KR20150077159A - Touch Display Device Having Function of Mouse And Method Of Driving The Same - Google Patents

Abstract

The present invention provides a touch display device having a mouse function. The touch display device includes: a display panel displaying an image; the touch panel which is arranged on a front side of the display panel and includes a display area, a left mouse area and a right mouse area which cover the display area; a main touch part including a plurality of first transmission lines and a plurality of first reception lines which are formed on the display area; a first subsidiary touch part including a plurality of second transmission lines and a plurality of second reception lines which are formed on the left mouse area; and a second subsidiary touch part including a plurality of third transmission lines and a plurality of third reception lines which are formed on the right mouse area. The first subsidiary touch part and the second subsidiary touch part are used to understand a command applied to a cursor displayed on the display area.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a touch display device having a mouse function,

The present invention relates to a touch display device, and more particularly to a touch display device having a mouse function by forming an auxiliary touch part in a non-display area of a touch panel and a driving method thereof.

In view of the information age, the display field has also been rapidly developed. As a flat panel display device (FPD) having the advantages of thinning, light weight, and low power consumption in response to the information age, ), A plasma display panel device (PDP), an organic light emitting diode (OLED) display device, and a field emission display device (FED) cathode ray tube (CRT).

In recent years, a touch display device, which is a display device having a touch panel on a display panel, is well-known.

The touch display device, which is also referred to as a touch screen, is used as an output means for displaying an image, and is used as input means for inputting a user's command by touching a specific portion of the displayed image. Depending on the position information detection method, it can be classified into a resistance film type, a capacitance type, an infrared type, and an ultrasonic type.

That is, when the user touches the touch panel while viewing an image displayed on the display panel, the touch panel detects the position information of the touch portion and compares the detected position information with the position information of the image to recognize the user's command .

Such a touch display device can be manufactured such that a separate touch panel is attached to the display panel or the touch panel is formed on the substrate of the display panel and integrated.

On the other hand, the capacitive touch device includes a mutual capacitance type in which a transmission wiring and a reception wiring are formed independently and a change in capacitance between a transmission wiring and a reception wiring due to a touch is detected, And a self capacitance type in which a voltage is applied to the touch electrode and a change in capacitance of the touch electrode due to a touch is detected.

Among them, the mutual capacitance type touch display device will be described with reference to the drawings.

1 is a view showing a conventional touch display apparatus.

1, the conventional touch display device 10 includes a display panel (not shown) for displaying an image using a plurality of pixels, a display panel (not shown) disposed in front of the display panel, And a touch panel 20.

The touch panel 20 includes a display area DA directly used for image display and a non-display area NDA at the upper and lower portions of the display area DA. The non-display area NDA is also referred to as a bezel area It is called.

A plurality of transmission lines 30 and a plurality of reception lines 32 for sensing touch are formed in the display area DA of the touch panel 20 and a non- A simple input means 40 such as a button for inputting a command in an OFF operation is formed.

A plurality of transmission wirings 30 and a plurality of reception wirings 32 cross each other with an insulating layer therebetween to form a plurality of capacitors. The plurality of transmission wirings 30 and the plurality of reception wirings 32 are touch- When a finger of a user approaches a specific point in a state where a voltage and a touch sensing voltage are applied, the capacitance of the capacitor at the corresponding point is varied, and the variation of such capacitance appears as a variation of the touch sensing voltage.

Accordingly, the coordinate of the touch point can be calculated by successively applying the touch driving voltage and detecting the variation of the touch sensing voltage sequentially.

However, in the touch display device 10, since the display area DA of the touch panel 20 is touched with a finger to input a command, there is a problem that the finger hides a part of the displayed image.

As the size of a display device of a mobile terminal such as a smart phone increases, a user wants to use the mobile terminal in an environment such as a personal computer, but the touch display device 10 has a cursor, There is a problem in that it does not have the function of a mouse for moving the mouse.

It is an object of the present invention to provide a touch display device having a mouse function and a driving method therefor by forming an auxiliary touch portion in a non-display region and calculating a moving direction or the like.

Another object of the present invention is to provide a touch display device and a method of driving the touch display device, in which the manufacturing cost is reduced by forming the main touch portion of the display region and the auxiliary touch portion of the non-display region in the same process.

