method of a grating substrate, a grating substrate and a display device are provided. The fabrication method of the grating substrate, comprises: forming an array of comb-shaped, opaque touch electrodes and a plurality of first conductive bridges (3) on a base substrate, wherein the array of touch electrodes includes a plurality of first touch electrodes (1) and a plurality of second touch electrodes (2) which are disconnected from each other, and the plurality of first touch electrodes (1) in the array are connected together via the first conductive bridges (3); forming an insulating spacing layer (4) on the base substrate on which the array of touch electrodes and the plurality of first touch electrodes (1) are formed, the insulating spacing layer (4) covering the first conductive bridges (3); forming second conductive bridges (5) on the insulating spacing layer (4), the plurality of second touch electrodes (2) in the array being connected together via the second conductive bridges (5).

Abstract: The pixel circuit according to an embodiment of the present disclosure may include: a display driving module, arranged to compensate for the voltage threshold of the driving transistor by a data signal inputted by the data line and a first signal inputted by the first signal source in a time period, which is under a control of a first scanning signal inputted by the first scanning line, a second scanning signal inputted by the second scanning line, and a control signal inputted by the control line, so that a light-emitting driving signal of the OLED is independent of the voltage threshold of the driving transistor, within a fourth stage of the time period; and an in-cell touch detection module, arranged to detect a touch signal of a touch screen based on a variation of light caused by a touch operation in the time period, which is under the control of the first scanning signal and the control signal.

Abstract: An electronic device, including circuitry to detect, based on an output of a touch panel, a kind of finger that operates the touch panel; determine, based on the detected kind of the finger, an arrangement of display elements on a display formed on or integrally with the touch panel; and control the display to display the elements in accordance with the determined arrangement.

Abstract: A display comprising a display panel, wherein the display panel comprises two or more bonding areas; a driver configured to drive the display panel; a layer that provides a medium via which signals can propagate to and from the driver, and wherein the driver is mounted to the layer; and two or more flexible connectors, wherein the two or more flexible connectors provide communication paths between the display panel and the driver, and wherein a first end of each of the two or more flexible connectors connects to the display panel at a corresponding one of the two or more bonding areas, and wherein a second end of each of the two or more flexible connectors connects to the driver via the layer.

Abstract: A touch sensor integrated display device includes a plurality of common electrode blocks serving as touch-sensing regions and/or touch-driving regions. Conductive lines connected to the common electrode blocks are placed under the common electrode blocks and the pixel electrodes of the pixels, and they are routed across the active area, directly toward an inactive area where drive-integrated circuits are located. The conductive lines are positioned under one or more planarization layers, and are connected to the corresponding common electrode blocks via one or more contact holes.

Abstract: One embodiment of the present invention sets forth a method for displaying content on a display surface. The method includes receiving an input associated with a target location on the display surface corresponding to a region associated with a parent asset that resides at least partially within a render space and is displayed at a first display location on the display surface. The method further includes, in response to receiving the input, determining a first spawn location within the render space from one or more possible spawn locations that are available and are associated with the parent asset and the target location and causing a spawn asset to be displayed at a second display location on the display surface that corresponds to the first spawn location, wherein the first spawn location is closer to a first edge of the parent asset than any of the other one or more possible spawn locations.

Abstract: A touch display device includes a thin film transistor (TFT) array substrate and an opposite substrate opposite to the TFT array substrate. The TFT array substrate includes a plurality of gate lines, a plurality of data lines, and a plurality of TFTs. Each TFT includes a gate coupled to a corresponding gate line, a source coupled to a corresponding data line, a channel layer located corresponding with the gate, and a conductive layer located corresponding with the channel layer. The gate and the source are respectively coupled with the channel layer. The opposite substrate includes a common electrode layer. When a touch operation is applied to the touch display device, the opposite substrate is deformed to make the common electrode layer to couple with the conductive layer of at least one of the TFT, to detect the touch operation.

Abstract: One inventive aspect is an array substrate. The array substrate includes a plurality of touch leads, a common electrode layer, and a drive circuit. The common electrode layer is divided into a plurality of self-capacitive electrodes, and the self-capacitive electrodes are electronically connected to the drive circuit through the touch leads. The array substrate also includes a plurality of pixel units. Each touch lead is electronically connected to the self-capacitive electrode corresponding to the touch lead via a first via hole. At least one touch lead is continuous and passes through a whole column of the self-capacitive electrodes. In a direction perpendicular to the array substrate, a projection of the self-capacitive electrode covers projections of a plurality of pixel units. In addition, along a direction of the touch leads, an interval between two adjacent first via holes is greater than or equal to a length of two pixel units.

Abstract: An array substrate and a liquid crystal display panel are provided. The array substrate includes: multiple thin film transistors arranged in an array; a first flat layer on the multiple thin film transistors; a touch wire layer arranged on the first flat layer, where the touch wire layer includes multiple touch wires; and a second flat layer arranged on the touch wire layer. The array substrate addresses issues of an uneven surface of the film layer due to the arrangement of the touch wires in the touch wire layer, thereby eliminating negative effects on subsequent processes due to the arrangement of the touch wires. The touch wires are arranged between two flat layers, and an insulating layer adjacent to the touch wire layer is omitted. Only one insulating layer is arranged between the common electrode and the pixel electrode.

