KR20230090827A - Touch sensing apparatus - Google Patents

Abstract

The embodiment of the present invention relates to a touch sensing device which senses a touch by a touch electrode disposed on each display panel in a multi-display panel. The present invention provides a technology for confirming touch coordinates of a multi-display panel by collecting data sensed from a plurality of touch controllers connected to each display panel from a master touch controller. The touch sensing device includes: a touch driver which supplies a driving signal to the plurality of touch electrodes disposed on the first display panel; and a data processing unit which receives sensing values sensed from the plurality of touch electrodes disposed on the first display panel.

Description

Touch sensing device {TOUCH SENSING APPARATUS}

The present embodiment relates to a touch sensing device that senses a touch by touch electrodes disposed on a display panel in a multi-display environment.

Recently, touch functions are widely used in display panels ranging from small electronic devices (eg, smart phones) to large-sized electronic devices (eg, TVs, kiosks, or electronic blackboards). In this case, most of the display panel is implemented as a flat panel display device such as a liquid crystal display device, and the touch function is implemented as a touch panel combined with the display panel.

The touch panel refers to a transparent switch panel having a function of operating a device or executing a program according to a user pressing text, an image, or an icon. The touch panel may be configured to perform capacitive touch recognition, and as an example of a touch panel implementing capacitive touch recognition, a “mutual capacitance touch sensing device” has been disclosed as “US Patent Publication No. US 2009/0091551”. there is. A general touch panel has a configuration independent of the display panel and is manufactured separately and combined with the display panel.

Meanwhile, in the touch panel, touch electrodes (TE) (or electrodes; EL) of a certain size may be arranged according to a specific arrangement method (or specific pattern). For example, the size of a display device or a touch panel Touch electrodes having a certain size according to the size of may be arranged in the form of an N×M matrix When a specific object (eg, a hand or an electronic pen) contacts a plurality of touch electrodes disposed on the touch panel, each The touch electrode can sense the contact of the object, and the touch sensing device can determine the touched position (or touch coordinates) of the object based on the position of the touch electrode where the contact of the object is sensed.

As the demand for a large display increases, a multi-display device that connects several display panels to form one large display panel is being implemented. A signal sensed through touch electrodes disposed on each display panel constituting the multi-display device is input to a touch sensing device (eg, a touch micro controller unit (MCU) or touch controller) corresponding to each display panel, and each The touch sensing device may generate touch coordinates for a corresponding display panel based on the sensed signal. Meanwhile, since touch sensing devices individually connected to each display panel in the multi-display device generate individual touch data (eg, touch coordinates), when a boundary area between adjacent display panels is touched, erroneous touch data (eg, touch coordinates) is touched. touch coordinates) may be confirmed. In addition, since each touch sensing device individually generates touch data, a disconnection may occur when, for example, a drag or drawing operation starting from a touch on a first display panel to an adjacent second display panel occurs.

Against this background, an object of the present embodiment is, in one aspect, to provide a touch sensing device capable of generating accurate touch coordinates when touching a boundary area between display panels constituting a multi-display.

In order to achieve the above object, in one aspect, the present embodiment, a touch driver for supplying a driving signal to a plurality of touch electrodes disposed on the first display panel; and a data processor configured to receive sensing values sensed from the plurality of touch electrodes disposed on the first display panel, wherein the data processor includes a first area of the first display panel adjacent to a second display panel. A first sensing value sensed from touch electrodes disposed in an area and a second sensing value sensed from touch electrodes disposed in a second area excluding the first area are checked, and Based on the second sensing values sensed from corresponding touch electrodes, touch coordinates of the second area are identified, and the first sensing values sensed from touch electrodes corresponding to the first area and the second Provided is a touch sensing device that transmits touch coordinates of an area to an external device.

In another aspect, according to the present embodiment, a first sensing value sensed from a first touch sensing device connected to a first display panel and touch electrodes disposed in an area of the first display panel adjacent to the second display panel. Receive a second sensing value sensed from touch electrodes disposed in an area adjacent to the first display panel among areas of the second display panel, from a second touch sensing device connected to the second display panel; a data processing unit that checks touch coordinates of the first and second display panel areas based on the first and second sensing values; and a data transmitter configured to transmit touch coordinates of the region of the first display panel and the region of the second display panel to an external device.

As described above, according to the present embodiment, by allowing one master touch sensing device to process the sensing values of the touch sensing devices connected to each display panel in the multi-display, accurate touch coordinates when touching the boundary area between the display panels. can create

Further, according to the present embodiment, the number of communication lines connected to the processor can be reduced by allowing one master touch sensing device to process the sensing values of the touch sensing devices connected to each display panel in the multi-display.

1 is a configuration diagram of a display device including a touch sensing device according to an exemplary embodiment.
2 is a diagram illustrating an internal configuration of a pixel when a touch electrode is used as a common voltage electrode according to an exemplary embodiment.
3 is a diagram illustrating that a touch sensing unit drives a touch electrode according to an exemplary embodiment.
4 is an exemplary diagram illustrating a base capacitance according to an exemplary embodiment.
5 is an example diagram of data corresponding to a touch electrode according to an exemplary embodiment.
6 is a diagram illustrating a touch pattern according to an exemplary embodiment.
7 is a diagram illustrating connections to each display panel of a multi-display device according to an exemplary embodiment.
8 is a diagram showing connections to each display panel of a multi-display device according to an exemplary embodiment.
9 is a diagram illustrating division of regions in each display panel of a multi-display device according to an exemplary embodiment.
10 is a diagram illustrating touch electrodes disposed on each display panel of a multi-display device according to an exemplary embodiment.
11 is a configuration diagram of a touch controller according to an exemplary embodiment.
12 is a configuration diagram of a master touch controller according to an embodiment.

1 is a configuration diagram of a display device including a touch sensing device according to an embodiment of the present invention. As shown in FIG. 1, the display device 100 according to an embodiment of the present invention performs a display function and a touch sensing function, and is a liquid crystal display (LCD) or an organic light emitting diode display (Organic Light Display). It can be implemented as a flat panel display such as an Emitting Diode (OLED). Embodiments described below illustrate an LCD, but the present invention is not limited thereto and may be equally or similarly applied to a display based on LED or OLED.

In one embodiment, the display device 100 according to the present invention includes a capacitive touch screen integrally implemented therein to sense a touch by a contact of a conductive object such as a finger or an active pen. can include Such a touch screen may be configured in a form independent of a display panel for display implementation, or may be embedded in a pixel array of a display panel.