In order to solve the above problems, the present invention provides a display device comprising: a display panel for displaying an image; A touch panel disposed in front of the display panel and including a display area and a left mouse area and a right mouse area surrounding the display area; A main touch unit including a plurality of first transmission lines and a plurality of first reception lines formed in the display area; A first auxiliary touch unit including a plurality of second transmission lines and a plurality of second reception lines formed in the left mouse area; And a second auxiliary touch part including a plurality of third transmission lines and a plurality of third reception lines formed in the right mouse area, wherein the first and second auxiliary touch parts are applied to a cursor displayed on the display area A touch display device having a mouse function used for grasping an instruction is provided.

The touch display device having the mouse function outputs the first to third touch driving voltages to the first to third transmission wirings respectively and outputs the first to third touch driving voltages to the first to third transmission wirings, A touch driver configured to receive the first to third touch sensing voltages and to calculate coordinate information of touch points from the first to third touch driving voltages and the first to third touch sense voltages; And a central processing unit receiving coordinate information of the touch point.

Also, the touch driver may control the first touch driving voltage and the first touch sensing voltage, the second touch driving voltage, the second touch sensing voltage, the third touch driving voltage, A mux selecting a pair of third touch sense voltages; A sensing unit for calculating voltage variation data from the selected pair transmitted through the mux; And a control unit for calculating coordinate information of the touch point from the voltage variation data transmitted from the sensing unit and transmitting coordinate information of the calculated touch point to the central processing unit.

In addition, one frame, which is a unit time interval for touch detection, is divided into first, second, and third time intervals, and the touch driver applies the first touch driving voltage and the first touch sensing Calculates coordinate information of the touch point of the display area from the voltage and calculates coordinate information of the touch point of the left mouse area from the second touch drive voltage and the second touch sensing voltage during the second time interval , Coordinate information of the touch point of the right mouse area can be calculated from the third touch driving voltage and the third touch sensing voltage during the third time period.

Also, the touch driver may select one of a touch mode and a mouse mode according to a mode command of the central processing unit, and may select one of the first touch driving voltage and the first touch sensing voltage during a touch time interval corresponding to the touch mode Calculating coordinate information of the touch point in the display area and calculating coordinate information of the touch point of the left mouse area from the second touch drive voltage and the second touch sensing voltage during a mouse time interval corresponding to the mouse mode And calculate coordinate information of the touch point of the right mouse area from the third touch drive voltage and the third touch sense voltage.

The mouse time interval is divided into first and second mouse time intervals for detecting touches of the first and second auxiliary touch units, respectively, and the first and second auxiliary touch units are time- Can be driven.

In addition, the touch driver may calculate voltage variation data from the second touch sense voltage or the third touch sense voltage, and determine whether the first touch point at which the maximum force is applied and the minimum force A second touch point may be calculated, and a vector from the second touch point to the first touch point may be set in a moving direction of the cursor.

The touch driver calculates a first touch point at which a maximum force is applied during a first frame, calculates a second touch point at which a maximum force is applied during a second frame after the first frame, The vector pointing from the touch point to the second touch point can be set to the moving direction of the cursor.

It is preferable that the second touch sensing voltage or the third touch sensing voltage has a first voltage variation distribution at a first timing and that there is no voltage variation during a predetermined time difference, If the second voltage variation amount distribution has the same distribution as the variation amount distribution, the touch driver can determine that the touch point is a double click on the same touch point.

The present invention has an effect of realizing a mouse function by forming the auxiliary touch part in the non-display area and calculating the moving direction and the like.

The present invention has the effect of reducing the manufacturing cost by forming the main touch portion of the display area and the auxiliary touch portion of the non-display area in the same process.

1 is a view showing a conventional touch display device.
2 is a diagram illustrating a touch display device having a mouse function according to an embodiment of the present invention.
3 is a view illustrating a driving unit of a touch display device having a mouse function according to an embodiment of the present invention.
4A and 4B are diagrams for explaining a time division mode and a mode division driving method of a touch display device having a mouse function according to an embodiment of the present invention, respectively.
5A to 5D are diagrams for explaining a moving direction calculating method of a cursor of a touch display device having a mouse function according to the embodiment of the present invention.
6 is a diagram for explaining a double-click calculation method of a touch display device having a mouse function according to the embodiment of the present invention.

Hereinafter, a touch display device having a mouse function and a driving method thereof according to the present invention will be described with reference to the accompanying drawings.

2 is a diagram illustrating a touch display device having a mouse function according to an embodiment of the present invention.

2, the touch display device 110 having a mouse function according to the embodiment of the present invention includes a display panel (not shown) for displaying an image using a plurality of pixels, a display panel And a touch panel 120 for sensing the touch and calculating coordinates.

