KR102146024B1 - Display device and method of drving the same - Google Patents

Abstract

The present invention relates to a display device and a driving method thereof, wherein the number of sensing pulses is increased or decreased according to whether a sensing pulse output period in which sensing pulses are output exceeds a preset touch sensing period. It includes a sensing unit.

Description

Display device and its driving method {DISPLAY DEVICE AND METHOD OF DRVING THE SAME}

The present invention relates to a display device, and more particularly, to a display device including a self-cap type touch panel and a driving method thereof.

The touch panel includes a liquid crystal display device (LCD), a plasma display panel device (PDP), an organic light emitting display device (OLED), and an electrophoretic display device (EPD). It is installed on a display device such as a Display Device), and is a type of input device that allows a user to input information by directly touching the screen with a finger or a pen while looking at the display device.

The touch panel may be manufactured independently of the panel constituting the display device and then attached to the top surface of the panel, or may be integrally formed with the panel.

For example, a touch panel is an in-cell type embedded in a pixel of a panel on which an image is displayed, an on-cell type formed on the panel, and an upper portion of the panel after being manufactured separately from the panel. It can be classified into an add-on type that adheres to.

A conventional display device in which a touch panel is formed includes a panel in which the touch panel is formed and a touch sensing unit for driving the touch panel.

Methods of driving the touch panel include a resistive method and a capacitive method, and the capacitive method may be further divided into a self-cap method and a mutual method.

Among these, in the conventional display device using the self-cap method, the touch electrode wiring is independently extracted from each touch electrode, and qxp = n in consideration of the number of horizontal and vertical touch electrodes. Two detectors are required.

Each of the sensors applies tens or more sensing pulses to the touch electrode 61 during a touch sensing period, and determines whether or not a corresponding touch electrode has been touched by analyzing a sensing signal received from the touch electrode.

In general, sensing of touch in the self cap method uses charging and discharging of a touch voltage. That is, the self-cap method detects whether a touch is made using a change in a voltage slope according to a change in capacitance (Cap) when a touch is made and when the touch is not made.

1 is an exemplary view showing a state in which a sensing pulse is normally output during a touch sensing period in a conventional display device in which a self-cap type touch panel is embedded. 2 is an exemplary view showing a state in which a sensing pulse is output even during an image output period in a conventional display device in which a self-cap type touch panel is embedded.

In the method of sensing by driving the touch electrode with current, the sensing time changes according to the size of the load of the touch electrode, and in particular, the sensing time changes according to the size of the capacitance of the touch electrode.

In addition, in the display device in which the touch panel is formed inside the panel constituting the display device, as shown in Figs. 1 and 2 (a), a touch sensing period (A) for sensing a touch and an image are output. The image output period (DP) for this is divided.

In this case, when the load of the touch electrode is large or the capacitance is large, the sensing pulses output an image beyond the touch sensing period (A), as shown in FIG. 1B. It may also be output in the image output period DP for.

That is, the sensing pulse output period B through which the sensing pulses are actually output may be formed within the image output period DP. In this case, determination of whether or not a touch may be performed normally, and ghosts may be generated in an image output through the panel.

In order to prevent the above-described phenomena, the sensing pulse output period (B) in which the sensing pulses are actually output is included in the touch sensing period (A), as shown in FIG. 2B. Display devices are being manufactured. That is, the sensing pulse output period (B) is formed to be smaller than the touch sensing period (A), and a period of the touch sensing period (A) excluding the sensing pulse output period (B) is a sensing margin period ( It is called C).

To explain further, since the sensing pulse output period (B) in which sensing pulses for sensing a touch are actually output must exist within the touch sensing period (A), as shown in FIG. 2(b), The sensing pulse output period (B) is set to be smaller than the touch sensing period (A).

In particular, there are variations between capacitances or loads of the touch electrodes, and in consideration of these variations, the touch margin C is increasing. That is, the touch clearance period (C) is increasing so that the sensing pulse output periods (B) for all the touch electrodes constituting one touch panel can exist within the touch sensing period (A).

However, when the touch clearance period (C) increases, the sensing pulse output period (B) in which the sensing pulses are output to the touch electrodes decreases, so the number of sensing pulses decreases, thereby reducing the touch sensitivity. Is done.