As shown in FIG. 1 , the display device 100 according to an embodiment of the present invention includes a panel driving device 110, a panel 120 (eg, a display panel or a touch panel), and a touch sensing unit 140 ( For example, it includes a touch sensing device, a touch sensing circuitry, a touch controller, or a touch micro controller unit (MCU).

The panel 120 displays an image of a predetermined gray level or receives a touch input by a hand (or finger) or an active pen (or electronic pen). The panel 120 may be a display panel having an in-cell touch type structure using a capacitance method. In one embodiment, the panel 120 may be an in-cell touch type display panel using a self capacitance method or an in-cell touch type display panel using a mutual capacitance method. Hereinafter, for convenience of explanation, it will be assumed that the panel 120 is a self-capacitance in-cell touch type display panel.

The panel 120 may operate in a display mode and a touch sensing mode. The panel 120 may display an image using light emitted from the backlight unit during the display mode and may serve as a touch panel for touch sensing during the touch sensing mode.

The panel driving device 110 may include a data driver 112 , a gate driver 114 , and a timing controller 116 . Each of the data driving unit 112 , the gate driving unit 114 , and the touch sensing unit 140 may drive at least one component included in the panel 120 .

The data driver 112 drives the data lines DL (eg, D1 to Dn) connected to the pixel (P), and the gate driver 114 drives the gate line GL (connected to the pixel P). Example: G1 to Gm) can be driven. Also, the touch sensing unit 140 may drive an electrode (EL) or a touch electrode (TE) disposed on the panel 120 .

The data driver 112 may supply a data voltage to the data line DL to display an image on each pixel P of the panel 120 . The data driver 112 may include at least one data driver integrated circuit, and the at least one data driver integrated circuit may be a tape automated bonding (TAB) method or a chip on glass (COG) method. It may be connected to a bonding pad of the panel 120 in a glass method, or may be directly formed on the panel 120, or may be integrated and formed on the panel 120 in some cases. Also, the data driver 112 may be implemented in a Chip On Film (COF) method.

The gate driver 114 may supply a scan signal to the gate line GL in order to turn on or off the transistor located in each pixel P. The gate driver 114 may be located on only one side of the panel 120 as shown in FIG. 1 or may be divided into two and located on both sides of the panel 120 according to a driving method. In addition, the gate driver 114 may include at least one gate driver integrated circuit, and the at least one gate driver integrated circuit is a tape automated bonding (TAB) method or a chip on glass (COG) method. It may be connected to the bonding pad of 120, implemented as a GIP (Gate In Panel) type and directly formed on the panel 120, or may be integrated and formed on the panel 120 in some cases. In addition, the gate driver 114 may be implemented in a Chip On Film (COF) method.

The panel 120 may include only a touch screen panel (TSP) and may further include a display panel. Here, the touch panel and the display panel may share some components with each other. For example, a touch electrode TE for sensing a touch in a touch panel may be used as a common voltage electrode supplied with a common voltage in a display panel. In view of the fact that some components of the display panel and the touch panel are shared with each other, such a panel 120 is sometimes referred to as an integrated panel, but the present invention is not limited thereto. In addition, although an in-cell type panel is known as a form in which a display panel and a touch panel are integrally combined, this is only one example of the above-described panel 120, and a panel to which the present invention is applied is such an in-cell (in-cell) type panel. Cell) type panel is not limited.

Meanwhile, a plurality of touch electrodes TE may be disposed on the panel 120 , and the touch sensing unit 140 may drive the touch electrodes TE using a driving signal. Also, the touch sensing unit 140 may generate a sensing value for the touch electrode TE according to a response signal formed on the touch electrode TE in response to the driving signal. In addition, the touch sensing unit 140 may calculate touch coordinates by using sensing values of the plurality of touch electrodes TE disposed on the panel 120, and the calculated touch coordinates may be used by another device (eg, a host). or a controller or processor) and may be utilized.

2 is a diagram illustrating an internal configuration of a pixel when a touch electrode is used as a common voltage electrode according to an exemplary embodiment. Referring to FIG. 2 , the pixel P may include a transistor (eg, TFT), a liquid crystal (LC), and a common voltage electrode (VCOM). A gate terminal of the transistor TFT may be connected to the gate line GL, a drain terminal may be connected to the data line DL, and a source terminal may be connected to the liquid crystal LC.

When the scan signal SCAN corresponding to the turn-on voltage is supplied to the gate terminal through the gate line GL, the drain terminal and the source terminal of the transistor TFT are conducted and the data voltage Vdata is supplied to the liquid crystal LC. It can be. A common voltage may be supplied to the common voltage electrode VCOM, and the brightness of the pixel P may be adjusted while the liquid crystal LC is controlled according to a difference between the common voltage and the data voltage Vdata.

Meanwhile, the common voltage electrode VCOM may be the same electrode as the touch electrode TE driven by the touch sensing unit (see 140 in FIG. 1) described with reference to FIG. Examples are not limited thereto.

3 is a diagram illustrating that a touch sensing unit drives a touch electrode according to an exemplary embodiment. Referring to FIG. 3 , the touch sensing unit 140 drives the touch electrode TE using the driving signal Stx and generates a response signal Srx formed on the touch electrode TE in response to the driving signal Stx. Accordingly, a touch or proximity of the external object OBJ to the panel may be sensed.

At this time, the touch sensing unit 140 may adopt a capacitive touch method that recognizes the proximity or touch of the object OBJ by sensing the capacitance or capacitance change of the touch electrode TE.

Such a capacitive touch method may be divided into, for example, a mutual capacitance touch method and a self capacitance touch method. In the mutual capacitance touch method, which is a type of capacitive touch method, a driving signal Stx is applied to one touch electrode and another touch electrode mutually coupled with one touch electrode is sensed. In this mutual capacitance touch method, a value sensed by another touch electrode changes depending on the touch or proximity of an object (OBJ) such as a finger or a pen. Touch coordinates and the like can be detected.

In the self-capacitance touch method, which is another kind of capacitive touch method, a driving signal Stx is applied to one touch electrode and then the corresponding one touch electrode is sensed again. In this self-capacitance touch method, a value sensed by a corresponding touch electrode varies according to the touch or proximity of an object (OBJ) such as a finger or a pen. Touch coordinates and the like can be detected. In this self-capacitance touch method, the touch electrode for applying the driving signal Stx and the touch electrode for sensing are the same.

