KR102352751B1 - Touch Device And Method Of Driving The Same - Google Patents

Abstract

The present invention generates a touch synchronization signal during a signal period in which an image signal is supplied, and generates the touch synchronization signal in which a frequency or a waveform is modulated during a no-signal period in which the image signal is not supplied, and the image signal and a plurality of A timing controller for generating image data, a data control signal, and a gate control signal using a timing signal, and a touch scan signal according to the touch synchronization signal during the signal period, and according to the touch synchronization signal during the no-signal period a microcomputer that stops generating the touch scan signal; a data driver that generates a data signal using the image data and the data control signal; and a gate driver that generates a gate signal using the gate control signal; Provided is a touch display device including a touch display panel that displays an image using a gate signal and the data signal and senses a touch using the touch scan signal.

Description

Touch Device And Method Of Driving The Same

The present invention relates to a touch display device, and more particularly, to a touch display device capable of preventing vibration and noise by controlling the output of a touch scan signal depending on whether an image signal is input or not, and a method of driving the same.

In line with the information age, the display field has also developed rapidly, and in response to this, a liquid crystal display device (LCD) as a flat panel display device (FPD) with the advantages of thinness, light weight, and low power consumption. ), plasma display panel device (PDP), organic light emitting diode display device (OLED), field emission display device (FED), etc. It is rapidly replacing the cathode ray tube (CRT).

Recently, a touch display device (or a touch screen) in which a touch panel is attached to such a display panel has been in the spotlight.

The touch display device is used as an output means for displaying an image, and is used as an input means for receiving a user's command by touching a specific part of the displayed image. It can be divided into a decompression method, an electrostatic method, an infrared method, an ultrasonic method, and the like.

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

Such a touch display device may be manufactured in a form in which a separate touch panel is attached to the display panel or the touch panel is formed on a substrate of the display panel to be integrated.

In particular, in recent years, in order to slim down portable terminals such as smartphones and tablet PCs, the electrodes and wires constituting the touch panel are formed on the substrate of the display panel and integrated with the in-cell type touch display device. Demand is increasing.

The in-cell type touch display device divides a time section of one frame into a display section for displaying an image and a touch section for detecting a touch to perform image display and touch sensing, respectively, which will be described with reference to the drawings.

1 is a diagram illustrating a conventional touch display device.

As shown in FIG. 1 , the conventional touch display device 10 includes a timing controller 20 , a microcomputer 30 , a data driver 40 , a gate driver 50 , and a touch display panel 60 . do.

The timing controller 20 includes a plurality of timing signals, such as an image signal IS, a data enable signal DE, a horizontal synchronization signal HSY, a vertical synchronization signal VSY, and a clock CLK, transmitted from an external system. is used to generate a touch synchronization signal (TSY), image data (RGB), a data control signal (DCS) and a gate control signal (GCS), and the generated touch synchronization signal (TSY) is a microcontroller unit (MCU) unit 30 , the generated image data RGB and data control signal DCS are transferred to the data driver 40 , and the generated gate control signal GCS is transferred to the gate driver 50 .

The microcomputer 30 generates a touch scan signal TSS using the touch synchronization signal TSY transmitted from the timing controller 20 , and transmits the generated touch scan signal TSS to the data driver 40 . and analyzes the touch sensing signal transmitted from the data driver 40 to determine whether or not there is a touch.

The data driver 40 generates a data signal by using the image data RGB and the data control signal DCS transmitted from the timing controller 20 , and uses the generated data signal through data wiring of the touch display panel 60 . While being applied to the DL, the touch scan signal TSS transmitted from the microcomputer 30 is applied to the touch wiring TL of the touch display panel 180, and the touch sensing signal of the touch wiring TL is read. (read out), and transmits the read touch sensing signal to the microcomputer (30).

The gate driver 50 generates a gate signal using the gate control signal GCS transmitted from the timing controller 20 , and applies the generated gate signal to the gate line GL of the touch display panel 60 .

The touch display panel 60 displays an image using a gate signal and a data signal, and senses a touch using a touch scan signal and a touch detection signal, and a gate wiring GL that crosses each other to define the pixel P. ) and a data line DL, a pixel P connected to the gate line GL and the data line DL, and a touch line TL spaced apart in parallel to the data line DL.