To further explain, in order to maximize the touch sensitivity of the first touch panel, as shown in FIG. 2, when the touch margin C is minimized, the determination of whether or not the first touch panel is touched It can be done normally.

However, when the touch clearance period (C) is applied as it is to the second touch panel in which the load of the touch electrode is larger than the first touch panel, as shown in FIG. 1, the sensing pulse output period (B) is It may be formed in the image output period beyond the touch free period (C). In this case, the digital value converted from the sensed analog signal has an abnormal waveform. Accordingly, determination of whether or not the second touch panel is touched may not be performed normally, and ghosts may be generated in an image output from a panel in which the second touch panel is embedded.

That is, in the related art, the touch clearance period (C) having the same size was applied to all touch panels.

Therefore, in consideration of the touch panel having the largest touch electrode load, if the touch clearance period C is set to be large, the time for sensing a touch is shortened, so that touch sensitivity can be reduced. In addition, in consideration of a touch panel having a touch electrode load below a certain level, when the touch clearance period (C) is set to be small, determination of whether a touch panel having a touch electrode load larger than a certain level is touched is normally performed. Either not, or ghosting may occur.

The present invention has been proposed to solve the above-described problem, and the number of sensing pulses may be increased or decreased depending on whether the sensing pulse output period in which the sensing pulses are output exceeds a preset touch sensing period. It is a technical problem to provide a display device and a method of driving the same.

The display device according to the present invention for achieving the above-described technical problem includes a panel in which a self-cap type touch panel formed of a plurality of touch electrodes is embedded; And a touch sensing unit that increases or decreases the number of sensing pulses according to whether the sensing pulse output period in which the sensing pulses are output exceeds a preset touch sensing period.

The method for driving a display device according to the present invention for achieving the above-described technical problem includes the steps of determining whether a sensing pulse output period in which sensing pulses are output exceeds a preset touch sensing period; If the sensing pulse output period does not exceed the touch sensing period, increasing the number of sensing pulses; And if the sensing pulse output period exceeds the touch sensing period, reducing the number of sensing pulses.

According to the present invention, irrespective of the variation in the capacitance of the touch electrodes between the touch panels, in all display devices using the touch panel, the sensing pulse output period (B) is formed within the touch sensing period (A). I can.

Accordingly, sensing signals from all touch panels are maximized, and touch sensitivity may be improved.

1 is an exemplary view showing a state in which a sensing pulse is normally output during a touch sensing period in a conventional display device in which a self-cap type touch panel is embedded.
2 is an exemplary view showing a state in which a sensing pulse is output even during an image output period in a conventional display device in which a self-cap type touch panel is embedded.
3 is an exemplary view schematically showing a configuration of a display device according to the present invention.
4 is an internal configuration diagram of a touch sensing unit applied to a display device according to an embodiment of the present invention.
5 is a flowchart of an embodiment of a method for driving a display device according to the present invention.
6 is an exemplary diagram for explaining a case in which a sensing pulse output period is included within a touch sensing period in a method of driving a display device according to the present invention.
7 is an exemplary view illustrating a case in which a sensing pulse output period exceeds a touch sensing period in a method of driving a display device according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, for convenience of description, a liquid crystal display will be described as an example of the present invention, but the present invention is not limited thereto. That is, the present invention can be applied to various display devices capable of displaying an image using a common electrode and a common voltage.

3 is an exemplary view schematically showing the configuration of a display device according to the present invention, and FIG. 4 is an internal configuration diagram of a touch sensing unit applied to the display device according to the present invention.

The present invention relates to a display device in which an in-cell touch panel is formed. The in-cell touch panel is embedded in a panel constituting the display device.

Methods of driving the in-cell touch panel include a resistive type and a capacitive type.

The capacitive method may be further divided into a self-cap method and a mutual method, among which, the present invention uses a self-cap method.

That is, the present invention relates to a display device using an in-cell touch panel and a self-cap method, and a driving method thereof.