The display panel may include a flat panel display (FPD) such as a liquid crystal display (LCD), a plasma display (PDP), an organic light emitting diode (OLED) display, and a field emission display (FED).

The touch panel 120 includes a display area DA directly used for image display and upper and lower non-display areas NDA surrounding the display area DA, and a non-display area NDA, also referred to as a bezel area, (NDA) includes a left mouse area (LMA) and a right mouse area (RMA) arranged on the left and right of simple input means 140 such as a button for inputting an instruction in an on-off operation.

A plurality of first transmission wirings 130 and a plurality of first reception wirings 132 are formed in the display area DA of the touch panel 120 and a plurality of first reception wirings 132 are formed in the left mouse area LMA of the non- A plurality of second transmission lines 142 and a plurality of second reception lines 144 are formed in the non-display area NDA and a plurality of third transmission lines 146 and a plurality of third transmission lines 142 are formed in the right mouse area RMA of the non- A receiving wiring 148 is formed.

A plurality of first transmission lines 130 and a plurality of first reception lines 132, a plurality of second transmission lines 142 and a plurality of second reception lines 144, and a plurality of third transmission lines 146 And the plurality of third receiving wirings 148 cross each other with an insulating layer therebetween to form a plurality of capacitors.

The plurality of first transmission lines 130 and the plurality of first reception lines 132 are used to calculate touch coordinates by sensing the touch of the display area DA, And the plurality of third reception wiring 144 and the plurality of third transmission wiring 146 and the plurality of third reception wiring 148 detect the touch of the left mouse area LMA and the right mouse area RMA And is used to implement the mouse function.

A plurality of second transmission wiring 142 and a plurality of second reception wiring 144 and a plurality of third transmission wiring 146 and a plurality of third reception wiring 148 are connected to a plurality of first transmission wirings The first receiving wiring 132 may be formed in a smaller number than the number of the first receiving wiring 132 and may be less than or equal to 3X3 (= 9 touch points) or less than 20X20 (= 40 touch points) have.

The plurality of first transmission lines 130 and the plurality of first reception lines 132 of the display area DA constitute a main touch part and the plurality of second transmission lines 142 of the left mouse area LMA And the plurality of second reception wiring 144 constitute a first auxiliary touch portion and a plurality of third transmission wiring 146 and a plurality of third reception wiring 148 of the right mouse region RMA constitute a second auxiliary touch .

That is, the main touch unit detects the touch of the display area DA by a finger or the like and is used for grasping an instruction displayed on the display area DA, and the first and second auxiliary touch units are arranged in the non-display area NDA A double click, a left click, a right click, a wheel, and the like for detecting a touch and applying it to a cursor 134 displayed in the display area DA.

Therefore, the user can indirectly input the command by directly entering the command in contact with the display area DA, or by moving and clicking the cursor in contact with the non-display area NDA, It is possible to input a command without selecting an image displayed on the screen.

A plurality of first transmission lines 130 and a plurality of first reception lines 132, a plurality of second transmission lines 142 and a plurality of second reception lines 144, And the third reception wiring 148 and the third reception wiring 148 are formed on the same substrate through the same process, the manufacturing cost can be reduced.

2, the main touch unit and the first and second auxiliary touch units are of the mutual capacitive type. However, in another embodiment, the main touch unit and the first and second auxiliary touch units may be of the self-capacitance type, , An infrared ray system, and an ultrasonic wave system.

The main touch portion and the first and second auxiliary touch portions may be formed on the same or different surfaces of a substrate such as a glass or a film.

Although not shown, the touch display device 110 having a mouse function according to the embodiment of the present invention further includes a driving unit for driving the display panel and the touch panel 120, And a touch driving unit for driving the touch panel 120. The touch driving unit includes an integrated circuit (IC) for commonly driving the main touch unit and the first and second auxiliary touch units And the main touch unit and the first and second auxiliary touch units can be driven by time division or mode division.

The touch driver of the touch display device 110 having such a mouse function will be described with reference to the drawings.

FIG. 3 is a block diagram illustrating a driving unit of a touch display device having a mouse function according to an embodiment of the present invention. Referring to FIG.

3, the touch display device 110 having a mouse function according to an embodiment of the present invention includes a touch driver 160 for driving the touch panel 120, a touch panel 120 for driving the touch panel 120, (Not shown).