As described above, the conventional touch display device 10 displays an image using a gate signal and a data signal, and detects a touch using a touch scan signal TSS and a touch detection signal, which will be described with reference to the drawings. do.

FIG. 2 is a waveform diagram illustrating a plurality of signals used in a conventional touch display device, which will be described with reference to FIG. 1 .

As shown in FIG. 2 , in the conventional touch display device 10 , the timing controller 20 generates a touch synchronization signal TSY using a plurality of timing signals transmitted from an external system, and the generated touch The synchronization signal TSY is transmitted to the microcomputer 30, and the microcomputer 30 generates a touch scan signal TSS using the touch synchronization signal TSY, and transmits the generated touch scan signal TSS. It is transmitted to the data driver 40 .

Specifically, the touch synchronization signal TSY has a high level HL during the display period DP in which the touch display panel 60 displays an image, and the touch period in which the touch display panel 60 detects a touch ( TP) has a rectangular wave shape with a low level LL.

The touch scan signal TSS has a constant value of the low level LL during the display period DP, and includes a plurality of pulses that change between the low level LL and the high level HL during the touch period TP. have

That is, the microcomputer 30 generates the touch scan signal TSS at the low level LL when the touch synchronization signal TSY is at the high level HL, and the touch synchronization signal TSY sets the low level LL. ), the touch scan signal TSS is generated as a plurality of pulses.

In the conventional touch display device 10 , there is a section in which the image signal IS is not supplied from the external system.

That is, the operation section of the touch display device 10 includes a signal section SP in which the image signal IS is supplied from the external system to the timing controller 20 and the image signal IS from the external system to the timing controller 20 . ) is divided into a non-signaling section (NSP) that is not supplied.

Here, the timing controller 20 generates a touch synchronization signal TSY during the signal period SP and the non-signal period NSP, respectively, according to a predetermined first frequency f1. A touch synchronization signal TSY, Since the image data RGB, the data control signal DCS, and the gate control signal GCS are generated, the touch synchronization signal TSY has a first frequency f1 during the signal period SP and the non-signal period NSP, respectively. has

Then, the microcomputer 30 generates a plurality of pulses of the touch scan signal TSS according to the low level LL of the touch synchronization signal TSY during the signal period SP and the non-signal period NSP, respectively. .

On the other hand, vibration and noise evaluation is performed by driving the touch display device 10 in a state in which the image signal IS is not supplied from the external system, and the image signal IS is not supplied from the external system. ), the microcomputer 30 generates a plurality of pulses of the touch scan signal TSS.

Since a plurality of pulses of the touch scan signal (TSS) have a specific frequency, a microcomputer such as a substrate, a flexible printed circuit (FPC), a printed circuit board (PCB), and a backlight unit There is a problem in that the peripheral object of the unit 30 may vibrate by a plurality of pulses of the touch scan signal TSS, and accordingly, noise is generated, so that the touch display device 10 cannot pass vibration and noise evaluation.

In addition, during the non-signal period NSP in which there is no need to detect a touch, the microcomputer 30 operates to generate a touch scan signal TSS for detecting a touch, so that the power consumption of the touch display device 10 is increased. there is a problem with

An object of the present invention is to provide a touch display device that prevents vibration and noise by modulating a touch synchronization signal according to an image signal to block generation of a touch scan signal, and a method for driving the same do it with

In addition, the present invention provides a touch display device and a method for driving the same in which vibration and noise are prevented and power consumption is reduced by modulating the frequency or waveform of the touch synchronization signal according to the image signal to block the generation of the touch scan signal. to serve a different purpose.

In order to solve the above problems, the present invention generates a touch synchronization signal during a signal period in which an image signal is supplied, and generates the touch synchronization signal in which a frequency or a waveform is modulated during a non-signal period in which the image signal is not supplied. and a timing controller for generating image data, a data control signal, and a gate control signal by using the image signal and a plurality of timing signals, and a touch scan signal according to the touch synchronization signal during the signal period, and the non-signal During the period, a microcomputer that stops generation of the touch scan signal according to the touch synchronization signal, a data driver that generates a data signal using the image data and the data control signal, and a gate signal using the gate control signal Provided is a touch display device comprising: a gate driver generating

In addition, the timing control unit includes an image signal sensing unit that detects the image signal to determine whether to supply the image signal, and a touch synchronization signal generation unit that generates the touch synchronization signal according to the determination result of the image signal detection unit. can do.