Abstract: An array substrate and a drive method thereof, a touch control display and a display apparatus are provided. An array substrate includes, in part, a gate line layer configured with a multitude of gate lines, and a common electrode layer configured with a multitude of common electrodes. The common electrodes further operate as touch control electrodes with a projection on the array substrate along a direction substantially perpendicular to the array substrate. The projection covers n gate lines, where n is a positive integral number. At least one of the touch control electrodes comprises n sub common electrodes each having a projection on the array substrate along the direction substantially perpendicular to the array substrate covering one of the gate lines. Accordingly, less flicks or stripes appear on the display.

Abstract: There are provided an array substrate, a touch display panel and a touch display device according to the disclosure. The array substrate includes: multiple gate lines and multiple data lines; multiple pixel units surrounded by the gate lines and the data lines; a common electrode layer divided into multiple electrode units, where each electrode unit includes at least two electrode blocks with a cross area where the at least two electrode blocks are chimeric with each other, the length of the cross area in a direction parallel to the data lines is greater than or equal to the length of an area where drive signals overlap in the direction parallel to the data lines, the area where the drive signals overlap includes the gate lines the drive signals for which overlap and the pixel units electronically connected to the gate lines.

Abstract: An array substrate is provided. The array substrate includes a display region and a non-display region; the display region includes a first display region, a second display region, and a third display region arranged in sequence; the non-display region includes a first control module and a second control module; the display region is configured with a plurality of electrode blocks; the electrode blocks located in the first display region are connected with the first control module; the electrode blocks located in the third display region are connected with the second control module; the second display region includes at least one column of the electrode blocks, regarding each of the at least one column, some of the electrode blocks are connected with the first control module, and others are connected with the second control module. Accordingly, vision disparity can be avoided by alternately connecting the electrode blocks with different control modules.

Abstract: An array substrate and a display panel are provided. The array substrate includes: a plurality of common electrodes, a first and a second signal line, wherein a common electrode insulated from the first signal line has a first slit in a part facing to the first signal line, a common electrode insulated from the second signal line has a second slit in a part facing to the second signal line, a resistance of the first signal line is greater than that of the second signal line, there are a first deviation distance between a projection of the first signal line and a middle position of the first slit and a second deviation distance between a projection of the second signal line and a middle position of the second slit, and the first deviation distance is smaller than the second deviation distance. Display performance and touch performance can be improved.

Abstract: It is provided an array substrate and a display device. The array substrate includes a first substrate. Multiple first common electrodes and multiple second common electrodes are arranged above the first substrate, where the first and second common electrodes are configured to serve as common electrodes in a display phase and serve as touch sensing electrodes in a touch sensing phase. The first common electrodes are arranged in a different film layer from the second common electrodes, and projections of first common electrodes on the first substrate are adjacent to or overlap with projections of second common electrodes adjacent to the first common electrodes on the first substrate in a first direction.

Abstract: An electronic device, a touch display panel and a touch display substrate are provided. The touch display substrate includes a substrate plate and a common electrode layer disposed on the substrate plate, where the common electrode layer includes multiple touch display electrodes insulated from each other, and the touch display electrodes are arranged in an array, and multiple touch display wires insulated from each other, where the touch display wires and the touch display electrodes are arranged and connected electrically according to a one-to-one correspondence. Areas of at least two touch display electrodes increase gradually in a first direction, and the first direction is an extending direction of the touch display wire and extends from a contact point between the touch display wire and the touch display electrode to an edge of the substrate plate.

Abstract: A touch display panel structure, a method for forming the touch display panel structure, and a touch display device are provided. The touch display panel structure includes: a substrate, scan lines each including a plurality of scan line segments, touch electrode lines each disposed at an interval between adjacent scan line segments; a first dielectric layer and data lines; a second dielectric layer and a first interconnection structure; a first via hole through the first dielectric layer and the second dielectric layer; a third dielectric layer a common electrode layer; a second via hole through the first dielectric layer and the second dielectric layer; and a plurality of third via holes through the third dielectric layer, wherein each touch electrode is connected to a touch electrode line via the second via hole and the third via hole.

Abstract: An array substrate, a display panel and a display device are provided. The array substrate includes: multiple gate lines and multiple data lines, where the gate lines are insulated from and intersect with the data lines, which define multiple pixel units; a pixel electrode layer, where the pixel electrode layer includes multiple pixel electrodes, and the pixel electrodes are disposed in the pixel units; a common electrode layer, where the common electrode layer includes multiple common electrodes, and the common electrode serves as a touch electrode; and multiple auxiliary electrodes, where the auxiliary electrode is electrically connected to the touch electrode, is disposed in a different conductive layer from the pixel electrode, and overlaps with at least one of the pixel electrodes. In this way, the storage capacitance is increased, and the display device has an improved display effect as compared with the conventional technology.

Abstract: According to one embodiment, a sensor-equipped display device includes a display panel including pixel electrodes and common electrodes, a cover member opposed to the display panel, a polarizer located between the display panel and the cover member, and a first detection module located between the polarizer and the cover member. The first detection module includes a first detection electrode including dot-like openings and a dummy module including dot-like dummy electrodes.