KR20120116097A - Touch display device and method for calculating moving direction of touch area - Google Patents

Abstract

PURPOSE: A touch display device and a touch area directivity calculating method thereof are provided to accurately predict coordinates of the next touch area by supplying the directivity of the touch area, even though there is an outer noise. CONSTITUTION: Touch sensors are formed on a touch panel. A sensing data generator(201) generates sensing data on each frame by using touch sensing signals supplied by the touch sensors. A touch area determiner(202) determines a touch area on each frame by analyzing the sensing data on each frame. A difference value generator(203) generates difference values by deducting the sensing data of a previous frame and the sensing data of a current frame corresponding to each other. [Reference numerals] (201) Sensing data generator; (202) Touch area determiner; (203) Difference value generator; (204) Directional determination unit; (AA) Touch sensing signals of m

Description

TOUCH DISPLAY DEVICE AND METHOD FOR CALCULATING MOVING DIRECTION OF TOUCH AREA}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a touch display device, and more particularly, to a touch display device providing a directionality of a touch area so as to predict coordinates of a touch area in a next frame, and a method of calculating a touch area movement direction thereof.

Conventional touch display devices have a problem in that they cannot provide accurate coordinates of the touch area touched by the user due to external noise.

The present invention has been made to solve the above problems, and by providing the directivity of the touch area to predict the coordinates of the touch area in the next frame, even if there is external noise, the coordinates of the next touch area can be accurately estimated and calculated. SUMMARY OF THE INVENTION An object of the present invention is to provide a touch display device and a method of calculating the touch area directionality thereof.

According to an aspect of the present invention, there is provided a touch display device including: m touch sensors (m is a natural number greater than 1) formed in a touch panel; A sensing data generation unit generating m sensing data using m touch sensing signals provided from the m touch sensors every frame; A touch region determination unit for analyzing m sensing data from the sensing data generation unit every frame to determine a touch region for each frame; A difference value generation unit for generating m difference values by calculating the difference between the m sensed data in the previous frame and the m sensed data in the current frame. And dividing the touch area in each frame into a plurality of touch cells, and determining the direction of each touch cell in each frame based on the tea values of the touch cells and the tea values of touch cells located in the vicinity. The direction of the touch area in each frame is determined based on the direction of each touch cell, and the touch area in the current frame is touched in the previous frame based on the determined direction of the touch area in every frame. It characterized in that it comprises a directional determination section for determining in which direction the movement from the area.

The directional determination unit may include a first step of selecting any one of a plurality of touch cells included in the touch area in the current frame and defining the selected touch cell as a center touch cell; Among the plurality of peripheral touch cells adjacent to the center touch cell, the values of the plurality of peripheral touch cells located to the left of the center touch cell are summed to generate left-direction data for the center touch cell, and the adjacent touch cells are adjacent to the center touch cell. Among the plurality of peripheral touch cells, the values of the plurality of peripheral touch cells located to the right of the center touch cell are summed to generate right-direction data for the center touch cell, and the plurality of peripheral touch cells adjacent to the center touch cell. Sum values of a plurality of peripheral touch cells located above the center touch cell to generate upward data for the center touch cell, and among the plurality of peripheral touch cells adjacent to the center touch cell. A second stage of generating the downward data for the central touch cell by summing the values of a plurality of peripheral touch cells located below the; .; The moving direction of the center touch cell in the horizontal direction is determined based on the polarity comparison between the left data and the right data, and the vertical direction of the center touch cell is based on the polarity comparison of the upper data and the lower data. A third step of determining a moving direction to A fourth step of determining the final moving direction of the center touch cell based on the moving direction in the horizontal direction and the vertical direction of the center touch cell; A fifth step of determining a final moving direction of each of the remaining touch cells by performing the first to fourth steps with respect to each of the remaining touch cells of the touch area; And a sixth step of determining the final moving direction of the touch area based on the final moving direction of each of the touch cells included in the touch area.

The left-direction data of the center touch cell includes a value of a peripheral touch cell positioned diagonally on the upper left side of the center touch cell, a value of a peripheral touch cell positioned immediately to the left of the center touch cell, and a directly lower left side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally; The right-direction data of the center touch cell includes a tea value of a peripheral touch cell positioned at a diagonal of the right upper side of the center touch cell, a tea value of a peripheral touch cell located immediately to the right of the center touch cell, and a immediately lower right side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally; The upward direction data of the center touch cell may include a tea value of a peripheral touch cell positioned at an upper left diagonal line of the center touch cell, a tea value of a peripheral touch cell located immediately above the center touch cell, and a right upper side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally; The downward data of the center touch cell includes a value of a peripheral touch cell positioned at a lower left diagonal line of the center touch cell, a value of a peripheral touch cell positioned directly below the center touch cell, and a directly lower right side of the center touch cell. It means that the sum of the tea value of the surrounding touch cell located on the diagonal.