In addition, the touch synchronization signal generator generates the touch synchronization signal of a reference frequency during the signal period, and generates the touch synchronization signal of a modulation frequency different from the reference frequency during the no-signal period, and the microcomputer comprises: The touch scan signal may be generated by detecting the reference frequency during the signal period, and the generation of the touch scan signal may be stopped by detecting the modulation frequency during the no-signal period.

And, the touch synchronization signal generating unit generates the touch synchronization signal in the form of a high-level and low-level square wave during the signal period, and generates the touch synchronization signal in the form of a high-level DC voltage during the no-signal period, The microcomputer unit generates the touch scan signal by detecting the low level in the form of a square wave during the signal period, and stops the generation of the touch scan signal by detecting the high level in the form of the DC voltage during the no signal period can do.

Also, the touch scan signal may have a low level value during a display period for displaying an image, and may have a plurality of pulses that change between the low level and the high level during the touch period for detecting a touch.

Meanwhile, in the present invention, the timing controller generates a touch synchronization signal during a signal period to which an image signal is supplied, and generates the touch synchronization signal in which a frequency or a waveform is modulated during a non-signal period in which the image signal is not supplied, generating image data, a data control signal, and a gate control signal by using the image signal and a plurality of timing signals; and a microcomputer, generating a touch scan signal according to the touch synchronization signal during the signal period, and the non-signal Stopping generation of the touch scan signal according to the touch synchronization signal during a section; generating, by a data driver, a data signal using the image data and the data control signal; and, by a gate driver, controlling the gate A touch display device, comprising: generating a gate signal using a signal; displaying, by a touch display panel, an image using the gate signal and the data signal; provides a driving method for

The generating of the touch synchronization signal by the timing control unit includes: an image signal detecting unit detecting the image signal to determine whether to supply the image signal; and a touch synchronization signal generating unit determining a result of the image signal detecting unit It may include generating the touch synchronization signal according to the

In addition, the touch synchronization signal generator generates the touch synchronization signal of a reference frequency during the signal period, and generates the touch synchronization signal of a modulation frequency different from the reference frequency during the no-signal period, and the microcomputer comprises: The touch scan signal may be generated by detecting the reference frequency during the signal period, and the generation of the touch scan signal may be stopped by detecting the modulation frequency during the no-signal period.

And, the touch synchronization signal generating unit generates the touch synchronization signal in the form of a high-level and low-level square wave during the signal period, and generates the touch synchronization signal in the form of a high-level DC voltage during the no-signal period, The microcomputer unit generates the touch scan signal by detecting the low level in the form of a square wave during the signal period, and stops the generation of the touch scan signal by detecting the high level in the form of the DC voltage during the no signal period can do.

The present invention modulates a touch synchronization signal according to an image signal to block generation of a touch scan signal, thereby preventing vibration and noise.

In addition, the present invention blocks the generation of the touch scan signal by modulating the frequency or waveform of the touch synchronization signal according to the image signal, thereby preventing vibration and noise and reducing power consumption.

1 is a view showing a conventional touch display device.
2 is a waveform diagram illustrating a plurality of signals used in a conventional touch display device.
3 is a view showing a touch display device according to a first embodiment of the present invention.
4 is a waveform diagram illustrating a plurality of signals used in the touch display device according to the first embodiment of the present invention.
5 is a waveform diagram illustrating a plurality of signals used in a touch display device according to a second embodiment of the present invention.

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

3 is a diagram illustrating a touch display device according to a first embodiment of the present invention.

As shown in FIG. 3 , the touch display device 110 according to the first embodiment of the present invention includes a timing controller 120 , a microcontroller unit (MCU) unit 130 , a data driver 140 , and a gate. It includes a driving unit 150 and a touch display panel 160, and the touch display device 110 is an organic light emitting diode display device (OLED display device) or a liquid crystal display device (LCD). device) may be

The touch display device 110 divides the time period of one frame into a display period for displaying an image (DP in FIG. 4 ) and a touch period for sensing a touch (TP in FIG. 4 ) to perform image display and touch detection, respectively. During the display period DP, a gate signal and a data signal are respectively applied to the gate wiring GL and the data line DL of the touch display panel 160 to display an image, and during the touch period TP, the touch display panel A touch is sensed by applying the touch scan signal TSS to the touch wiring TL of 160 and reading the touch sensing signal of the touch wiring TL of the touch display panel 160 .