The touch driver 160 outputs a plurality of touch driving voltages VTx1, VTx2 and VTx3 to the touch panel 120 and receives a plurality of touch sensing voltages VRx1, VRx2 and VRx3 from the touch panel 120, The coordinate information PI of the touch point is calculated from the plurality of touch drive voltages VTx1, VTx2 and VTx3 and the plurality of touch sense voltages VRx1, VRx2 and VRx3, And receives a mode command (MC) selectively from the central processing unit 170.

To this end, the touch driver 160 includes a mux 162, a sensing unit 164, and a control unit 166.

The multiplexer 162 multiplexes the first transmission lines 130 and the first reception lines 132 received from the sensing unit 164 or the control unit 166 according to the selection signal SEL, The second touch driving voltage VTx1 and the second touch sensing voltage VRx1 transmitted from the plurality of second transmission lines 142 and the plurality of second receiving lines 144, The touch sensing voltage VRx2 and the third touch driving voltage VTx3 and the third touch sensing voltage VRx3 received from the plurality of third transmission wiring 146 and the plurality of third receiving wiring 148 And transmits the selected signal to the sensing unit 164.

The sensing unit 164 receives the first touch drive voltage VTx1 and the first touch sense voltage VRx1, the second touch drive voltage VTx2, and the second touch sense voltage VRx2, The third touch driving voltage VTx3, and the third touch sensing voltage VRx3, and transfers the calculated voltage variation data to the control unit 166. [0156]

The control unit 166 calculates the coordinate information PI of the touch point from the voltage variation data transmitted from the sensing unit 164 and transmits the coordinate information PI of the calculated touch point to the central processing unit 170. [

The control unit 166 sequentially outputs a selection signal for receiving the next pair of the touch driving voltage and the touch sensing voltage in accordance with the mode command MC received from the central processing unit 170, (SEL) to the MUX 162.

Here, when the operation of the touch display device 110 is started by power application, since there is no selected pair of touch driving voltage and touch sensing voltage, the sensing part 164 generates a pair of touch driving voltage and touch sensing voltage And may transmit the generated selection signal SEL to the MUX 162. [

The central processing unit 170 grasps and executes the command of the corresponding display panel from the touch point coordinate information PI of the main touch part of the display area DA and controls the left mouse area of the non-display area NDA Click, right click, and wheel) from the coordinate information (PI) of the touch point to the first and second auxiliary touch parts of the right mouse area (LMA) and the right mouse area (RMA) .

When the touch display apparatus 110 is driven by mode division, the central processing unit 170 transmits the mode command MC for the specific mode to the control unit 166, And to transmit the selection signal SEL to the mux 162 for selecting the touch sensing voltage.

The time division mode and mode division driving method of the touch display device 110 having a mouse function according to the embodiment of the present invention will now be described with reference to the drawings.

FIGS. 4A and 4B are views for explaining a time division mode and a mode division driving method of a touch display device having a mouse function according to an embodiment of the present invention, and will be described with reference to FIGS. 2 and 3. FIG.

As shown in FIG. 4A, one frame F, which is a unit time period for touch detection, is divided into first, second and third time intervals TP1, TP2 and TP3, The first auxiliary touch unit, and the second auxiliary touch unit are sequentially detected during the first, second and third time intervals TP1, TP2 and TP3, respectively, It can be driven by time division.

That is, the coordinate information PI of the touch point of the display area DA is calculated from the first touch driving voltage VTx1 and the first touch sensing voltage VRx1 during the first time period TP1, The coordinate information PI of the touch point of the left mouse area LMA of the non-display area NDA is calculated from the second touch drive voltage VTx2 and the second touch sense voltage VRx2 during the third touch period TP2, The coordinate information PI of the touch point of the right mouse area RMA in the non-display area NDA can be calculated from the third touch drive voltage VTx3 and the third touch sense voltage VRx3 during the time period TP3 have.

At this time, the second and third time intervals TP2 and TP3 may be shorter than the first time interval TP1, respectively.

4B, one of the touch mode and the mouse mode is selected according to the mode command MC of the central processing unit 170, and the touch time interval TPT corresponding to the touch mode and the mouse mode The touch display device 110 having a mouse function can be driven by mode division by detecting touches of the main touch portion and touches of the first and second auxiliary touch portions during the mouse time interval TPM.

That is, the coordinate information PI of the touch point of the display area DA is calculated from the first touch driving voltage VTx1 and the first touch sensing voltage VRx1 during the touch time interval TPT, and the mouse time interval TPM The coordinate information PI of the touch point of the left mouse area LMA of the non-display area NDA is calculated from the second touch drive voltage VTx2 and the second touch sense voltage VRx2, The coordinate information PI of the touch point of the right mouse area RMA of the non-display area NDA can be calculated from the third touch sense voltage VRx3 and the third touch sense voltage VRx3.