In the third step, when the left direction data and the right direction data in the current frame have the same polarity, the directional determination unit determines that the center touch cell does not move in the horizontal direction in the current frame; If the left direction data and the right direction data in the current frame exhibit opposite polarity, determine that the center touch cell in the current frame is horizontally moved in the direction indicated by the data of the negative polarity; Determining that the center touch cell does not move vertically in the current frame when the upper direction data and the lower direction data in the current frame have the same polarity; When the upper direction data and the lower direction data in the current frame exhibit opposite polarity, the center touch cell in the current frame is determined to be vertically moved in the direction indicated by the negative data. .

In the sixth step, the directional determination unit adds all the horizontal moving components included in the final moving directions of all the touch cells of the touch area, and moves the touch area in the horizontal direction based on the summed value. Determine the direction; Summing all the vertical movement components included in the final moving directions of all the touch cells of the touch area, and determining the moving direction of the touch area in the vertical direction based on the summed value; The final moving direction of the touch area is determined based on the moving direction in the horizontal direction and the vertical direction of the touch area.

In addition, the touch area directional calculation method of the touch display device for achieving the above-described object, the touch area directional calculation method in the touch display device comprising m touch sensors (m is a natural number greater than 1) formed in the touch panel. The method may include: generating m sensing data using m sensing signals provided from the m touch sensors every frame; Analyzing the m pieces of sensing data every frame to determine a touch area for each frame; Generating m difference values by subtracting m sensed data in a previous frame and m sensed data in a current frame from corresponding values; And dividing the touch area in each frame into a plurality of touch cells, and determining the direction of each touch cell in each frame based on the tea values of the touch cells and the tea values of touch cells located in the vicinity. The direction of the touch area in each frame is determined based on the direction of each touch cell, and the touch area in the current frame is touched in the previous frame based on the determined direction of the touch area in every frame. And a step D for determining in which direction from the area.

The step D may include selecting any one of a plurality of touch cells included in the touch area in the current frame and defining the selected touch cell as a center touch cell; Among the plurality of peripheral touch cells adjacent to the center touch cell, the values of the plurality of peripheral touch cells located to the left of the center touch cell are summed to generate left-direction data for the center touch cell, and the adjacent touch cells are adjacent to the center touch cell. Among the plurality of peripheral touch cells, the values of the plurality of peripheral touch cells located to the right of the center touch cell are summed to generate right-direction data for the center touch cell, and the plurality of peripheral touch cells adjacent to the center touch cell. Sum values of a plurality of peripheral touch cells located above the center touch cell to generate upward data for the center touch cell, and among the plurality of peripheral touch cells adjacent to the center touch cell. Generating a downward direction data for the center touch cell by summing the values of the plurality of peripheral touch cells located at the lower side of the second touch cell; The moving direction of the center touch cell in the horizontal direction is determined based on the polarity comparison between the left data and the right data, and the vertical direction of the center touch cell is based on the polarity comparison of the upper data and the lower data. Determining the moving direction to the step D-3; Determining a final movement direction of the center touch cell based on the movement direction in the horizontal direction and the vertical direction of the center touch cell; Performing step D-1 to step D-4 on each of the remaining touch cells of the touch area to determine a final moving direction for each of the remaining touch cells; And determining step D-6 of the final movement direction of the touch region based on the final movement direction of each touch cell included in the touch region.

The left-direction data of the center touch cell includes a value of a peripheral touch cell positioned diagonally on the upper left side of the center touch cell, a value of a peripheral touch cell positioned immediately to the left of the center touch cell, and a directly lower left side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally; The right-direction data of the center touch cell includes a tea value of a peripheral touch cell positioned at a diagonal of the right upper side of the center touch cell, a tea value of a peripheral touch cell located immediately to the right of the center touch cell, and a immediately lower right side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally; The upward direction data of the center touch cell may include a tea value of a peripheral touch cell positioned at an upper left diagonal line of the center touch cell, a tea value of a peripheral touch cell located immediately above the center touch cell, and a right upper side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally; The downward data of the center touch cell includes a value of a peripheral touch cell positioned at a lower left diagonal line of the center touch cell, a value of a peripheral touch cell positioned directly below the center touch cell, and a directly lower right side of the center touch cell. It means that the sum of the tea value of the surrounding touch cell located on the diagonal.

In step D-3, if the left data and the right data in the current frame have the same polarity, it is determined that the center touch cell does not move in the horizontal direction in the current frame; If the left direction data and the right direction data in the current frame exhibit opposite polarity, determine that the center touch cell in the current frame is horizontally moved in the direction indicated by the data of the negative polarity; Determining that the center touch cell does not move vertically in the current frame when the upper direction data and the lower direction data in the current frame have the same polarity; When the upper direction data and the lower direction data in the current frame exhibit opposite polarity, the center touch cell in the current frame is determined to be vertically moved in the direction indicated by the negative data. .