The display device according to the present invention includes a self-cap type touch panel 500 formed of a plurality of touch electrodes 510 as shown in FIG. 3, and is The panel 100 on which the defined pixels are formed, and the touch noise values of all the touch electrodes 510 constituting the touch panel 500 are calculated, and the values of the touch noise are used in a charger (not shown). An image signal is output to the touch sensing unit 600 and the data line formed in the panel 100 to determine whether the noise caused by the touch panel 500 affects the determination of whether or not the touch panel 500 is touched. A driver 400 for outputting a scan signal to a gate line and a common voltage to the touch electrodes is included.

First, the panel 100 performs a function of outputting an image, and the self-cap type touch panel 500 formed of a plurality of touch electrodes 510 is embedded in the panel 100.

The panel 100 may vary according to the type of the display device. In particular, when the display device is a liquid crystal display (LCD), it may be a liquid crystal panel in which a liquid crystal layer is formed between two glass substrates. have.

In this case, on the lower glass substrate of the panel 100, a plurality of data lines, a plurality of gate lines crossing the data lines, a plurality of thin films formed at intersections of the data lines and the gate lines Transistors (TFT: Thin Film Transistors), a plurality of pixel electrodes for charging a data voltage to the pixel, and a touch electrode 510 for driving a liquid crystal charged in the liquid crystal layer together with the pixel electrode are formed. In the panel 100, the pixels are arranged in a matrix form by an intersection structure of the data lines and the gate lines.

A black matrix (BM) and a color filter are formed on the upper glass substrate of the panel 100.

The present invention relates to a touch panel-embedded display device in which a touch electrode 510 constituting the touch panel 500 is included in the panel 100 as described above.

Next, the touch panel 500 performs a function of detecting whether a user touches or not. In particular, the touch panel 500 applied to the present invention uses a capacitive method applying a self-cap method. Are doing. The touch panel 500 includes a plurality of touch electrodes 510 and a plurality of touch electrode wirings 520.

Each of the plurality of touch electrodes 510 may be formed over a plurality of pixels formed on the panel 100. The touch electrodes 510 perform a function of generating a sensing signal according to a sensing pulse transmitted from the touch sensing unit 600 during a touch sensing period, and together with the pixel electrode formed in each pixel during an image output period. It performs the function of driving liquid crystal.

Each of the plurality of touch electrode wirings 520 is connected to the touch electrode 510, and an end thereof is connected to the touch sensing unit 600.

As described above, the touch panel 500 applied to the present invention uses a capacitive method, and is embedded in the panel 100. That is, the touch electrode 510 of the touch panel 500 applied to the present invention performs a function of a common electrode for driving a liquid crystal together with the pixel electrode and a function as a medium for determining whether or not to touch.

Next, the driver 400 includes a gate driver for controlling signals input to the gate line, a data driver for controlling signals input to the data line, and a timing controller for controlling the gate driver and the data driver. It can be composed of. As shown in FIG. 4, the gate driver, the data driver, and the timing controller constituting the driver 400 may be configured as one integrated circuit (IC), but may be configured individually.

First, the timing controller receives timing signals such as a data enable signal and a dot clock from an external system and generates control signals for controlling operation timings of the data driver and the gate driver. In addition, the timing controller performs a function of rearranging input image data input from the external system and outputting the rearranged image data to the data driver.

The timing controller controls the data driver and the gate driver, as well as a control signal for controlling the input/output operation timing of the touch sensing unit 600, and the touch sensing unit receives either a common voltage or a touch voltage. Control signals to be applied to the touch electrode 510 may be generated and transmitted to the touch sensing unit 600.

The common voltage output to the touch electrode 510 may be generated by a common voltage generating unit and output through the driving unit 400, but the touch sensing unit 600 receiving the control signal from the driving unit 400 It can also be output through. In addition, the touch voltage may be output through the touch sensing unit 600 that has received the control signal from the driving unit 400, and output from the touch sensing unit 600 and then through the driving unit 400. It may be supplied to the touch electrode 510.

Second, the data driver converts the image data input from the timing controller into a data voltage, and supplies a data voltage for one horizontal line to the data lines for every horizontal period in which a scan pulse is supplied to the gate line. . That is, the data driver converts the image data into a data voltage using gamma voltages supplied from a gamma voltage generator (not shown) and outputs the converted image data to the data lines.