An embodiment can be applied to both the mutual capacitance touch method and the self capacitance touch method. In some examples below, a case in which an embodiment is applied to a self-capacitive touch method will be described for convenience of description.

4 is an exemplary diagram illustrating a base capacitance according to an exemplary embodiment. Referring to FIG. 4 , when there is no touch or proximity of an external object, base capacitance Ce may be formed in the touch electrode TE. Meanwhile, the touch sensing unit 140 may supply the driving signal Stx to the touch electrode TE and receive the response signal Srx from the touch electrode TE. Further, the touch sensing unit 140 may check a sensed value corresponding to the capacitance of the touch electrode TE by using the response signal Srx. This sensed value is a base capacitance corresponding to the base capacitance Ce. If it is different from the sensed value, the touch sensing unit 140 may recognize that an external object approaches or touches the touch electrode TE.

5 is an example diagram of data corresponding to a touch electrode according to an exemplary embodiment. The touch image 500 shown in FIG. 5 may refer to a table displaying sensing values corresponding to positions of touch electrodes. Each sensing value displayed in the table may be referred to as row data.

Referring to the touch image shown in FIG. 5 , according to the touch of the external object OBJ, the sensing value of the third touch electrode on the X line represents the highest value at 182, and the sensing value decreases as the distance from the corresponding touch electrode increases. can know The sensing values of the line X of FIG. 5 may represent a continuous curve, and the touch sensing unit 140 may calculate touch coordinates by inputting several sensing values identified along a certain line into a specific model or algorithm. For example, the touch sensing unit 140 may calculate first touch coordinates in the direction of the X line by substituting three or more sensed values identified along the X line into a predetermined function, for example, a Gaussian curve. Similarly, the second touch coordinates in the Y-line direction can be calculated. When touch coordinates are calculated for the two orthogonal directions, touch coordinates on a plane may be calculated. As an algorithm for calculating touch coordinates based on each sensed value displayed in the table, various algorithms may be applied. The touch sensing unit 140 may generate high-precision touch coordinates based on the various algorithms.

6 is a diagram illustrating a touch pattern according to an exemplary embodiment. Referring to FIG. 6 , the touch electrodes TE disposed on the panel 120 may form a matrix-type touch pattern 610 as shown in FIGS. 1 and 6 . Each touch electrode TE may have a quadrangular shape, but embodiments described later are not limited thereto.

In the touch pattern 610 , the touch electrodes TE may be arranged in a constant size and at regular intervals according to each row and column. For example, when the touch electrodes TE are disposed in the touch pattern 610 to form four rows and four columns, a total of 16 touch electrodes TE may be disposed. The touch electrodes TE having a 4*4 arrangement in the touch pattern 610 may be referred to as one unit array for convenience, but are not limited thereto. Depending on the size of the display device or the touch panel, the unit array is repeatedly formed along the horizontal axis and/or the vertical axis, so that touch electrodes TE suitable for the corresponding size may be disposed.

A sensing value sensed by each touch electrode TE in the touch pattern 610 may be input to the touch sensing unit 140 . For example, the touch sensing unit 140 may obtain 16 sensing values from 16 touch electrodes TE included in the unit array. The touch sensing unit 140 may determine a location where an object is touched or whether or not an object is touched based on a sensing value for each touch electrode TE.

Hereinafter, embodiments of a method of generating touch coordinates in a multi-display device including a plurality of display modules will be described with reference to FIGS. 7 to 12 .

7 is a diagram illustrating connections to each display panel of a multi-display device according to an exemplary embodiment. Referring to FIG. 7 , a multi-display device may include a plurality of display panels 120 . For example, the multi-display device may include a first display panel 120a, a second display panel 120b, a third display panel 120c, and a fourth display panel 120d. Although FIG. 7 illustrates a multi-display device in which four display panels 120a, 120b, 120c, and 120d are disposed adjacent to each other in a 2×2 form, the multi-display device according to the present embodiment is shown in FIG. It is not limited to a given form. For example, the multi-display device according to the present embodiment may arrange two display panels in a 1×2 or 2×1 shape, including 2×3, 3×2, 2×4 or 4×2 shapes. Thus, it may include various forms of M×N (where M and N are natural numbers).

Each of the plurality of display panels 120a, 120b, 120c, and 120d may be connected to a corresponding touch controller 710. For example, the first display panel 120a may be connected to the first touch controller 710a, the second display panel 120b may be connected to the second touch controller 710b, and the third display panel 120c may be connected to It can be connected to the third touch controller 710c, and the fourth display panel 120d can be connected to the fourth touch controller 710d. Each of the touch controllers 710a, 710b, 710c, and 710d may include at least some of the functions of the touch sensing unit 140 of FIG. 1 described above, or may be substituted for the touch sensing unit 140 . Each of the touch controllers 710a, 710b, 710c, and 710d may be referred to as a touch sensing device, a touch sensing circuitry, or a touch microcontroller unit (MCU).

Each of the touch controllers 710a, 710b, 710c, and 710d includes an electrode (EL) or a touch electrode (TE) disposed on each display panel 120a, 120b, 120c, and 120d (hereinafter, for convenience of description). The electrode EL or the touch electrode TE will be referred to as a touch electrode) can be driven. For example, the first touch controller 710a may drive the touch electrodes by supplying a driving signal to the touch electrodes disposed on the first display panel 120a. Also, the first touch controller 710a may generate a sensing value for the touch electrode TE according to a response signal formed in the touch electrode disposed on the first display panel 120a in response to the driving signal. Also, the first touch controller 710a may calculate touch coordinates using sensed values of a plurality of touch electrodes disposed on the first display panel 120a. The touch coordinates calculated by the first touch controller 710a or the touch data corresponding to the touch coordinates may be transmitted to and utilized by an external device (eg, a host, controller, or processor). For example, the first touch controller 710a may be connected to the external device through Universal Serial Bus (USB) communication and transmit the touch coordinates or touch data corresponding to the touch coordinates to the external device.