At this time, the touch time interval TPT and the mouse time interval TPM may include a plurality of frames F until a new mode command MC is inputted.

The mouse time interval TPM can be divided into first and second mouse time periods in which the touches of the first and second auxiliary touch units can be respectively detected. In this case, Can be time-divisionally driven within the interval (TPM).

A method of calculating the moving direction and double-click of the cursor on the touch display device 110 having such a mouse function will be described with reference to the drawings.

5A to 5D are diagrams for explaining a moving direction calculating method of a cursor of a touch display device having a mouse function according to the embodiment of the present invention. FIG. 2 is a diagram for explaining a double-click calculation method of the apparatus, and FIG. 3 and FIG. 3 together. FIG.

5A to 5D, the contact portion between the user's finger and the left mouse region (LMA) or the right mouse region (RMA) of the touch panel 120 has a touch point at which the maximum force Fmax is applied, And a touch point at which a force Fmin is applied.

That is, the second touch drive voltage VTx2 and the second touch sense voltage VRx2 of the plurality of second transmission lines 142 and the plurality of second reception lines 144 of the left mouse area LMA, The voltage variation data is calculated from the third touch transmission drive voltage 146 of the RMA and the third touch drive voltage VTx3 and the third touch sense voltage VRx3 of the plurality of third reception wiring 148, It is possible to calculate the touch point at which the maximum force Fmax is applied and the touch point at which the minimum force Fmin is applied from the voltage fluctuation data at which the maximum force Fmax is applied and the maximum force Fmax is applied from the touch point at which the minimum force Fmin is applied You can define a vector that points to a point where you lose touch points in the direction of cursor movement.

5A, in the case of the touch state where the maximum force Fmax and the minimum force Fmax are applied to the fifteenth touch point P15 and the thirty-third touch point P33, A vector from the 33rd touch point P33 to the 15th touch point P15 having the maximum variation amount Dmax and the minimum variation amount Dmin at the 15th touch point P15 and the 33th touch point P33, The direction of movement of the cursor can be determined.

5B, in the case of the touch state in which the maximum force Fmax and the minimum force Fmax are applied to the eleventh touch point P11 and the thirty-third touch point P33, The vector from the 33rd touch point P33 to the 11th touch point P11 is set to be the maximum value Dmax and the minimum variation amount Dmin at the 11th touch point P11 and the 33rd touch point P33, As shown in FIG. 5C, in the case of the touch state in which the maximum force Fmax and the minimum force Fmax are applied to the 51st touch point P51 and the 33rd touch point P33 , The touch sensing voltage has the maximum variation amount Dmax and the minimum variation amount Dmin at the 51st touch point P51 and the 33rd touch point P33 respectively and from the 33rd touch point P33 to the 51st touch point P51 As shown in FIG. 5D, the vector pointing to the 55th touch point P55 and the 33st touch point P33 can be determined as the direction of movement of the cursor. The touch sensing voltage is set to the maximum variation Dmax and the minimum variation Dmin at the 55th touch point P55 and the 33rd touch point P33 respectively in the case of the touch state in which the deflection Fmax and the minimum force Fmax are applied, And a vector from the 33rd touch point P33 to the 55th touch point P55 can be determined as the movement direction of the cursor.

Accordingly, the user can move the cursor by adding a force in a specific direction of up, down, left, and right in a state in which the finger touches the left mouse area (LMA) or the right mouse area (RMA).

5A to 5D, the movement direction of the cursor is determined from the touch point at which the maximum force and the minimum force are applied in one frame. However, in another embodiment, the cursor is moved from the touch point, May be determined.

That is, a first touch point at which a maximum force is applied during the first frame is calculated, a second touch point at which a maximum force is applied during a second frame after the first frame is calculated, The vector pointing to the point can be determined as the moving direction of the cursor.

Thus, the user can move the cursor by moving the finger to the first touch point and then to the second touch point, in which case the second frame is not only the frame immediately after the first frame but also one of the following multiple frames Lt; / RTI >

6, the user touches the finger of the user and the left mouse area (LMA) or the right mouse area (RMA) of the touch panel 120 includes a plurality of touch points, Then, if the contact portion includes the same number of touch points, it can be set by double clicking.