The data driver generates a sampling signal by shifting the source start pulse transmitted from the timing controller according to a source shift clock. In addition, the data driver latches the image data input according to the source shift clock according to the sampling signal, changes to the data voltage, and then the data voltage in units of horizontal lines in response to the source output enable signal. Is supplied to the data lines.

To this end, the data driver may include a shift register unit, a latch unit, a digital to analog conversion unit, and an output buffer.

Third, the gate driver sequentially supplies scan pulses to the gate lines using gate control signals generated by the timing controller. In response to the scan pulse, the thin film transistors TFT of the panel 100 are driven in units of horizontal lines of the panel.

Finally, the touch sensing unit 600 performs a function of supplying a sensing pulse to the touch electrodes during a touch sensing period during one frame period.

In particular, the touch sensing unit 600 performs a function of increasing or decreasing the number of sensing pulses according to whether the sensing pulse output period in which the sensing pulses are output exceeds a preset touch sensing period. do.

That is, the touch sensing unit 600, when the sensing pulse output period does not exceed the touch sensing period, increases the number of the sensing pulses, and when the sensing pulse output period exceeds the touch sensing period, sensing It performs the function of reducing the number of pulses.

For example, in an in-cell display device in which the in-cell touch panel is formed inside a panel constituting the display device, a touch sensing period for sensing a touch and an image output period for outputting an image are divided. In addition, in the self-cap method in which the touch electrode is driven with electric current or electric charge, the sensing time varies according to the size of the load of the touch electrode. The sensing pulse output period in which the pulse is actually output is changed. In this case, when the sensing pulse output period overlaps the image output period, an error may occur in determining whether a touch is present or a ghost may occur in the output image. Conversely, when the sensing pulse output period is set to be small, the touch sensitivity may decrease. That is, in the related art, since the sensing pulse output period is set equally in all display devices, an error may occur in determining whether to touch or not, depending on the characteristics of the touch panel formed in each display device, and ghosting. May occur, and the touch sensitivity may be deteriorated.

In order to solve the above problem, the touch sensing unit 600 applied to the display device according to the present invention, when the sensing pulse output period exceeds the touch sensing period, reduces the number of sensing pulses, The sensing pulse output period is included in the touch sensing period, and when the sensing pulse output period is smaller than the touch sensing period, the number of sensing pulses is increased, so that the sensing pulse output period becomes the touch sensing period. While included in the inside, the touch sensitivity can be increased.

In order to perform the functions as described above, the touch sensing unit 600 supplies the sensing pulse to the touch electrodes 510 and then receives a sensing signal from the touch electrodes 510. (620), if the sensing pulse output period does not exceed the touch sensing period, the number of sensing pulses is increased, and when the sensing pulse output period exceeds the touch sensing period, the determination of reducing the number of sensing pulses It includes a device 630 and a storage device 640 for storing various types of information necessary for the determination.

In addition, the touch sensing unit 600 may further include a mux 610 for individually operating each touch group by grouping the pxq number of touch electrodes 510 shown in FIG. 3 into a plurality of touch groups. have.

The mux 610 divides the touch sensing period by the number of the touch groups, and supplies the sensing pulse to the touch electrodes 510 included in one touch group for each divided period. For example, when the total number of the touch electrodes is 240 (= 20(p) x 12(q)) and the touch group is three, a total of 240 lines connected to the mux 610 are touched. It is connected to the electrodes 510, and a total of 80 (= 240 / 3) lines are connected between the touch driver 620 and the mux 610.

In this case, the mux 610 divides the touch sensing period into three periods, and supplies the sensing pulse to a total of 80 touch electrodes 510 in each period.

Detailed functions and operation methods of the touch sensing unit 600 will be described in detail with reference to FIGS. 3 to 5.

5 is a flowchart of an embodiment of a method for driving a display device according to the present invention. 6 is an exemplary view for explaining a case in which a sensing pulse output period is included within a touch sensing period in a method of driving a display device according to the present invention. 7 is an exemplary view for explaining a case in which a sensing pulse output period exceeds a touch sensing period in a method of driving a display device according to the present invention. In FIGS. 6 and 7, reference numeral A'denotes a touch sensing period for one touch group. That is, the sum of the touch sensing time of each of the touch groups divided by the mux 610 is formed to be less than or equal to the touch sensing period.