Similarly, the second touch controller 710b can drive the touch electrodes by supplying driving signals to the touch electrodes disposed on the second display panel 120b. Also, the second touch controller 710b may generate a sensing value for the touch electrode TE according to a response signal formed in the touch electrode TE disposed on the second display panel 120b in response to the driving signal. there is. Also, the second touch controller 710b may calculate touch coordinates using sensed values of a plurality of touch electrodes disposed on the second display panel 120b. The touch coordinates calculated by the second touch controller 710b or the touch data corresponding to the touch coordinates may be transmitted to and utilized by the external device (eg, a host, controller, or processor). For example, the second touch controller 710b may be connected to the external device through Universal Serial Bus (USB) communication and transmit the touch coordinates or touch data corresponding to the touch coordinates to the external device. Operations of the third touch controller 710c and the fourth touch controller 710d may be identical to or similar to those of the aforementioned first touch controller 710a and second touch controller 710b, so detailed descriptions thereof will be omitted. do. The first touch controller 710a, the second touch controller 710b, the third touch controller 710c, and the fourth touch controller 710d may be simultaneously connected to one external device. The external device multi-functions based on touch coordinates or touch data transmitted from the first touch controller 710a, the second touch controller 710b, the third touch controller 710c, and the fourth touch controller 710d, respectively. A touch input on the display device may be confirmed.

As an example, when a touch is input to the boundary between the first display panel 120a and the second display panel 120b, the first touch controller 710a connected to the first display panel 120a and the Each of the second touch controllers 710b connected to the second display panel 120b may sense a touch. Accordingly, the first touch controller 710a and the second touch controller 710b may individually generate touch coordinates or touch data. The first touch controller 710a maps a first identification number (eg, touch identification (ID)) to the touch coordinates or touch data and transmits the mapping to an external device, and the second touch controller 710b maps the touch coordinates Alternatively, the second identification number may be mapped to touch data and transmitted to an external device. An external device may check the touch coordinates or touch data identification numbers received from the first touch controller 710a and the second touch controller 710b and recognize them as separate touch inputs.

As another example, when a user performs a dragging or drawing operation from the first display panel 120a to the second display panel 120b, the first touch controller 710a and the second touch controller 710b as described above. ) individually checks the sensed touch in the boundary area between the first display panel 120a and the second display panel 120b and generates touch coordinates or touch data, so that dragging or drawing may be disconnected.

7, the first touch controller 710a, the second touch controller 710b, the third touch controller 710c, and the fourth touch controller 710d are one. As they are simultaneously connected to external devices, as many communication lines as the number of display panels may be required.

8 is a diagram showing connections to each display panel of a multi-display device according to an exemplary embodiment. Referring to FIG. 8 , a multi-display device may include a plurality of display panels 120 . For example, the multi-display device may include a first display panel 120a, a second display panel 120b, a third display panel 120c, and a fourth display panel 120d. Although FIG. 8 illustrates a multi-display device in which four display panels 120a, 120b, 120c, and 120d are arranged adjacent to each other in a 2×2 form, the multi-display device according to the present embodiment is shown in FIG. It is not limited to a given form. For example, the multi-display device according to the present embodiment may arrange two display panels in a 1×2 or 2×1 shape, including 2×3, 3×2, 2×4 or 4×2 shapes. Thus, it may include various forms of M×N (where M and N are natural numbers).

Each of the plurality of display panels 120a, 120b, 120c, and 120d may be connected to a corresponding touch controller 710. For example, the first display panel 120a may be connected to the first touch controller 710a, the second display panel 120b may be connected to the second touch controller 710b, and the third display panel 120c may be connected to It can be connected to the third touch controller 710c, and the fourth display panel 120d can be connected to the fourth touch controller 710d. Each of the touch controllers 710a, 710b, 710c, and 710d may include at least some of the functions of the touch sensing unit 140 of FIG. 1 described above, or may be substituted for the touch sensing unit 140 . Each of the touch controllers 710a, 710b, 710c, and 710d may be referred to as a touch sensing device, a touch sensing circuitry, or a touch microcontroller unit (MCU).

According to an embodiment, each of the touch controllers 710a, 710b, 710c, and 710d may be connected to a master touch controller 800 through communication. For example, each of the touch controllers 710a, 710b, 710c, and 710d may be connected to the master touch controller 800 through Serial Peripheral Interface (SPI) communication. The master touch controller 800 may collect data transmitted from each of the touch controllers 710a, 710b, 710c, and 710d. The master touch controller 800 may communicate with each of the touch controllers 710a, 710b, 710c, and 710d in a master-slave relationship, but the terminology is not intended to limit its function.

According to an embodiment, each of the touch controllers 710a, 710b, 710c, and 710d may drive a touch electrode disposed on each display panel 120a, 120b, 120c, and 120d. For example, the first touch controller 710a may drive the touch electrodes by supplying a driving signal to the touch electrodes disposed on the first display panel 120a. The second touch controller 710b may drive the touch electrodes by supplying driving signals to the touch electrodes disposed on the second display panel 120b. The third touch controller 710c may drive the touch electrodes by supplying driving signals to the touch electrodes disposed on the third display panel 120c. The fourth touch controller 710d may drive the touch electrodes by supplying a driving signal to the touch electrodes disposed on the fourth display panel 120d.

According to an embodiment, the first touch controller 710a may be applied to a display panel disposed adjacent to the area of the first display panel 120a (eg, the second display panel 120b or the third display panel 120c). ) and the adjacent area or boundary area (hereinafter, the area adjacent to other display panels in the area of each display panel 120 is referred to as a 'first area' for convenience of explanation). and a touch electrode disposed in an area other than the adjacent area (first area) (hereinafter, for convenience of description, an area of each display panel 120 that is not adjacent to another display panel is referred to as a 'second area'). A second sensed value sensed from s can be checked, and the first area and the second area can be processed differently. For example, the first touch controller 710a may be applied to an area of the first display panel 120a adjacent to an adjacent display panel (eg, the second display panel 120b or the third display panel 120c). A first sensing value sensed from the touch electrodes disposed in the first area of , may be transmitted to the master touch controller 800 . The first touch controller 710a controls the second area based on the second sensing values sensed from the touch electrodes disposed in the second area of the first display panel 120a except for the first area. Touch coordinates or touch data (hereinafter referred to as 'touch coordinates' for convenience of explanation) may be checked, and the checked touch coordinates may be transmitted to the master touch controller 800 . Various algorithms may be applied to a method of generating touch coordinates for the second area based on the second sensed value. For example, as described above in the description of FIG. 5 , touch coordinates may be calculated by substituting the second sensing value into a predetermined function, for example, a Gaussian curve.