In step D-6, the horizontal moving components included in the final moving directions of all the touch cells of the touch area are summed, and the moving direction of the touch area in the horizontal direction is determined based on the summed value. ; Summing all the vertical movement components included in the final moving directions of all the touch cells of the touch area, and determining the moving direction of the touch area in the vertical direction based on the summed value; The final moving direction of the touch area is determined based on the moving direction in the horizontal direction and the vertical direction of the touch area.

The touch display device and the method for calculating the touch area orientation thereof according to the present invention have the following effects.

According to the present invention, the touch display device and the method of calculating the touch area directionality thereof may provide the directivity of the touch area so as to predict the coordinates of the touch area in the next frame. Can be.

1 illustrates a touch display device according to an exemplary embodiment of the present invention.
2 is a detailed configuration diagram of the touch analysis / determination unit of FIG.
3 illustrates a touch area in a previous frame.
4 is a diagram illustrating numerical values of sensed data of each touch cell of FIG. 3.
5 illustrates a touch area in the current frame.
FIG. 6 is a diagram illustrating numerical values of sensed data of each touch cell of FIG. 5; FIG.
7 is a diagram illustrating a difference between sensing data of a previous frame and sensing data of a current frame.
8 shows a part of FIG. 7;
9 illustrates left-direction data of touch cells positioned in the first and second touch regions.
FIG. 10 is a diagram illustrating right-direction data of touch cells positioned in first and second touch regions. FIG.
FIG. 11 illustrates upper direction data of touch cells positioned in first and second touch regions.
FIG. 12 illustrates left-direction data of touch cells positioned in the first and second touch regions.
FIG. 13 illustrates direction components of touch cells positioned in first and second touch regions.
14 is a view of a portion of FIG. 7;
15 is a flowchart illustrating a method of determining a touch area movement direction of a touch display device according to an exemplary embodiment of the present invention.

1 illustrates a touch display device according to an exemplary embodiment of the present invention.

As shown in FIG. 1, the touch display device according to an exemplary embodiment of the present invention may include a display panel TP, a touch analysis / determination unit TAD, a timing controller TC, a gate driver GD, and a data driver. DD) and gamma voltage generation unit GV.

The display panel TP includes n pixels (n is a natural number greater than 1) for displaying an image and m touch sensors TS (m is a natural number greater than 1) for sensing a touch from the outside. Include. One touch sensor TS is formed on the display panel TP per k pixels (k is a natural number larger than 1).

The touch sensor TS is a capacitive touch sensor TS. The touch sensor TS detects when a touch is applied to the display unit of the display panel TP by a finger or a separate touch means. When the touch is not applied to the display unit, the touch sensor TS outputs a touch sensing signal having a value greater than a preset reference signal, whereas when a touch is applied to the display unit, the touch sensing signal having a value smaller than the reference signal is applied. Outputs

The touch analysis / determination unit (TAD) analyzes m touch detection signals provided from m touch sensors TS every frame to determine whether each touch is detected, and if there is a touch, the touched area (hereinafter referred to as “touch”). , Expressed as a touch area). The calculated coordinates are then supplied to the timing controller TC.

The timing controller TC corrects image data from the outside based on the coordinates of the touch area provided from the touch analysis / determination unit TAD, and supplies the corrected image data to the data driver DD. In addition, the timing controller TC generates a data control signal and a gate control signal using a horizontal synchronization signal, a vertical synchronization signal, and a dot clock provided from the outside. This data control signal is a control signal for controlling the operation of the data driver DD, which is supplied to the data driver DD. The gate control signal is a signal for controlling the gate driver GD, and the gate control signal is supplied to the gate driver GD.

The data driver DD converts the corrected image data provided from the timing controller TC into an analog signal by using the gamma voltage from the gamma voltage generation unit GV, and converts the converted image data into the display panel TP. Pixels).

The gate driver GD drives m pixels in each frame period by sequentially driving pixels in horizontal line units.

Here, the touch analysis / determination unit (TAD) will be described in more detail.

FIG. 2 is a detailed configuration diagram of the touch analysis / determination unit (TAD) of FIG. 1.

As illustrated in FIG. 2, the touch analysis / determination unit TAD includes a sensing data generation unit 201, a touch area determination unit 202, a difference value generation unit 203, and a directional determination unit 204. .

The sensing data generation unit 201 generates m sensing data using m touch sensing signals provided from m touch sensors TS every frame. The m touch sensing signals are analog signals and the m sensing data are digital signals.

The touch area determination unit 202 analyzes m pieces of sensing data from the sensing data generation unit 201 every frame. And based on this analysis, the touch area in every frame is determined.

The difference value generation unit 203 calculates m difference values by subtracting m sense data in a previous frame and m sense data in a current frame.