In the method of driving a display device according to the present invention, as shown in FIGS. 5 to 7, it is determined whether the sensing pulse output period B in which sensing pulses are output exceeds a preset touch sensing period A. Step 702, if the sensing pulse output period (B) does not exceed the touch sensing period (A), increasing the number of the sensing pulses (704 to 708) and the determination result, the sensing pulse output If the period (B) exceeds the touch sensing period (A), the step of reducing the number of sensing pulses (710 to 714).

In particular, the touch sensing unit 600 includes a sensing pulse act signal (Y) and the touch sensing period (A) having a value opposite to the sensing pulse synchronization signal (X) for dividing the sensing pulse output period (B). It is possible to determine whether the sensing pulse output period B exceeds the touch sensing period A by using the distinguished touch synchronization signal S.

The terms described below are defined as follows.

First, the touch synchronization signal S defines a period in which the sensing pulses are output. That is, the sensing pulses are controlled to be output within the touch sensing period A defined by the touch synchronization signal S. The touch sensing period (A) means, for example, a period in which the touch synchronization signal S is high.

Second, the sensing pulse synchronization signal X defines a point in time at which the sensing pulses are output. That is, the sensing pulses are sequentially output according to the sensing pulse synchronization signal X. In particular, the sensing pulses are output within a sensing pulse output period (B) defined by the sensing pulse synchronization signal (X). The sensing pulse output period (B) refers to a period in which the sensing pulse synchronization signal (X) is low.

Third, the interrupt signal Z is output in the form of a pulse when the touch synchronization signal S falls from high to low.

Fourth, the sensing pulse act signal (Y) is a signal having a value opposite to that of the sensing pulse synchronization signal (X). When the interrupt signal (Z) is output in the form of a pulse, when the sensing pulse act signal (Y) is low, the touch sensing unit 600, the sensing pulse output period (B) is the touch sensing period (A) ). In this case, the touch sensing unit 600 determines that the sensing pulses are normally output.

When the interrupt signal (Z) is output in the form of a pulse, if the sensing pulse act signal (Y) is high, the touch sensing unit 600, the sensing pulse output period (B) is the touch sensing period (A) ) Is judged to be exceeded. In this case, the touch sensing unit 600 determines that the sensing pulses are abnormally output.

Fifth, in the following description, both an embodiment with the mux 610 and an embodiment without the mux 610 will be described. In the case of the presence of the mux 610, in particular, the present invention will be described by taking as an example that the mux 610 divides and drives the touch electrodes 510 into three touch groups. When the mux 610 divides and drives the touch electrodes 510 into three touch groups, as shown in FIGS. 6(b) and 7(b), the touch synchronization signal (S) Is output as three pulses. In this case, the total pulse width of the three pulses becomes the touch sensing period (A).

Here, the touch signal (S), the sensing pulse synchronization signal (X), the sensing pulse act signal (Y), and the interrupt signal (Z) may be generated by the driving unit 400, or the touch sensing unit It can also be generated at 600. When the signals are generated by the driving unit 400, the signals may be particularly generated by the timing controller. In addition, some of the signals may be generated by the driver 400 and some of the signals may be generated by the touch sensing unit 600.

For example, the sensing pulse synchronous signal (X) and the touch signal (S) are generated by the driving unit 400, and the sensing pulse act signal (Y) and the interrupt signal (Z) are the touch sensing unit ( 600).

The above processes will be described in detail for each step as follows.

First, the touch sensing unit 600 determines whether or not the sensing pulse output period B in which the sensing pulses are output exceeds a preset touch sensing period A during the first frame period (702). ).

First, the touch sensing unit 600 has a value opposite to the sensing pulse synchronization signal X for distinguishing the sensing pulse output period when the touch synchronization signal S for distinguishing the touch sensing period is low. When the sensing pulse act signal Y having a is low, it is determined that the sensing pulse output period B does not exceed the touch sensing period.

For example, the sensing pulse output period (B), which is actually output to the touch electrode 510, of the sensing pulses, as shown in FIGS. 6A and 6B, If within the touch sensing period (A), the sensing pulse synchronization signal (X) defining the sensing pulse output period (B) is high when the touch synchronization signal (S) is polled from high to low. Is, and the sensing pulse act signal Y having a value opposite to that of the sensing pulse synchronous signal X becomes low.