The second touch controller 710b, in the same way as the first touch controller 710a, is disposed adjacent to a display panel (eg, the first display panel 120a or A first sensing value sensed from touch electrodes disposed in an area adjacent to the fourth display panel 120d or in a boundary area (first area), and an area (second area) excluding the adjacent area (first area) A second sensing value sensed from the touch electrodes disposed on may be checked, and the first area and the second area may be differently processed. For example, the second touch controller 710b may be applied to an area of the second display panel 120b adjacent to an adjacent display panel (eg, the first display panel 120a or the fourth display panel 120d). A first sensing value sensed from the touch electrodes disposed in the first area of , may be transmitted to the master touch controller 800 . The second touch controller 710b controls the second area based on the second sensing values sensed from the touch electrodes disposed in the second area excluding the first area of the second display panel 120b. The touch coordinates may be checked, and the checked touch coordinates may be transmitted to the master touch controller 800 .

The third touch controller 710c is a display panel disposed adjacent to the area of the third display panel 120c (eg, Sensed values (hereinafter, for convenience of description, each display panel 120 A value sensed in each first area of ) is referred to as a 'first sensing value') and a sensing value sensed from touch electrodes disposed in an area (second area) excluding the adjacent area (first area) ( Hereinafter, for convenience of description, a value sensed in each second region of each display panel 120 is referred to as a 'second sensed value'), and the first region and the second region may be processed differently. . For example, the third touch controller 710c may be applied to an area of the third display panel 120c adjacent to an adjacent display panel (eg, the first display panel 120a or the fourth display panel 120d). A first sensing value sensed from the touch electrodes disposed in the first area of , may be transmitted to the master touch controller 800 . The third touch controller 710c controls the second area based on the second sensing values sensed from the touch electrodes disposed in the second area excluding the first area of the third display panel 120c. The touch coordinates may be checked, and the checked touch coordinates may be transmitted to the master touch controller 800 .

The fourth touch controller 710d is a region of the fourth display panel 120d in the same way as the first touch controller 710a, the second touch controller 710b, or the third touch controller 710c. A first sensing value sensed from touch electrodes disposed in an area adjacent to the adjacent display panel (eg, the second display panel 120b or the third display panel 120c) or in a boundary area (first area) and a second sensing value sensed from touch electrodes disposed in an area (second area) other than the adjacent area (first area), and processing the first area and the second area differently. there is. For example, the fourth touch controller 710d may be applied to an area of the fourth display panel 120d adjacent to an adjacent display panel (eg, the second display panel 120b or the third display panel 120c). A first sensing value sensed from the touch electrodes disposed in the first area of , may be transmitted to the master touch controller 800 . The fourth touch controller 710d controls the second area based on the second sensing values sensed from the touch electrodes disposed in the second area excluding the first area of the fourth display panel 120d. Touch coordinates may be transmitted to the master touch controller 800 .

According to an embodiment, the master touch controller 800 generates a sensing value (eg, raw data) for a first area corresponding to an area adjacent to each other from each of the touch controllers 710a, 710b, 710c, and 710d. ) may be received, and touch coordinates may be received for a second area corresponding to areas that are not adjacent to each other.

According to an embodiment, the master touch controller 800 is disposed in an area adjacent to the second display panel 120b among areas of the first display panel 120a received from the first touch controller 710a. From the sensed values from the touch electrodes and the touch electrodes disposed in the area adjacent to the first display panel 120a among the areas of the second display panel 120b received from the second touch controller 710b Based on the sensed values, touch coordinates for the area of the first display panel and the area of the second display panel (eg, in the boundary area between the first display panel 120a and the second display panel 120b) touch coordinates) can be checked.

In the same way, the master touch controller 800 has a touch electrode disposed in an area adjacent to the third display panel 120c among the areas of the first display panel 120a received from the first touch controller 710a. and the sensed value received from the third touch controller 710c and sensed from touch electrodes disposed in an area adjacent to the first display panel 120a among the areas of the third display panel 120c. Based on the sensed value, touch coordinates of the area of the first display panel and the area of the third display panel (eg, touch of a boundary area between the first display panel 120a and the third display panel 120c) coordinates) can be checked.

In addition, the master touch controller 800 receives touch electrodes disposed in an area adjacent to the fourth display panel 120d among areas of the second display panel 120b received from the second touch controller 710b. The sensed value and the sensed value received from the fourth touch controller 710d and sensed from touch electrodes disposed in an area adjacent to the second display panel 120b among the areas of the fourth display panel 120d. Based on , touch coordinates for the area of the second display panel and the area of the fourth display panel (eg, touch coordinates for the boundary area between the second display panel 120b and the fourth display panel 120d) can be checked.

Also, the master touch controller 800 receives touch electrodes disposed in an area adjacent to the fourth display panel 120d among areas of the third display panel 120c received from the third touch controller 710c. The sensed value and the sensed value received from the fourth touch controller 710d and sensed from touch electrodes disposed in an area adjacent to the third display panel 120c among the areas of the fourth display panel 120d. Based on , touch coordinates for the area of the third display panel and the area of the fourth display panel (eg, touch coordinates for the boundary area between the third display panel 120c and the fourth display panel 120d) can be checked.

According to an embodiment, the master touch controller 800 checks each display based on the sensed value (eg, raw data) corresponding to the first area received from each of the touch controllers 710a, 710b, 710c, and 710d. An external device (eg, a host or to a controller or processor). For example, the master touch controller 800 may be connected to the external device through Universal Serial Bus (USB) communication and transmit the touch coordinates or touch data corresponding to the touch coordinates to the external device.

According to an embodiment, as shown in FIG. 8 , touch coordinates are checked through the master touch controller 800 for areas adjacent to each other between display panels 120, and for areas that are not adjacent to each other, each display panel By allowing the touch controller 710 connected to 120 to check touch coordinates, it is possible to prevent touch errors in the boundary area between display panels in a multi-display device. For example, when a touch occurs on a boundary area between display panels, the master touch controller 800 may identify it as one touch rather than a separate touch based on sensing values received from two adjacent display panels. Accordingly, the master touch controller 800 may map one identification number (eg, touch ID) to a touch on the boundary area between the display panels.

Also, for example, when a user performs a drag or drawing operation from the first display panel 120a to the second display panel 120b, the master touch controller 800 moves the first display panel 120a and the second display panel 120a. Based on the sensed values simultaneously received from the first touch controller 710a and the second touch controller 710b at the time of passing the boundary area of the display panel 120b, the sensed value from each touch controller is converted into one touch. By identifying it as , it is possible to prevent dragging or disconnection in drawing.