The timing controller 120 includes an image signal IS, a data enable signal DE, a horizontal synchronization signal HSY, and a vertical synchronization signal VSY, transmitted from an external system (not shown) such as a graphic card or a TV system. , the clock CLK and the like to generate a touch synchronization signal TSY, image data RGB, a data control signal DCS, and a gate control signal GCS, and the generated touch synchronization signal ( TSY) is transmitted to the microcomputer 130 , the generated image data RGB and the data control signal DCS are transmitted to the data driver 140 , and the generated gate control signal GCS is transmitted to the gate driver 150 . forward to

In particular, the timing control unit 120 is driven at a predetermined reference frequency (fr in FIG. 4 ) during the signal period (SP of FIG. 4 ) in which the image signal IS is supplied from the external system, and the reference frequency fr without frequency modulation. ), and is driven at a modulation frequency (fm) different from the reference frequency (fr) during the no-signal period (NSP in FIG. 4) in which the image signal (IS) is not supplied from the external system. generates a touch synchronization signal TSY of the modulated modulation frequency fm.

To this end, the timing control unit 120 includes an image signal detection unit 122 that detects the image signal IS and determines whether the image signal IS is supplied from an external system, and the image signal detection unit 122 . It may include a touch synchronization signal generator 124 that generates a touch synchronization signal TSY having a frequency according to the determination result.

Specifically, during the signal period SP in which the image signal IS is supplied from the external system, the image signal detection unit 122 of the timing control unit 120 determines that the image signal IS is supplied, and the timing control unit ( The touch synchronization signal generating unit 124 of 120 may generate the touch synchronization signal TSY of the reference frequency fr according to the determination result of the image signal detecting unit 122 .

And, during the non-signal period NSP in which the image signal IS is not supplied from the external system, the image signal detection unit 122 of the timing controller 120 determines that the image signal IS is not supplied, and the timing The touch synchronization signal generator 124 of the controller 120 may generate the touch synchronization signal TSY having a modulation frequency fm different from the reference frequency fr according to the determination result of the image signal detection unit 122 . .

The microcomputer 130 generates a touch scan signal TSS by using the touch synchronization signal TSY transmitted from the timing controller 120 , and transmits the generated touch scan signal TSS to the data driver 140 . and analyzes the touch sensing signal transmitted from the data driver 140 to determine whether or not there is a touch.

For example, the microprocessor 130 refers to a computer in which a microprocessor and an input/output module are made of a single chip to perform a predetermined function, and includes a central processing unit (CPU), memory, and programmable input/output. may include

In particular, the microcomputer 130 generates a touch scan signal TSS by detecting the reference frequency fr of the touch synchronization signal TSY during the signal period SP in which the image signal IS is supplied from the external system. , stops the generation of the touch scan signal TSS by detecting the modulation frequency fm of the touch synchronization signal TSY during the non-signal period NSP in which the image signal IS is not supplied from the external system.

To this end, the microcomputer 130 may include a touch synchronization signal sensing unit (not shown) that determines the frequency of the touch synchronization signal TSY.

Specifically, during the signal period SP in which the image signal IS is supplied from the external system, the touch synchronization signal sensing unit of the microcomputer 130 determines that the touch synchronization signal TSY has the reference frequency fr, The microcomputer 130 may generate the touch scan signal TSS according to the determination result of the touch synchronization signal sensing unit.

And, during the non-signal period NSP in which the image signal IS is not supplied from the external system, the touch synchronization signal sensing unit of the microcomputer 130 detects the touch synchronization signal TSY at a different modulation frequency ( fm), and the microcomputer 130 may stop generating the touch scan signal TSS according to the determination result of the touch synchronization signal sensing unit.

The data driver 140 generates a data signal (data voltage) using the data control signal DCS and the image data RGB transmitted from the timing controller 120 , and applies the generated data signal to the touch display panel 160 . ) to the data line (DL).

In addition, the data driver 140 applies the touch scan signal TSS transmitted from the microcomputer 130 to the touch wiring TL of the touch display panel 160 and receives the touch sensing signal of the touch wiring TL. It reads out, and transmits the read touch sensing signal to the microcomputer 130 .

The gate driver 150 generates a gate signal (gate voltage) using the gate control signal GCS transmitted from the timing controller 120 , and applies the generated gate signal to the gate wiring GL of the touch display panel 160 . ) is approved.