When the touch synchronization signal S is polled from high to low, the interrupt signal Z is output in the form of a pulse.

The touch sensing unit 600 includes the sensing pulse act signal Y when the interrupt signal Z is output in a pulse form, that is, when the touch synchronization signal S is polled from high to low. Determine whether it is high or low.

In the above example, when the touch synchronization signal S falls from high to low, the sensing pulse act signal Y goes low.

When the touch synchronization signal S is polled from high to low, the touch sensing unit 600, when the sensing pulse act signal Y is low, as shown in FIG. 6, the sensing pulses are It is determined that it is being output within the touch sensing period (A).

In the above example, the touch synchronization signal S may be output in the form of one pulse during the touch sensing period, as shown in FIG. 6A. However, as described above, when the touch electrodes are divided into three touch groups and operated by the mux 610, as shown in (b), they may be output in the form of three pulses.

When the touch synchronization signal S is output in the form of one pulse, the touch sensing unit 600 performs the above process at a time when the one pulse falls from high to low, so that the sensing pulses are It may be determined that it is being output within the touch sensing period A.

However, when the touch synchronization signal S is output in the form of three pulses, the touch sensing unit 600 performs the above process at a time when the third output pulse is polled to a high low, It may be determined that the sensing pulses are being output within the touch sensing period A. Whether the touch synchronization signal S is output in the form of a number of pulses varies depending on the structure of the mux 610, and information on the pulse form may be stored in the storage unit 640.

Second, when the touch synchronization signal S for dividing the touch sensing period is low, the sensing pulse act signal Y is high, the sensing pulse output period It is determined that (B) has exceeded the touch sensing period (A).

For example, the sensing pulse output period (B), which is actually output to the touch electrode 510, of the sensing pulses, as shown in FIGS. 7A and 7B, If the touch sensing period (A) is exceeded, the sensing pulse synchronization signal (X) defining the sensing pulse output period (B) is low when the touch synchronization signal (S) is polled from high to low. ), and the sensing pulse act signal (Y) having a value opposite to that of the sensing pulse synchronization signal (X) becomes high.

When the touch synchronization signal S is polled from high to low, the interrupt signal Z is output in the form of a pulse.

The touch sensing unit 600 includes the sensing pulse act signal Y when the interrupt signal Z is output in a pulse form, that is, when the touch synchronization signal S is polled from high to low. Determine whether it is high or low.

In the above example, when the touch synchronization signal S falls from high to low, the sensing pulse act signal Y becomes high.

When the touch synchronization signal S is polled from high to low, the touch sensing unit 600, when the sensing pulse act signal Y is high, as shown in FIG. 7, the sensing pulses are It is determined that the touch sensing period (A) is exceeded.

That is, the touch sensing unit 600 includes the sensing pulse act signal Y and the touch sensing period A having a value opposite to the sensing pulse synchronization signal X for dividing the sensing pulse output period B. ), it is determined whether the sensing pulse output period (B) in which the sensing pulses are output exceeds the preset touch sensing period (A) (702). ).

Next, if the determination result 702, the sensing pulse output period (B) does not exceed the touch sensing period (A), the touch sensing unit 600, increasing the number of the sensing pulse step 704 to 708).

In this case, the touch sensing unit 600 controls the touch driver 620 so that the touch driver 620 increases the number of the sensing pulses output in the sensing pulse output period B. do.

More specifically, it is as follows.

First, the touch sensing unit 600, if the determination result, during the first frame period, the sensing pulse output period (B) does not exceed the touch sensing period, as shown in FIG. 6 (702) , The number of sensing pulses is increased (704).

Second, the touch sensing unit 600 drives the touch panel 500 during a second frame period by using the increased sensing pulses.

Third, the touch sensing unit 600 determines whether or not the sensing pulse output period due to the increased sensing pulses exceeds the touch sensing period (706). That is, the touch sensing unit 600 repeatedly performs a process of determining whether the sensing pulse output period (B) exceeds the touch sensing period (A) in the first frame, even in the second frame. do.