The directional determination unit 204 divides the touch area in each frame into a plurality of touch cells TC, and based on the difference between the touch cells TCs and the neighboring touch cells TCs. The direction of each touch cell TC in the frame is determined. The directionality of the touch area in every frame is determined based on the directionality of each of the determined touch cells TC, and the touch area in the current frame is based on the directionality of the touch area in each of the determined frames. The direction of movement from the touch area in the previous frame is determined.

Herein, the operation of the directional decision unit 204 will be described in more detail.

3 illustrates a touch area in a previous frame.

3 illustrates an example in which a total of 176 touch sensors TS are configured on the display panel TP. One rectangle in FIG. 3 means one touch cell TC. One touch cell TC is detected by one touch sensor TS. As shown in FIG. 3, two touch regions exist in the display panel TP. For convenience of description, the upper touch area is defined as the first touch area TA1, and the lower touch area is defined as the second touch area TA2.

4 is a diagram illustrating numerical values of sensed data of each touch cell TC in FIG. 3. That is, the numerical value displayed on one touch cell TC refers to the numerical value of sensed data detected by the touch sensor TS corresponding to the touch cell TC. Here, the reference signal as a reference for determining whether the touch is set to 150. The touch cell TC having the sensing data larger than 150 means that the cell has not been touched. The touch cell TC having the sensed data indicates that the touched cell is a touched cell. In FIG. 4, the touch cells TC touched are displayed in yellow. In FIG. 4, the five touch cells TC shown in yellow form the first touch area TA1, and the other three touch cells TC shown in yellow form the second touch area TA2.

5 illustrates a touch area in the current frame.

FIG. 5 shows a state in which the first and second touch areas TA1 and TA2 of FIG. 4 are moved.

FIG. 6 is a diagram illustrating numerical values of sensed data of each touch cell TC in FIG. 5. In FIG. 6, the touch cells TC touched are displayed in yellow. In FIG. 6, the seven touch cells TC shown in yellow form the first touch area TA1, and the other three touch cells TC shown in yellow form the second touch area TA2. 6 illustrates a situation in which two touches are simultaneously generated.

As such, the positions of the first and second touch areas TA1 and TA2 change with time, and thus, the first and second touch areas TA1 and TA2 in the previous frame and the first and second touches in the current frame. The positions of the areas TA1 and TA2 change. This occurs when the user moves two fingers in a specific direction while touching two fingers on the display unit of the display panel TP.

The directional decision unit 204 according to the present invention determines the direction in which the first and second touch areas TA1 and TA2 in the previous frame are moved in the current frame by the following method, and thus the first and second touch areas. The orientation of TA1 and TA2 can be determined.

 7 is a diagram illustrating a difference between sensing data of a previous frame and sensing data of a current frame.

This difference is expressed by subtracting 176 sensed data of the previous frame from 176 sensed data of the current frame. 7 shows 176 touch cells TC having these differences.

The directional decision unit 204 calculates the moving direction of the touch area in the current frame by sequentially performing the following first to sixth steps.

First, the directional decision unit 204 selects any one of the plurality of touch cells TC included in the touch area in the current frame, and selects the selected touch cell TC. A first step of defining the center touch cell TC is performed.

For example, FIG. 8 is a view of a portion of FIG. 7, and as illustrated in FIG. 7, one of the seven touch cells TC positioned in the first touch area TA1 has a difference of −5. The touch cell TC may be defined as the center touch cell TC.

Subsequently, the directional decision unit 204 determines the values of the plurality of peripheral touch cells TC located on the left side of the center touch cell TC among the plurality of peripheral touch cells TC adjacent to the center touch cell TC. Summing up to generate left-direction data for this center touch cell (TC), and a plurality of peripheral touch cells (TC) adjacent to the center touch cell (TC) located on the right side of the center touch cell (TC) The values of the peripheral touch cells TC are summed to generate rightward data for the center touch cell TC, and the center touch cell among the plurality of peripheral touch cells TC adjacent to the center touch cell TC. Sum values of the plurality of peripheral touch cells TC located above the TC to generate upward data for the central touch cell TC, and generate a plurality of peripheral touches adjacent to the center touch cell TC. Of the plurality of peripheral touch cells TC located below the center touch cell TC of the cells TC Summing the values to carry out the second step of generating a downward direction data for a center touch cell (TC).

For example, there are eight peripheral touch cells TC around the center touch cell TC of FIG. 8, and the left-direction data includes the center touch cell TC among the eight peripheral touch cells TC. The value of the peripheral touch cell TC positioned at the diagonal of the upper left side of the first touch cell TC-1, the value of the peripheral touch cell TC positioned immediately to the left of the center touch cell TC-1, and the center touch cell. It means the sum between the tea values (0) of the peripheral touch cells (TC) located on the lower left diagonal just below (TC). That is, this leftward data becomes -2 (-1 + (-1) + 0). FIG. 9 illustrates left-direction data of the touch cells TC positioned in the first and second touch areas TA1 and TA2, and the left-side data of the touch cell TC having the difference of -5 is- It can be seen that it is indicated by 2.