The gate driving unit 150 includes a gate-in-panel formed together on a substrate of the touch display panel 160 on which the gate wiring GL, the data line DL, the touch wiring TL, and the pixel P are formed. gate in panel: GIP) type.

The touch display panel 160 displays an image using a gate signal and a data signal, and senses a touch using a touch scan signal and a touch detection signal, and a gate wiring GL that crosses each other to define the pixel P. ) and a data line DL, a pixel P connected to the gate line GL and the data line DL, and a touch line TL spaced apart in parallel to the data line DL.

When the touch display device 110 is an organic light emitting diode display device, the pixel P of the touch display panel 160 may include a switching thin film transistor, a driving thin film transistor, a storage capacitor, and a light emitting diode, and the touch display device 110 ) is a liquid crystal display device, the pixel P of the touch display panel 160 may include a thin film transistor, a storage capacitor, and a liquid crystal capacitor.

As described above, the touch display device 110 according to the first embodiment of the present invention displays an image using a gate signal and a data signal, senses a touch using a touch scan signal TSS and a touch detection signal, and , in particular, stops the generation of the touch scan signal TSS according to the touch synchronization signal TSY of the modulation frequency during the non-signal period NSP in which the image signal IS is not supplied, which will be described with reference to the drawings.

4 is a waveform diagram illustrating a plurality of signals used in the touch display device according to the first embodiment of the present invention, which will be described with reference to FIG. 3 .

As shown in FIG. 4 , in the touch display device 110 according to the first embodiment of the present invention, the timing controller 120 uses a plurality of timing signals transmitted from an external system to generate a touch synchronization signal TSY. and transmits the generated touch synchronization signal TSY to the microcomputer 130, and the microcomputer 130 generates a touch scan signal TSS using the touch synchronization signal TSY, and the generated The touch scan signal TSS is transmitted to the data driver 140 .

Specifically, the touch synchronization signal TSY has a high level HL during the display period DP in which the touch display panel 160 displays an image, and the touch period in which the touch display panel 160 detects a touch ( TP) has a rectangular wave shape with a low level LL.

In addition, the touch synchronization signal TSY has a reference frequency fr during the signal period SP in which the image signal IS is supplied from the external system, and has a non-signal period in which the image signal IS is not supplied from the external system. It has a modulation frequency fm different from the reference frequency fr during (NSP).

For example, the reference frequency fr may be 60 Hz, and the modulation frequency fm may be 50 Hz.

That is, the timing controller 120 generates the touch synchronization signal TSY of the reference frequency fr during the signal period SP, and a modulation frequency fm different from the reference frequency fr during the non-signal period NSP. of the touch synchronization signal TSY may be generated.

The touch scan signal TSS has a constant value of the low level LL during the display period DP, and includes a plurality of pulses that change between the low level LL and the high level HL during the touch period TP. have

In addition, the touch scan signal TSS has a plurality of pulses during the touch period TP of the signal period SP in which the image signal IS is supplied from the external system, and the image signal IS is not supplied from the external system. It has a constant value of the low level LL during the touch period TP of the non-signal period NSP.

That is, when the touch synchronization signal TSY is at the high level HL, the microcomputer 130 generates the touch scan signal TSS at the low level LL, and the touch synchronization signal TSY sets the low level LL. ), the touch scan signal TSS is generated as a plurality of pulses, and a touch scan signal TSS including a plurality of pulses is generated during the signal period SP, and a plurality of pulses are generated during the non-signal period NSP. The generation of the included touch scan signal TSS may be stopped (OFF).

As described above, in the touch display device 110 according to the first embodiment of the present invention, during the signal period SP in which the image signal IS is supplied from the external system, the timing controller 120 controls the reference frequency fr. generates a touch synchronization signal TSY of , and the microcomputer 130 detects a reference frequency fr of the touch synchronization signal TSY to maintain generation of a touch scan signal TSS including a plurality of pulses, During the non-signal period NSP in which the image signal IS is not supplied from the external system, the timing controller 120 generates a touch synchronization signal TSY having a modulation frequency fm different from the reference frequency fr, and The unit 130 detects the modulation frequency fm of the touch synchronization signal TSY to stop generating the touch scan signal TSS including a plurality of pulses.