Fourth, as a result of the determination in the second frame, if the sensing pulse output period (B) due to the increased sensing pulses does not exceed the touch sensing period (A), increasing the sensing pulse (704) ) And the determination process 706 are repeatedly performed.

Fifth, while repeating the process, if the determination result 706 in the n-th frame, the sensing pulse output period (B) due to the increased sensing pulses exceeds the touch sensing period (A), the previous step The touch panel 500 is driven by using the number of sensing pulses (708).

For example, when there are 100 sensing pulses output in the first frame, if it is determined that the sensing pulse output period (B) is less than the touch sensing period (A), the touch sensing unit 600 The number of sensing pulses is sequentially increased by at least one (704).

While the number of sensing pulses increases, the determination process 706 is continuously performed.

In the n-1th frame, the number of sensing pulses may be increased to 120, and even in the determination process 706 in the n-1th frame, the sensing pulse output period (B) is the touch sensing period ( It may not exceed A).

However, in the nth frame, when the determination process 706 is performed in a state in which the number of sensing pulses is increased to 122, the sensing pulse output period B may exceed the touch sensing period A. have.

In this case, from the n+1th frame, the touch sensing unit 600 may set the number of sensing pulses to 120 to determine whether or not the touch panel 500 is touched.

That is, even if the 120 sensing pulses are output, the sensing pulse output period (B) does not exceed the touch sensing period (A). Accordingly, the touch sensing unit 600 may determine whether a touch is performed using the maximum sensing pulse.

Accordingly, the touch sensitivity to the touch sensing unit 600 may be increased.

Finally, when the determination result 702 and the sensing pulse output period B exceed the touch sensing period A, steps 710 to 714 of reducing the number of sensing pulses are performed.

In this case, the touch sensing unit 600 controls the touch driver 620 so that the touch driver 620 reduces the number of the sensing pulses output in the sensing pulse output period B. do.

More specifically, it is as follows.

First, the touch sensing unit 600, when the determination result 702, during the first frame period, the sensing pulse output period (B) exceeds the touch sensing period, as shown in FIG. 7 ( 702), the number of sensing pulses is decreased (710).

Second, the touch sensing unit 600 drives the touch panel 500 during a second frame period by using the reduced sensing pulses.

Third, the touch sensing unit 600 determines whether or not the sensing pulse output period due to the reduced sensing pulses exceeds the touch sensing period (712). That is, the touch sensing unit 600 repeatedly performs a process of determining whether the sensing pulse output period (B) exceeds the touch sensing period (A) in the first frame, even in the second frame. do.

Fourth, as a result of the determination in the second frame, when the sensing pulse output period (B) due to the reduced sensing pulses exceeds the touch sensing period (A), the process of reducing the sensing pulse (710) And the determination process 712 is repeatedly performed.

Fifth, while repeating the process, if the determination result 712 in the n-th frame, the sensing pulse output period (B) due to the reduced sensing pulses is within the touch sensing period (A), the current The touch panel 500 is driven by using the number of sensing pulses (714).

For example, when the sensing pulses output from the first frame are 140, if it is determined that the sensing pulse output period (B) is greater than the touch sensing period (A), the touch sensing unit 600, the The number of sensing pulses is sequentially decreased by at least one (710).

While the number of sensing pulses decreases, the determination process 712 is continuously performed.

In the n-1th frame, the number of sensing pulses may be reduced to 122, and even in the determination process 712 in the n-1th frame, the sensing pulse output period (B) is the touch sensing period ( A) can be exceeded.

However, in the nth frame, when the determination process 712 is performed in a state where the number of sensing pulses is reduced to 120, the sensing pulse output period B may be formed within the touch sensing period A. have.

In this case, from the n+1th frame, the touch sensing unit 600 may set the number of sensing pulses to 120 to determine whether or not the touch panel 500 is touched.

That is, even if the 120 sensing pulses are output, the sensing pulse output period (B) does not exceed the touch sensing period (A). Accordingly, the touch sensing unit 600 may determine whether a touch is performed using the maximum sensing pulse.

Accordingly, the touch sensitivity to the touch sensing unit 600 may be increased.

The number of sensing pulses may be set differently in each display device according to the present invention.

Accordingly, each display device can determine whether a touch is performed using sensing pulses optimized for the corresponding display device. Accordingly, touch sensitivity may be improved.