In addition, when a multi-display device is configured in the manner shown in FIG. 8, the first touch controller 710a, the second touch controller 710b, the third touch controller 710c, and the fourth touch controller 710d Since is connected to one master touch controller 800 and the master touch controller 800 is connected to an external device (eg, a processor) through one communication line, connection with the external device can be simplified.

9 is a diagram illustrating division of regions in each display panel of a multi-display device according to an exemplary embodiment. Referring to FIG. 9 , as described above in the description of FIG. 8 , the area of each display panel 120 may be divided into a first area adjacent to another display panel and a second area not adjacent to another display panel and processed differently.

For example, the area of the first display panel 120a includes a first area 910a adjacent to another display panel (eg, the second display panel 120b or the third display panel 120b) and the first area 910a. It can be divided into a second area 920a (eg, an area not adjacent to the other display panel) excluding the . Similarly, the area of the second display panel 120b includes a first area 910b adjacent to another display panel (eg, the first display panel 120a or the fourth display panel 120d) and the first area 910b. It can be divided into the second area 920b except for . The area of the third display panel 120c excludes the first area 910c adjacent to another display panel (eg, the first display panel 120a or the second display panel 120b) and the first area 910c. It can be divided into a second area 920c. The area of the fourth display panel 120d excludes the first area 910d adjacent to another display panel (eg, the second display panel 120b or the third display panel 120c) and the first area 910d. It can be divided into a second area 920d.

As described above in the description of FIG. 8 , the touch controllers 710 (eg, slave touch controllers) connected to each display panel 120 may be connected to one master touch controller 800 . The touch controller 710 connected to each display panel 120 transmits a sensed value sensed from a corresponding touch electrode to the master touch controller 800 for the first areas 910a, 910b, 910c, and 910d. For the second regions 920a, 920b, 920c, and 920d, the touch coordinates confirmed based on the sensed values from the corresponding touch electrodes may be transmitted to the master touch controller 800 .

According to an embodiment, since the touches sensed at point A 901 and point B 902 in FIG. 9 correspond to the second area, the first touch controller 710a controls the point A 901 and point B ( Each touch coordinate corresponding to 902) may be transmitted to the master touch controller 800. According to an embodiment, an algorithm for calculating touch coordinates for point A 901 and an algorithm for calculating touch coordinates for point B 902 may be different from each other. For example, since point B 902 does not correspond to an area adjacent to another display panel, but is located at the edge of the first display panel 120a, a different algorithm from that applied to point A 901 is applied. Thus, the touch coordinates can be calculated.

According to an embodiment, the touch sensed at point C 903 in FIG. 9 corresponds to a touch in a boundary area between the first display panel 120a and the second display panel 120b, and the first display panel ( It can be sensed simultaneously in the first area of 120a) and the first area of second display panel 120b. As described above, the first touch controller 710a connected to the first display panel 120a may transmit sensed values from the touch electrodes corresponding to point C 903 to the master touch controller 800. there is. Also, the second touch controller 710b connected to the second display panel 120b may transmit sensed values sensed from touch electrodes corresponding to point C 903 to the master touch controller 800 . The master touch controller 800 may check the touch coordinates of the touch at point C 903 based on the sensing values received from the first touch controller 710a and the second touch controller 710b. there is. For example, the master touch controller 800 uses the same algorithm as the algorithm applied to the point A 901 based on the sensed values received from the first touch controller 710a and the second touch controller 710b. You can also check the touch coordinates by applying .

According to an embodiment, when a dragging or drawing operation is performed from point D 904 to point E 905 in FIG. 9 , as described above, a sensed touch during the dragging or drawing operation is applied to the first display panel 120a. ) and the boundary area of the second display panel 120b. In this way, when the touched point moves from the first display panel 120a to the second display panel 120b according to the dragging or drawing operation, the master touch controller 800 controls the first touch controller 710a. And based on the sensing values received from the second touch controller 710b, it is possible to prevent a disconnection of a drag or drawing operation by checking touch coordinates.

10 is a diagram illustrating touch electrodes disposed on each display panel of a multi-display device according to an exemplary embodiment. Referring to FIG. 10 , as described above in the description of FIGS. 8 and 9 , the area of each display panel 120 may be divided into a first area adjacent to another display panel and a second area not adjacent to another display panel and processed differently. there is.

For example, the area of the first display panel 120a includes a first area 910a adjacent to another display panel (eg, the second display panel 120b or the third display panel 120b) and the first area 910a. It can be divided into a second area 920a (eg, an area not adjacent to the other display panel) excluding the . Similarly, the area of the second display panel 120b includes a first area 910b adjacent to another display panel (eg, the first display panel 120a or the fourth display panel 120d) and the first area 910b. It can be divided into a second area 920b (eg, an area not adjacent to the other display panel) except for . The area of the third display panel 120c excludes the first area 910c adjacent to another display panel (eg, the first display panel 120a or the fourth display panel 120d) and the first area 910c. It may be divided into a second area 920c (eg, an area not adjacent to the other display panel). The area of the fourth display panel 120d excludes the first area 910d adjacent to another display panel (eg, the second display panel 120b or the third display panel 120c) and the first area 910d. It may be divided into a second area 920d (eg, an area not adjacent to the other display panel).

As described above, the first touch controller 710a connected to the first display panel 120a transmits sensed values from corresponding touch electrodes to the master touch controller 810 for the first area 910a. can The first touch controller 710a checks the touch coordinates of the second area 920a other than the first area 910a based on the sensed values from the corresponding touch electrodes, and checks the confirmed touch coordinates. may be transmitted to the master touch controller 810 .

According to an embodiment, the second area 920a may be divided into an edge area 922a and a non-edge area 921a. According to an embodiment, the edge area 922a and the non-edge area 921a of the second area 920a may generate touch coordinates by different algorithms.