Since generation of the touch synchronization signal TSS including a plurality of pulses is stopped during the non-signal period NSP, vibration and noise caused by the plurality of pulses of the touch synchronization signal TSS are prevented, and the touch display device 110 . of vibration and noise evaluation results are improved.

In addition, since generation of the touch synchronization signal TSS including a plurality of pulses is stopped during the non-signal period NSP, power consumption of the touch display device 110 is reduced.

In another embodiment, generation of the touch scan signal may be stopped during the no-signal period by modulating the waveform of the touch synchronization signal instead of the frequency of the touch synchronization signal, which will be described with reference to the drawings.

5 is a waveform diagram illustrating a plurality of signals used in the touch display device according to the second embodiment of the present invention. Since the configuration of the touch display device according to the second embodiment is similar to that of the first embodiment, FIG. 3 will be described with reference to, and descriptions of the same parts will be omitted.

3 and 5 , the touch display device 110 according to the second embodiment of the present invention includes a timing control unit 120 , a microcontroller unit (MCU) unit 130 , and a data driving unit 140 . ), a gate driver 150 and a touch display panel 160 .

The touch display device 110 divides the time period of one frame into a display period DP for displaying an image and a touch period TP for detecting a touch, respectively, to display an image and sense a touch, and the display period DP ) by applying a gate signal and a data signal to the gate wiring GL and the data line DL of the touch display panel 160, respectively, to display an image, and during the touch period TP, the touch wiring of the touch display panel 160 A touch is sensed by applying the touch scan signal TSS to TL and reading the touch sensing signal of the touch wiring TL of the touch display panel 160 .

The timing controller 120 includes an image signal IS, a data enable signal DE, a horizontal synchronization signal HSY, a vertical synchronization signal VSY, a clock CLK, etc. transmitted from an external system (not shown). A touch synchronization signal TSY, image data RGB, a data control signal DCS, and a gate control signal GCS are generated using a plurality of timing signals, and the generated touch synchronization signal TSY is transmitted to the microcomputer 130 ), the generated image data RGB and data control signal DCS are transferred to the data driver 140 , and the generated gate control signal GCS is transferred to the gate driver 150 .

In particular, the timing controller 120 generates a touch synchronization signal TSY in the form of a square wave having a high level HL and a low level LL alternately during the signal period SP in which the image signal IS is supplied from the external system. and generates a touch synchronization signal TSY in the form of a DC voltage of high level HL during the non-signal period NSP in which the image signal IS is not supplied from the external system.

To this end, the timing control unit 120 includes an image signal detection unit 122 that detects the image signal IS and determines whether the image signal IS is supplied from an external system, and the image signal detection unit 122 . The touch synchronization signal generator 124 may include a touch synchronization signal generating unit 124 that generates a touch synchronization signal TSY having a waveform according to the determination result.

Specifically, during the signal period SP in which the image signal IS is supplied from the external system, the image signal detection unit 122 of the timing control unit 120 determines that the image signal IS is supplied, and the timing control unit ( The touch synchronization signal generator 124 of 120 may generate the touch synchronization signal TSY in the form of a square wave according to the determination result of the image signal detection unit 122 .

And, during the non-signal period NSP in which the image signal IS is not supplied from the external system, the image signal detection unit 122 of the timing controller 120 determines that the image signal IS is not supplied, and the timing The touch synchronization signal generator 124 of the controller 120 may generate a touch synchronization signal TSY in the form of a DC voltage corresponding to the high level HL according to the determination result of the image signal detection unit 122 .

For example, the touch synchronization signal TSY has a high level HL during the display period DP of the signal period SP and a low level LL during the touch period TP of the signal period SP. It has a rectangular wave shape.

In addition, the touch synchronization signal TSY has a DC voltage of the high level HL during the non-signal period NSP.

The microcomputer 130 generates a touch scan signal TSS by using the touch synchronization signal TSY transmitted from the timing controller 120 , and transmits the generated touch scan signal TSS to the data driver 140 . and analyzes the touch sensing signal transmitted from the data driver 140 to determine whether or not there is a touch.

In particular, the microcomputer 130 generates a touch scan signal TSS by detecting the low level of the square wave form of the touch synchronization signal TSY during the signal period SP in which the image signal IS is supplied from the external system. , detects the high level of the DC voltage form of the touch synchronization signal TSY during the non-signal period NSP in which the image signal IS is not supplied from the external system to stop the generation of the touch scan signal TSS.