The right-direction data of the center touch cell TC is a difference value of the peripheral touch cell TC located at the right upper side diagonal line of the center touch cell TC, and immediately of the center touch cell TC. It means the sum between the tea value (-10) of the peripheral touch cell (TC) located on the right side and the tea value (-26) of the peripheral touch cell (TC) located on the right lower diagonal of the center touch cell (TC). That is, this right-side data becomes -38 ((-2) + (-10) + (-26)). FIG. 10 is a diagram illustrating right direction data of touch cells TC positioned in the first and second touch areas TA1 and TA2, and the right direction data of the touch cell TC having a difference of −5 described above is −38. It can be seen that.

The upward direction data of the center touch cell TC may include a difference value (-1) of a peripheral touch cell TC positioned on a left upper diagonal line of the center touch cell TC, and a bar of the center touch cell TC. It means the sum between the tea value (-1) of the peripheral touch cell TC located on the upper side and the tea value (-2) of the peripheral touch cell TC located on the right upper side diagonal line of the center touch cell TC. That is, this upward data becomes -4 ((-1) + (-1) + (-2)). FIG. 11 illustrates upper direction data of the touch cells TC positioned in the first and second touch areas TA1 and TA2, and the upper direction data of the touch cell TC having the difference of -5 is- It can be seen that it is indicated by 4.

The downward direction data of the center touch cell TC includes a difference value 0 of a peripheral touch cell TC positioned on a lower left diagonal line of the center touch cell TC, and immediately below the center touch cell TC. It means the sum of the tea value (-13) of the peripheral touch cell (TC) located at and the tea value (-26) of the peripheral touch cell (TC) located at the right lower diagonal of the center touch cell (TC). That is, this downward data becomes -39 (0 + (-13) + (-26)). FIG. 12 is a diagram illustrating left-direction data of touch cells TC positioned in the first and second touch areas TA1 and TA2, and the lower-direction data of the touch cell TC having the difference of −5 described above is − You can see that it is indicated by 39.

Next, the directional determination unit 204 determines the moving direction of the center touch cell TC in the horizontal direction based on the polarity comparison between the left direction data and the right direction data, and compares the polarity of the upper direction data and the lower direction data. A third step of determining the moving direction of the center touch cell (TC) in the vertical direction is performed based on. That is, when the left direction data and the right direction data in the current frame have the same polarity, the directional determination unit 204 determines that the center touch cell TC in the current frame does not move in the horizontal direction. On the other hand, when the left direction data and the right direction data in the current frame have opposite polarity, it is determined that the center touch cell TC in the current frame is horizontally moved in the direction indicated by the negative data.

For example, since the left direction data of the center touch cell TC having the difference of -5 is -2 and the right direction data is -38, it is determined that the center touch cell TC has not moved in the horizontal direction. . In addition, since the upper direction data of the center touch cell TC having a difference of -5 is -4 and the lower direction data is -39, it is determined that the center touch cell TC does not move even in the vertical direction.

Thereafter, the directional determination unit 204 performs a fourth step of determining the final moving direction of the center touch cell TC based on the moving direction in the horizontal direction and the vertical direction of the center touch cell TC. To perform.

The directional determination unit 204 displays the data 8 when one central touch cell TC has the direction to the left direction, and the data when the central touch cell TC has the direction to the right direction. 4, and when the center touch cell TC has the upward direction, it is displayed as data 2, and when this center touch cell TC has the direction of the downward direction, it is displayed as data 1 do. When the central touch cell TC does not have any directivity, the center touch cell TC displays data zero. In addition, when the center touch cell TC simultaneously has a direction in the left direction and an upward direction, it is represented by data 10 (8 + 2), and the center touch cell TC is directed in the left direction and the downward direction. When at the same time it is represented by data 9 (8 + 1), when this central touch cell (TC) has a direction in the right direction and upward direction at the same time, it is represented by data 6 (4 + 2), and When the central touch cell TC simultaneously has the direction in the right direction and the downward direction, it is represented by data 5 (4 + 1). On the other hand, since the center touch cell TC cannot move simultaneously in directions opposite to each other, the center touch cell TC cannot have directional directions in the left direction and the right direction at the same time, and also the directional directions in the upper direction and the lower direction. Cannot have at the same time.

Therefore, the center touch cell TC having a difference of -5 is represented by data 0. FIG. 13 is a diagram illustrating the direction components of the touch cells TC positioned in the first and second touch areas TA1 and TA2. As shown therein, the center touch cell TC having a difference of −5 represents data. You can see that it is marked as 0. That is, the final moving direction of the center touch cell TC having the difference of -5 is represented by data zero.