According to an embodiment, the width W of the first regions 910a, 910b, 910c, and 910d may be determined by a set number of touch electrodes. For example, FIG. 10 illustrates that the width W of the first regions 910a, 910b, 910c, and 910d is set by two touch electrodes TE. However, the width W of the first regions 910a, 910b, 910c, and 910d may be set to one or three or more touch electrodes TE, and the number of the touch electrodes determines touch coordinates in the border area. It can be set in consideration of the accuracy of

11 is a configuration diagram of a touch controller according to an exemplary embodiment. Referring to FIG. 11 , a touch controller 710 (eg, the touch sensing unit 140 of FIG. 1 ) includes a channel selector 1110 , a touch driver 1120 , and a data processor 1130 . The touch controller 710 may be disposed as many as the number of display panels 120a, 120b, 120c, and 120d constituting the multi-display device and connected to each display panel 120a, 120b, 120c, and 120d through communication. For example, as shown in FIG. 8 , the first touch controller 710a is communicatively connected to the first display panel 120a, and the second touch controller 710b is communicatively connected to the second display panel 120b. , the third touch controller 710c may be connected to the third display panel 120c through communication, and the fourth touch controller 710d may be connected through communication to the fourth display panel 120d. Each of the touch controllers 710a, 710b, 710c, and 710d may include at least some of the functions of the touch sensing unit 140 of FIG. 1 described above, or may be substituted for the touch sensing unit 140 . Each of the touch controllers 710a, 710b, 710c, and 710d may be referred to as a touch sensing device, a touch sensing circuitry, or a touch microcontroller unit (MCU).

The channel selector 1110 is connected to a plurality of touch electrodes one-to-one through a plurality of touch lines. The channel selector 1110 supplies the uplink signal supplied from the touch driver 1120 to the touch electrodes during the first touch sensing period, and supplies the touch driving signal supplied from the touch driver 1120 during the third touch sensing period. It can be supplied to the touch electrode.

Also, the channel selection unit 1110 connects the touch line to the touch sensing unit 1130 during the second touch sensing period and the third touch sensing period to sense capacitance generated by an active pen touch or a finger touch. To this end, the channel selection unit 1110 may include a plurality of multiplexers (not shown) that are switched according to the touch synchronization signal and the channel selection signal to selectively connect a plurality of touch lines to the data processing unit 1130 .

Meanwhile, the channel selector 1110 may supply a common voltage to a plurality of touch electrodes through each of a plurality of touch lines during the display period DP1 to DPn of the touch synchronization signal. The touch driver 1120 generates an uplink signal or touch driving signal, and supplies the generated uplink signal or touch driving signal to the touch electrode through each touch line connected to the channel selector 1110 . Specifically, the touch driver 1110 generates uplink signals during the first touch sensing period of one frame period, supplies them to touch electrodes through each touch line, and drives touches during a plurality of third touch sensing periods of one frame period. A signal is generated and supplied to the touch electrode through each touch line. In this case, the uplink signal may include panel information of the panel 120, a protocol version, or a synchronization signal.

In one embodiment, the touch driver 1120 generates an uplink signal or a touch driving signal using a driving signal DS having a plurality of driving pulses swinging between a high voltage and a low voltage based on a reference common voltage. can do. Meanwhile, the touch driver 1140 may supply a common voltage to each of the plurality of touch electrodes through each of the plurality of touch lines during the display period of the touch synchronization signal. In FIG. 11, it has been described that the touch driver 1140 directly inputs an uplink signal or a touch driving signal to the channel selector 1110, but in a modified embodiment, the touch driver 1120 uses an uplink signal or a touch driving signal. may be input to the channel selection unit 1110 through the data processing unit 1130.

Also, the data processing unit 1130 senses the finger touch during the third touch sensing period to generate second sensing data, and determines the coordinates of the finger touch using the generated second sensing data.

The data processing unit 1130 may perform all processes related to data processing in the touch sensing unit 140 . In this specification, all functions related to data processing in the operation of the touch sensing unit 140 may be performed by the data processing unit 1130 .

In order to implement the above functions, the data processing unit 1130 according to the present invention, as shown in FIG. 11, includes a plurality of sensing units 1132, an analog-to-digital converter 1134 (ADC), a pattern conversion unit 1136), and a data generator 1138.

According to an embodiment, the data generator 1138 may generate data of a set touch pattern as shown in FIGS. 5 and 6 based on a sensing value sensed from a touch electrode. As described above, the data generator 1138 may transfer a sensed value corresponding to the data of the touch pattern to the data transmitter 1142 for the first area, which is an area adjacent to another display panel. The data generator 1138 may transmit a sensed value corresponding to the data of the touch pattern to the touch coordinate determiner 1140 for the second area, which is an area not adjacent to another display panel. The touch coordinate determining unit 1140 may check or determine the touch coordinate of the second area based on a sensed value corresponding to data of a touch pattern of the second area. The touch coordinates of the second area identified through the touch coordinate determination unit 1140 may be transmitted to the data transmission unit 1142 . The data transmitter 1142 may transmit the sensed value of the first area and the touch coordinates of the second area to the master touch controller 800 .

12 is a configuration diagram of a master touch controller according to an embodiment. Referring to FIG. 12 , the master touch controller 800 includes touch controllers (eg, a first touch controller 710a, a second touch controller 710b, and a third touch controller) connected to each display panel 120 of a multi-display device. 710c and the fourth touch controller 710d) through communication. For example, the master touch controller 800 may be connected to each of the touch controllers 710a, 710b, 710c, and 710d through Serial Peripheral Interface (SPI) communication. The master touch controller 800 may include at least some functions of the touch sensing unit 140 of FIG. 1 described above, or may be substituted for the touch sensing unit 140 . The master touch controller 800 may be referred to as a touch sensing device, touch sensing circuitry, or a touch micro controller unit (MCU).

According to one embodiment, the master touch controller 800 may include a data processing unit 810 , a data transmission unit 820 , and a memory 830 . The data processing unit 811 may include a first area processing unit 811 , a second area processing unit 812 , and a touch management unit 813 . The master touch controller 810 may store information or data received from each of the touch controllers 710a, 710b, 710c, and 710d in the memory 830. For example, as described above, the master touch controller 810 receives the sensed value for the first area and the touch coordinates for the second area from each of the touch controllers 710a, 710b, 710c, and 710d, and receives the received touch coordinates for the second area. The sensed value of the first area and the touch coordinates of the second area may be stored in the memory 830 .

The first area processing unit 811 of the data processing unit 810 determines the boundary area between the display panels based on the sensing values of the first area received from the respective touch controllers 710a, 710b, 710c, and 710d. You can check your touch. For example, based on the sensed value of the first area 910a received from the first touch controller 710a and the sensed value of the first area 910b received from the second touch controller 710b as described above, Touch coordinates of a touch in the boundary area between the first display panel 120a and the second display panel 120b may be checked.