To this end, the microcomputer 130 may include a touch synchronization signal sensing unit (not shown) that determines the waveform of the touch synchronization signal TSY.

Specifically, during the signal period SP in which the image signal IS is supplied from the external system, the touch synchronization signal sensing unit of the microcomputer 130 determines that the touch synchronization signal TSY has a low level LL in the form of a square wave. After determining, the microcomputer 130 may generate a touch scan signal TSS according to the determination result of the touch synchronization signal sensing unit.

And, during the non-signal period NSP in which the image signal IS is not supplied from the external system, the touch synchronization signal sensing unit of the microcomputer 130 determines that the touch synchronization signal TSY has a high level in the form of a DC voltage. In addition, the microcomputer 130 may stop generating the touch scan signal TSS according to the determination result of the touch synchronization signal sensing unit.

For example, the touch scan signal TSS has a constant value of the low level LL during the display period DP of the signal period SP, and has a low level ( ) during the touch period TP of the signal period SP. LL) and the high level HL have a plurality of pulses, and have a constant value of the high level HL during the non-signal period NSP.

That is, the microcomputer 130 generates the touch scan signal TSS at the low level LL when the touch synchronization signal TSY is at the high level HL, and the touch synchronization signal TSY sets the low level LL. ), the touch scan signal TSS is generated as a plurality of pulses, a touch scan signal TSS including a plurality of pulses is generated during the signal period SP, and a plurality of pulses are generated during the non-signal period NSP. Generation of the included touch scan signal TSS may be stopped (OFF).

As described above, in the touch display device 110 according to the second embodiment of the present invention, during the signal period SP in which the image signal IS is supplied from the external system, the timing controller 120 performs the touch synchronization in the square wave form. The signal TSY is generated, and the microcomputer 130 detects the low level LL in the form of a square wave of the touch synchronization signal TSY to maintain the generation of the touch scan signal TSS including a plurality of pulses, During the non-signal period NSP in which the image signal IS is not supplied from the external system, the timing controller 120 generates a touch synchronization signal TSY in the form of a DC voltage of high level HL, and the microcomputer 130 ) detects the high level HL in the form of a DC voltage of the touch synchronization signal TSY to stop the generation of the touch scan signal TSS including a plurality of pulses.

Since generation of the touch synchronization signal TSS including a plurality of pulses is stopped during the non-signal period NSP, vibration and noise caused by the plurality of pulses of the touch synchronization signal TSS are prevented, and the touch display device 110 . of vibration and noise evaluation results are improved.

In addition, since generation of the touch synchronization signal TSS including a plurality of pulses is stopped during the non-signal period NSP, power consumption of the touch display device 110 is reduced.

Although the above has been described with reference to the preferred embodiment of the present invention, those skilled in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention described in the claims below You will understand that it can be done.

110: touch display device 120: timing control unit
122: image signal detection unit 124: touch synchronization signal generation unit
130: microcomputer 140: data driving unit
150: gate driver 160: touch display panel

Claims (11)