Next, the directional determination unit 204 may be configured based on the final moving direction of each of the touch cells TC included in the first and second touch areas TA1 and TA2. A sixth step of determining the final moving direction of TA2) is performed. That is, the direction of the remaining touch cells TC is determined sequentially.

For example, FIG. 14 is a view of a portion of FIG. 7, and as illustrated in FIG. 14, one of the seven touch cells TC positioned in the first touch area TA1 has a difference of −10. The touch cell TC may be defined as the center touch cell TC.

In the manner as described above, the left direction data, right direction data, upper direction data and lower direction data for the center touch cell TC having a difference of -10 are -19, 34, -1 and -23, respectively. It can be seen that. This can be seen from Figures 9-12. Since the left direction data of the center touch cell TC having a difference of −10 is −19 and the right direction data is 34, it is determined that the center touch cell TC has moved to the left direction. In addition, since the upper direction data of the center touch cell TC having a difference of -10 is -1 and the lower direction data is -23, it is determined that the center touch cell TC does not move in the vertical direction. Therefore, as shown in FIG. 13, the center touch cell TC having a difference of −10 is represented by data 8. That is, the final moving direction of the center touch cell TC having the difference of -10 is represented by data 8.

As another example, the left direction data, the right direction data, the up direction data, and the down direction data for the center touch cell TC having a difference of -26 in FIG. 7 are -25, 34, 1, and -23, respectively. It can be seen that. This can be seen from Figures 9-12. Since the left direction data of the center touch cell TC having the difference of -26 is -25 and the right direction data is 34, it is determined that the center touch cell TC has moved to the left direction. In addition, since the upper direction data of the center touch cell TC having a difference of -26 is 1 and the lower direction data is -23, it is determined that the center touch cell TC has also moved downward. Therefore, as shown in FIG. 13, the center touch cell TC having a difference of −26 is represented by data 9. This data 9 is the sum of data 8 corresponding to the moving component in the left direction and data 1 corresponding to the moving component in the downward direction. That is, the final moving direction of the center touch cell TC having the difference of -26 is represented by data 9.

In this manner, the directivity of all the touch cells TC included in the first and second touch areas TA1 and TA2 of the current frame may be represented by the directional data as shown in FIG. 13.

The directional determination unit 204 determines the final directivity of the first touch area TA1 and the final directivity of the second touch area TA2 based on the directional data of FIG. 12. For example, the touch cells TC included in the first touch area TA1 in FIG. 13 have data 0, 8, 8, 0, 9, 9, and 8, respectively, and thus, the first touch area TA1. ) Can be seen that as time elapses from the previous frame to the current frame, it finally moved by 5 in the left direction and 2 in the downward direction. In addition, since the touch cells TC included in the second touch area TA2 have data 0, 0, and 8, respectively, the second touch area TA2 is leftward as time passes from the previous frame to the current frame. It can be seen that moved by 1.

The touch analysis / determination unit TAD further includes a touch coordinate calculation unit for calculating the coordinates of the touch area, and the touch coordinate calculation unit receives the directional data (FIG. 13) provided from the directional determination unit 204 described above. More accurate coordinates of the touch area can be calculated in the frame.

15 is a flowchart illustrating a method of determining a movement direction of a touch area of a touch display device according to an exemplary embodiment of the present invention.

First, m touch detection signals are extracted from m touch sensors TS by scanning the entire area of the display panel TP during one frame (S1).

Thereafter, it is determined whether the frame is the first frame (S2). If this frame is the first frame, the entire area of the display panel TP is scanned again. On the other hand, if the frame is a second or more frame other than the first frame, it is determined whether a touch area exists (S3).

That is, m sensing data are generated using the m touch sensing signals, and the m touch sensing data are analyzed to determine whether a touch area exists in the frame. If the touch area does not exist, the entire area of the display panel TP is scanned again. On the other hand, if there is a touch area, the directional data as shown in Figure 13 is extracted (S4).

That is, any one of the plurality of touch cells TC included in the touch area in the current frame is selected, and the selected touch cell TC is defined as the center touch cell TC. Perform the first step.

Thereafter, among the plurality of peripheral touch cells TC adjacent to the center touch cell TC, the values of the plurality of peripheral touch cells TC positioned on the left side of the center touch cell TC are summed to form the center touch cell TC. Generating left-direction data for the plurality of peripheral touch cells TC of the plurality of peripheral touch cells TC adjacent to the central touch cell TC Summing up to generate right-direction data for this center touch cell (TC), and a plurality of peripheral touch cells (TC) adjacent to the center touch cell (TC) located above the center touch cell (TC) The values of the peripheral touch cells TC are summed to generate upward data for the center touch cell TC, and the center touch among the plurality of peripheral touch cells TC adjacent to the center touch cell TC. By summing the values of the plurality of peripheral touch cells TC located below the cell TC, It performs a second step of generating a downward direction data for the core touch cell (TC).