The second area processing unit 812 of the data processing unit 810 determines the touch coordinates on the multi-display based on the touch coordinates of the second area received from each of the touch controllers 710a, 710b, 710c, and 710d. can For example, since the touch coordinates of the second area received from each of the touch controllers 710a, 710b, 710c, and 710d are touch coordinates of the corresponding display panels 120a, 120b, 120c, and 120d, each touch coordinate is set as a whole. It can be converted into touch coordinates on multiple displays. According to an embodiment, the second region processing unit 812 or an operation of the second region processing unit 812 may be omitted.

The touch management unit 813 may integrate touch coordinates of the first area output from the first area processing unit 811 and touch coordinates of the second area output from the second area processing unit 812 to manage the touch. there is. For example, as shown in FIG. 9 , the touch management unit 813 converts touch coordinates corresponding to a touch at point A 901 and touch coordinates corresponding to a touch at point B 902 to the second area processing unit 812 . ) can be received through Also, the touch management unit 813 may receive touch coordinates corresponding to the touch at point C 903 through the first area processing unit 811 . According to an embodiment, when a dragging or drawing operation is performed from point D 904 to point E 905, the touch management unit 813 controls the first area processing unit 811 and the second area processing unit 812 from each other. Based on the received touch coordinates, it may be determined as a drag or drawing motion passing through a boundary area between display panels. For example, the touch management unit 813 may perform a touch tracking process based on touch coordinate change information received from the first area processing unit 811 and the second area processing unit 812 . In addition, the touch management unit 813 performs a smoothing process on coordinates moved by the touch based on the touch coordinate change information received from the first area processing unit 811 and the second area processing unit 812. can be done

According to an embodiment, the data transmission unit 820 may transmit information related to touch coordinates identified by the touch management unit 813 to the processor 1200 . The master touch controller 800 may be connected to the processor 1200 through Universal Serial Bus (USB) communication.

As described above, according to the present embodiment, touch coordinates are checked through the master touch controller 800 for areas adjacent to each other between display panels 120, and each display panel 120 for areas that are not adjacent to each other. ), it is possible to prevent a touch error on the boundary area between display panels in a multi-display device by having the touch controller 710 connected to check the coordinates of the touch.

Also, for example, when a user performs a dragging or drawing operation passing through a border area between display panels in a multi-display device, a touch controller connected to each display panel when the master touch controller 800 passes the border area. By identifying the sensed values sensed from each touch controller as a single touch based on the sensed values simultaneously received from the touch controller, it is possible to prevent dragging or drawing interruption.

In the foregoing, for convenience of description, an example in which the external object touching the panel is a finger - the so-called finger touch method - has been mainly described, but the present embodiment is not limited thereto, and the present embodiment is an active (stylus) pen touch method can also be applied.

Claims (16)

a touch driver supplying a driving signal to a plurality of touch electrodes disposed on the first display panel; and
A data processor configured to receive sensing values sensed from the plurality of touch electrodes disposed on the first display panel;
The data processing unit,
A first sensing value sensed from touch electrodes disposed in a first area adjacent to a second display panel among areas of the first display panel, and a sensed value obtained from touch electrodes disposed in a second area excluding the first area. Check the second sensed value;
Checking touch coordinates for the second area based on the second sensing values sensed from touch electrodes corresponding to the identified second area;
The touch sensing device transmits the first sensing values sensed by touch electrodes corresponding to the first area and touch coordinates of the second area to an external device. The method of claim 1, wherein the width of the first region,
A touch sensing device determined based on a set number of touch electrodes. According to claim 1,
The touch sensing device is connected to the external device through Serial Peripheral Interface (SPI) communication. According to claim 1,
The first display panel has a rectangular shape, a first side of the first display panel is adjacent to the second display panel, and a second side of the first display panel is adjacent to a third display panel. . According to claim 4,
The data processing unit,
The touch sensing device transmits third sensing values sensed from touch electrodes disposed in an area of the first display panel adjacent to the third display panel to the external device. According to claim 1,
The data processing unit,
generating touch information including the first sensing values sensed from touch electrodes corresponding to the first area and touch coordinates for the second area;
A touch sensing device that transmits the generated touch information to the external device. Receives a first sensing value sensed from touch electrodes disposed in an area of the first display panel adjacent to the second display panel, from a first touch sensing device connected to the first display panel, and receives second sensing values sensed from touch electrodes disposed in an area adjacent to the first display panel among areas of the second display panel, from a second touch sensing device connected to; a data processing unit that checks touch coordinates of the area of the first display panel and the area of the second display panel based on the 2 sensed values; and
A data transmission unit configured to transmit touch coordinates of the region of the first display panel and the region of the second display panel to an external device; including a master touch sensing device. According to claim 7,
The data processing unit,
Receives, from the first touch sensing device, touch coordinates of an area of the first display panel other than an area adjacent to the second display panel, and receives touch coordinates from the second touch sensing device to the area of the second display panel. Wherein the master touch sensing device receives touch coordinates for an area other than an area adjacent to the first display panel. According to claim 7,
The master touch sensing device is connected to the external device through USB (Universal Serial Bus) communication, the master touch sensing device. According to claim 7,
A first side of the first display panel is adjacent to the second display panel, and a second side of the first display panel is adjacent to a third display panel. According to claim 10,
The data processing unit,
receiving a third sensing value sensed from touch electrodes disposed in an area of the third display panel adjacent to the first display panel, from a third touch sensing device connected to the third display panel; A master touch sensing device that checks touch coordinates of an area of a display panel and an area of the third display panel. According to claim 7,
The data processing unit,
Based on the first sensing value and the second sensing value, the master touch sensing device confirms touch coordinates at a boundary between the first display panel and the second display panel as one touch operation. According to claim 12,
The data processing unit,
Assigning one identification number to the touch coordinates at the boundary identified by the one touch operation, the master touch sensing device. According to claim 12,
The data processing unit,
Based on the first sensing value and the second sensing value, confirming a drag input moving from an area of the first display panel to an area of the second display panel, the master touch sensing device. According to claim 12,
The data processing unit,
The master touch sensing device performs a touch tracking process based on the identified touch coordinate change information for the first display panel area and the second display panel area. According to claim 12,
The data processing unit,
The master touch sensing device performs a smoothing process on coordinates where the touch has moved based on the identified touch coordinate change information for the region of the first display panel and the region of the second display panel.

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