That is, according to the present invention, regardless of the difference in the size of the capacitance of the touch electrodes between the touch panels, in all display devices using the touch panel, the sensing pulse output period (B) is within the touch sensing period (A). Can be formed. Accordingly, sensing signals from all touch panels are maximized, and touch sensitivity may be improved.

Those skilled in the art to which the present invention pertains will be able to understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not limiting. The scope of the present invention is indicated by the claims to be described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

100: panel 400: driving unit
500: touch panel 510: touch electrode
520: touch electrode wiring 600: touch sensing unit
700: device for calculating the capacitance of the touch electrode

Claims (10)

Determining whether a sensing pulse output period in which the sensing pulses are output exceeds a preset touch sensing period;
If the sensing pulse output period does not exceed the touch sensing period, increasing the number of sensing pulses; And
And reducing the number of sensing pulses when the sensing pulse output period exceeds the touch sensing period. The method of claim 1,
The step of determining whether the sensing pulse output period exceeds the touch sensing period,
A method of driving a display device, comprising using a sensing pulse act signal having a value opposite to a sensing pulse synchronous signal for dividing the sensing pulse output period and a touch synchronous signal for dividing the touch sensing period. The method of claim 1,
The step of determining whether the sensing pulse output period exceeds the touch sensing period,
When the touch synchronization signal separating the touch sensing period is low, and the sensing pulse act signal having a value opposite to the sensing pulse synchronization signal separating the sensing pulse output period is low, the sensing pulse output period is the touch sensing period. Is judged not to exceed
And when the touch synchronization signal is low and the sensing pulse act signal is high, it is determined that the sensing pulse output period exceeds the touch sensing period. The method of claim 1,
The step of increasing the number of sensing pulses,
If the sensing pulse output period does not exceed the touch sensing period, after driving the touch panel by increasing the number of sensing pulses, the sensing pulse output period due to the increased sensing pulses exceeds the touch sensing period. A first step of determining whether or not;
A second step of repeatedly performing the first step when the sensing pulse output period due to the increased sensing pulses does not exceed the touch sensing period; And
Display comprising a third step of driving the touch panel using the number of sensing pulses before the number of sensing pulses is increased when the sensing pulse output period due to the increased sensing pulses exceeds the touch sensing period How to drive the device. The method of claim 1,
The step of reducing the number of sensing pulses,
When the sensing pulse output period exceeds the touch sensing period, after driving the touch panel by reducing the number of sensing pulses, whether the sensing pulse output period by the reduced sensing pulses exceeds the touch sensing period A first step of determining whether or not;
A second step of repeatedly performing the first step when the sensing pulse output period due to the reduced sensing pulses exceeds the touch sensing period; And
And a third step of driving the touch panel using a current number of sensing pulses when the sensing pulse output period due to the reduced sensing pulses does not exceed the touch sensing period. The method of claim 1,
When the touch panel is a self-cap type touch panel, and when at least two sensing pulse output periods are formed within one touch sensing period, determining whether the sensing pulse output period exceeds the touch sensing period,
And determining whether the last sensing pulse output period exceeds the touch sensing period among two or more sensing pulse output periods. A panel in which a self-cap type touch panel formed of a plurality of touch electrodes is embedded; And
A display device including a touch sensing unit that increases or decreases the number of sensing pulses according to whether a sensing pulse output period in which sensing pulses are output exceeds a preset touch sensing period. The method of claim 7,
The touch sensing unit,
When the sensing pulse output period does not exceed the touch sensing period, the number of sensing pulses is increased,
When the sensing pulse output period exceeds the touch sensing period, the number of sensing pulses is reduced. The method of claim 7,
The touch sensing unit,
A touch driver configured to receive a sensing signal from the touch electrodes after supplying the sensing pulse to the touch electrodes; And
Display including a determiner for increasing the number of sensing pulses when the sensing pulse output period does not exceed the touch sensing period, and decreasing the number of sensing pulses when the sensing pulse output period exceeds the touch sensing period Device. The method of claim 9,
The touch sensing unit,
During the touch sensing period, the display device further comprises a mux for driving the touch electrodes into at least two or more groups.

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