Next, the moving direction of the center touch cell TC in the horizontal direction is determined based on the polarity comparison between the left data and the right data, and the center is based on the polarity comparison of the upper data and the lower data. A third step of determining the moving direction of the touch cell TC in the vertical direction is performed.

Subsequently, a fourth step of determining the final moving direction of the center touch cell TC based on the moving direction in the horizontal direction and the vertical direction of the center touch cell TC is performed.

Subsequently, a fifth step of determining a final moving direction of each of the remaining touch cells TC is performed by performing the first to fourth steps described above with respect to each of the remaining touch cells TC of the touch area. .

Next, the final moving direction of the touch area is determined based on the final moving direction of each touch cell TC included in the touch area. That is, the final directivity of the touch area is determined based on the left and right direction and the vertical direction of the touch area (S5 and S6).

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents. Will be clear to those who have knowledge of.

201: detection data generation unit 202: touch area determination unit
203: tea value generating unit 204: directional determination unit

Claims (10)

M touch sensors (m is a natural number greater than 1) formed in the touch panel;
A sensing data generation unit generating m sensing data using m touch sensing signals provided from the m touch sensors every frame;
A touch region determination unit for analyzing m sensing data from the sensing data generation unit every frame to determine a touch region for each frame;
A difference value generation unit for generating m difference values by calculating the difference between the m sensed data in the previous frame and the m sensed data in the current frame. And,
The touch area in each frame is divided into a plurality of touch cells, and the direction of each touch cell in each frame is determined based on the value of the touch cells and the value of the touch cells located around the touch cell. The directionality of the touch area in every frame is determined based on the directionality with respect to each of them. And a directional determination unit determining which direction the vehicle moves. The method of claim 1,
The directional determination unit,
A first step of selecting any one of a plurality of touch cells included in the touch area in the current frame and defining the selected touch cell as a center touch cell;
Among the plurality of peripheral touch cells adjacent to the center touch cell, the values of the plurality of peripheral touch cells located to the left of the center touch cell are summed to generate left-direction data for the center touch cell, and the adjacent touch cells are adjacent to the center touch cell. Among the plurality of peripheral touch cells, the values of the plurality of peripheral touch cells located to the right of the center touch cell are summed to generate right-direction data for the center touch cell, and the plurality of peripheral touch cells adjacent to the center touch cell. Sum values of a plurality of peripheral touch cells located above the center touch cell to generate upward data for the center touch cell, and among the plurality of peripheral touch cells adjacent to the center touch cell. A second stage of generating the downward data for the central touch cell by summing the values of a plurality of peripheral touch cells located below the; .;
The moving direction of the center touch cell in the horizontal direction is determined based on the polarity comparison between the left data and the right data, and the vertical direction of the center touch cell is based on the polarity comparison of the upper data and the lower data. A third step of determining a moving direction to
A fourth step of determining the final moving direction of the center touch cell based on the moving direction in the horizontal direction and the vertical direction of the center touch cell;
A fifth step of determining a final moving direction of each of the remaining touch cells by performing the first to fourth steps with respect to each of the remaining touch cells of the touch area;
And a sixth step of determining a final moving direction of the touch area based on the final moving direction of each touch cell included in the touch area. The method of claim 2,
The left-direction data of the center touch cell includes a value of a peripheral touch cell positioned diagonally on the upper left side of the center touch cell, a value of a peripheral touch cell positioned immediately to the left of the center touch cell, and a lower left side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally;
The right-direction data of the center touch cell includes a tea value of a peripheral touch cell positioned at a diagonal of the right upper side of the center touch cell, a tea value of a peripheral touch cell located immediately to the right of the center touch cell, and a immediately lower right side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally;
The upward direction data of the center touch cell may include a tea value of a peripheral touch cell positioned at an upper left diagonal line of the center touch cell, a tea value of a peripheral touch cell located immediately above the center touch cell, and a right upper side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally;
The downward data of the center touch cell includes a value of a peripheral touch cell positioned at a lower left diagonal line of the center touch cell, a value of a peripheral touch cell positioned directly below the center touch cell, and a directly lower right side of the center touch cell. Touch display device, characterized in that the sum of the difference between the distance of the adjacent touch cell on the diagonal. The method of claim 2,
In the third step, the directional determination unit,
If the left data and the right data in the current frame have the same polarity, it is determined that the center touch cell does not move in the horizontal direction in the current frame;
If the left direction data and the right direction data in the current frame exhibit opposite polarity, determine that the center touch cell in the current frame is horizontally moved in the direction indicated by the data of the negative polarity;
Determining that the center touch cell does not move vertically in the current frame when the upper direction data and the lower direction data in the current frame have the same polarity; And,
If the upper direction data and the lower direction data in the current frame exhibits the opposite polarity, the touch display, characterized in that the center touch cell in the current frame is determined to move vertically in the direction indicated by the negative data Device. The method of claim 2,