Specifically, the touch sensing voltage at the first timing (T1) has a first distribution having the variation (D) at the 32nd, 33rd, 42nd and 43st touch points, and the touch sensing voltage The touch sensing voltage has a second distribution without the variation D and the variation D at the 32nd, 33rd, 42nd, and 43st touch points at the second timing T2 after a predetermined time difference? Having the second distribution having the same touch point can be set by double-clicking on the same touch point.

Therefore, when the cursor is positioned at a specific point, the user can double click on the specific point by sequentially touching the first touch point with a predetermined time difference T.

Although not shown, a command such as a wheel can be implemented in a manner similar to the movement of a cursor, and commands such as left click and right click can be implemented similarly to a double click.

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 invention as defined in the appended claims. It can be understood that

110: touch display device 120: touch panel
DA: display area NDA: non-display area
LMA: left mouse area RMA: right mouse area

Claims (9)

A display panel for displaying an image;
A touch panel disposed in front of the display panel and including a display area and a left mouse area and a right mouse area surrounding the display area;
A main touch unit including a plurality of first transmission lines and a plurality of first reception lines formed in the display area;
A first auxiliary touch unit including a plurality of second transmission lines and a plurality of second reception lines formed in the left mouse area;
A second auxiliary touch part including a plurality of third transmission lines and a plurality of third reception lines formed in the right mouse area,
Lt; / RTI >
Wherein the first and second auxiliary touch units are used for grasping a command applied to a cursor displayed on the display area.
The method according to claim 1,
The first to third touch driving voltages are respectively output to the plurality of first to third transmission lines, the first to third touch sensing voltages are inputted respectively from the plurality of first to third receiving lines, A touch driver for calculating coordinate information of a touch point from the first to third touch drive voltages and the first to third touch sense voltages;
A central processing unit for receiving coordinate information of the touch point,
The touch display device according to claim 1, further comprising:
3. The method of claim 2,
The touch-
The first touch driving voltage and the first touch sensing voltage, the second touch driving voltage and the second touch sensing voltage, the third touch driving voltage, and the third touch sensing voltage, A pair of muxes to choose;
A sensing unit for calculating voltage variation data from the selected pair transmitted through the mux;
A control unit for calculating coordinate information of the touch point from the voltage variation data transmitted from the sensing unit and transmitting coordinate information of the calculated touch point to the central processing unit,
And a mouse function.
3. The method of claim 2,
One frame, which is a unit time interval for touch detection, is divided into first, second and third time intervals,
The touch-
Calculating coordinate information of the touch point of the display area from the first touch driving voltage and the first touch sensing voltage during the first time period,
Calculating coordinate information of the touch point of the left mouse area from the second touch driving voltage and the second touch sensing voltage during the second time period,
And calculates coordinate information of the touch point of the right mouse area from the third touch drive voltage and the third touch sense voltage during the third time period.
3. The method of claim 2,
The touch-
Wherein the controller selects one of a touch mode and a mouse mode according to a mode command of the central processing unit,
Calculating coordinate information of the touch point in the display area from the first touch-driving voltage and the first touch-sensing voltage during a touch time interval corresponding to the touch mode,
Calculating coordinate information of the touch point of the left mouse area from the second touch-driving voltage and the second touch-sensing voltage during a mouse time interval corresponding to the mouse mode, And calculates coordinate information of the touch point of the right mouse region from the voltage.
6. The method of claim 5,
Wherein the mouse time interval is divided into first and second mouse time intervals for respectively detecting touches of the first and second auxiliary touch units,
Wherein the first and second auxiliary touch units have a mouse function that is time-divisionally driven within the mouse time interval.
3. The method of claim 2,
The touch-
The first touch point at which a maximum force is applied and the second touch point at which a minimum force is applied are calculated from the calculated voltage variation data from the second touch sense voltage or the third touch sense voltage And sets a vector from the second touch point to the first touch point in a moving direction of the cursor.
3. The method of claim 2,
The touch-
A first touch point at which a maximum force is applied during the first frame is calculated,
A second touch point at which a maximum force is applied during a second frame after the first frame is calculated,
And sets a vector from the first touch point to the second touch point in a moving direction of the cursor.
3. The method of claim 2,
Wherein the second touch sense voltage or the third touch sensation voltage has a first voltage variation amount distribution at a first timing and has no voltage variation amount for a predetermined time difference, and at the second timing after the time difference, If the second voltage variation amount distribution is the same as the second voltage variation amount distribution,
Wherein the touch driver has a mouse function to determine a double-click of the same touch point.

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