In the sixth step, the directional determination unit,
Summing all the horizontal moving components included in the final moving directions of all the touch cells of the touch area, and determining the moving direction of the touch area in the horizontal direction based on the summed value;
Summing all the vertical movement components included in the final moving directions of all the touch cells of the touch area, and determining the moving direction of the touch area in the vertical direction based on the summed value; And,
And a final moving direction of the touch area is determined based on the moving direction in the horizontal direction and the vertical direction of the touch area. In the method of determining the movement direction of the touch area in the touch display device comprising m touch sensors (m is a natural number greater than 1) formed in the touch panel,
Generating m sensing data using m sensing signals provided from the m touch sensors every frame;
Analyzing the m pieces of sensing data every frame to determine a touch area for each frame;
Generating m difference values by subtracting m sensed data in a previous frame and m sensed data in a current frame from corresponding values; And,
The touch area in each frame is divided into a plurality of touch cells, and the direction of each touch cell in each frame is determined based on the value of the touch cells and the value of the touch cells located around the touch cell. The directionality of the touch area in every frame is determined based on the directionality with respect to each of them. And a step (D) of determining which direction it has moved. The method according to claim 6,
The step D,
Selecting any one of a plurality of touch cells included in the touch area in the current frame and defining the selected touch cell as a center touch cell;
Among the plurality of peripheral touch cells adjacent to the center touch cell, the values of the plurality of peripheral touch cells located to the left of the center touch cell are summed to generate left-direction data for the center touch cell, and the adjacent touch cells are adjacent to the center touch cell. Among the plurality of peripheral touch cells, the values of the plurality of peripheral touch cells located to the right of the center touch cell are summed to generate right-direction data for the center touch cell, and the plurality of peripheral touch cells adjacent to the center touch cell. Sum values of a plurality of peripheral touch cells located above the center touch cell to generate upward data for the center touch cell, and among the plurality of peripheral touch cells adjacent to the center touch cell. Generating a downward direction data for the center touch cell by summing the values of the plurality of peripheral touch cells located at the lower side of the second touch cell;
The moving direction of the center touch cell in the horizontal direction is determined based on the polarity comparison between the left data and the right data, and the vertical direction of the center touch cell is based on the polarity comparison of the upper data and the lower data. Determining the moving direction to the step D-3;
Determining a final movement direction of the center touch cell based on the movement direction in the horizontal direction and the vertical direction of the center touch cell;
Performing step D-1 to step D-4 on each of the remaining touch cells of the touch area to determine a final moving direction for each of the remaining touch cells;
And determining the final moving direction of the touch area on the basis of the final moving direction of each touch cell included in the touch area. The method of claim 7, wherein
The left-direction data of the center touch cell includes a value of a peripheral touch cell positioned diagonally on the upper left side of the center touch cell, a value of a peripheral touch cell positioned immediately to the left of the center touch cell, and a directly lower left side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally;
The right-direction data of the center touch cell includes a tea value of a peripheral touch cell positioned at a diagonal of the right upper side of the center touch cell, a tea value of a peripheral touch cell located immediately to the right of the center touch cell, and a immediately lower right side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally;
The upward direction data of the center touch cell may include a tea value of a peripheral touch cell positioned at an upper left diagonal line of the center touch cell, a tea value of a peripheral touch cell located immediately above the center touch cell, and a right upper side of the center touch cell. It means the sum of the tea values of the surrounding touch cell located diagonally;
The downward data of the center touch cell includes a value of a peripheral touch cell positioned at a lower left diagonal line of the center touch cell, a value of a peripheral touch cell positioned directly below the center touch cell, and a directly lower right side of the center touch cell. A method of calculating the directionality of a touch display device, characterized in that the sum of the difference between the distances of the adjacent touch cells. The method of claim 7, wherein
In step D-3,
If the left data and the right data in the current frame have the same polarity, it is determined that the center touch cell does not move in the horizontal direction in the current frame;
If the left direction data and the right direction data in the current frame exhibit opposite polarity, determine that the center touch cell in the current frame is horizontally moved in the direction indicated by the data of the negative polarity;
Determining that the center touch cell does not move vertically in the current frame when the upper direction data and the lower direction data in the current frame have the same polarity; And,
If the upper direction data and the lower direction data in the current frame exhibits the opposite polarity, the touch display, characterized in that the center touch cell in the current frame is determined to move vertically in the direction indicated by the negative data Method for calculating touch area directionality of a device. The method of claim 7, wherein
In step D-6,
Summing all the horizontal moving components included in the final moving directions of all the touch cells of the touch area, and determining the moving direction of the touch area in the horizontal direction based on the summed value;
Summing all the vertical movement components included in the final moving directions of all the touch cells of the touch area, and determining the moving direction of the touch area in the vertical direction based on the summed value; And,
And a final movement direction of the touch area is determined based on the movement direction in the horizontal direction and the vertical direction of the touch area.

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