A touch synchronization signal is generated during a signal period to which an image signal is supplied, and the touch synchronization signal of which a frequency or a waveform is modulated during a non-signal period in which the image signal is not supplied is generated, and the image signal and a plurality of timing signals are used a timing controller for generating image data, data control signals, and gate control signals;
a microcomputer that generates a touch scan signal according to the touch synchronization signal during the signal period and stops generation of the touch scan signal according to the touch synchronization signal during the non-signal period;
a data driver for generating a data signal using the image data and the data control signal;
a gate driver for generating a gate signal using the gate control signal;
A touch display panel that displays an image using the gate signal and the data signal and senses a touch using the touch scan signal
including,
The timing control unit,
an image signal detection unit for detecting the image signal and determining whether to supply the image signal;
A touch synchronization signal generating unit that generates the touch synchronization signal according to a determination result of the image signal detecting unit
including,
The touch synchronization signal generating unit generates the touch synchronization signal of a reference frequency during the signal period, and generates the touch synchronization signal of a modulation frequency different from the reference frequency during the no-signal period,
The microcomputer unit detects the reference frequency during the signal period to generate the touch scan signal, and detects a modulation frequency during the no-signal period to stop generating the touch scan signal.
delete delete A touch synchronization signal is generated during a signal period to which an image signal is supplied, and the touch synchronization signal of which a frequency or a waveform is modulated during a non-signal period in which the image signal is not supplied is generated, and the image signal and a plurality of timing signals are used a timing controller for generating image data, data control signals, and gate control signals;
a microcomputer that generates a touch scan signal according to the touch synchronization signal during the signal period and stops generation of the touch scan signal according to the touch synchronization signal during the non-signal period;
a data driver for generating a data signal using the image data and the data control signal;
a gate driver for generating a gate signal using the gate control signal;
A touch display panel that displays an image using the gate signal and the data signal and senses a touch using the touch scan signal
including,
The timing control unit,
an image signal detection unit for detecting the image signal and determining whether to supply the image signal;
A touch synchronization signal generating unit that generates the touch synchronization signal according to a determination result of the image signal detecting unit
including,
The touch synchronization signal generating unit generates the touch synchronization signal in the form of a high-level and low-level square wave during the signal period, and generates the touch synchronization signal in the form of a high-level DC voltage during the no-signal period,
The microcomputer unit detects the low level in the form of a square wave during the signal period to generate the touch scan signal, and detects the high level in the form of the DC voltage during the no-signal period to stop generating the touch scan signal touch display device.
The method of claim 1,
The touch scan signal has a low level value during a display period for displaying an image, and has a plurality of pulses that change between the low level and the high level during a touch period for detecting a touch.
The timing control unit generates a touch synchronization signal during a signal period to which an image signal is supplied, and generates the touch synchronization signal in which a frequency or a waveform is modulated during a non-signal period in which the image signal is not supplied, and the image signal and the plurality of generating image data, a data control signal, and a gate control signal by using the timing signal;
generating, by a microcomputer, a touch scan signal according to the touch synchronization signal during the signal period, and stopping generation of the touch scan signal according to the touch synchronization signal during the non-signal period;
generating, by a data driver, a data signal using the image data and the data control signal;
generating, by a gate driver, a gate signal using the gate control signal;
displaying, by a touch display panel, an image using the gate signal and the data signal, and sensing a touch using the touch scan signal;
including,
The step of the timing control unit generating the touch synchronization signal,
determining, by an image signal detection unit, whether the image signal is supplied by detecting the image signal;
generating, by a touch synchronization signal generating unit, the touch synchronization signal according to the determination result of the image signal sensing unit;
including,
The touch synchronization signal generating unit generates the touch synchronization signal of a reference frequency during the signal period, and generates the touch synchronization signal of a modulation frequency different from the reference frequency during the no-signal period,
The microcomputer unit detects the reference frequency during the signal period to generate the touch scan signal, and detects a modulation frequency during the no-signal period to stop generating the touch scan signal.
delete delete The timing control unit generates a touch synchronization signal during a signal period to which an image signal is supplied, and generates the touch synchronization signal in which a frequency or a waveform is modulated during a non-signal period in which the image signal is not supplied, and the image signal and the plurality of generating image data, a data control signal, and a gate control signal by using the timing signal;
generating, by a microcomputer, a touch scan signal according to the touch synchronization signal during the signal period, and stopping generation of the touch scan signal according to the touch synchronization signal during the non-signal period;
generating, by a data driver, a data signal using the image data and the data control signal;
generating, by a gate driver, a gate signal using the gate control signal;
displaying, by a touch display panel, an image using the gate signal and the data signal, and sensing a touch using the touch scan signal;
including,
The step of the timing control unit generating the touch synchronization signal,
determining, by an image signal detection unit, whether the image signal is supplied by detecting the image signal;
generating, by a touch synchronization signal generating unit, the touch synchronization signal according to the determination result of the image signal sensing unit;
including,
The touch synchronization signal generating unit generates the touch synchronization signal in the form of a high-level and low-level square wave during the signal period, and generates the touch synchronization signal in the form of a high-level DC voltage during the no-signal period,
The microcomputer unit detects the low level in the form of a square wave during the signal period to generate the touch scan signal, and detects the high level in the form of the DC voltage during the no-signal period to stop generating the touch scan signal A method of driving a touch display device.
A touch synchronization signal of a reference frequency is generated during a signal period to which an image signal is supplied, and the touch synchronization signal of a modulation frequency different from the reference frequency is generated during a non-signal period in which the image signal is not supplied, and the image signal and the plurality of a timing control unit for generating image data, a data control signal, and a gate control signal by using the timing signal of ;
a microcomputer that generates a touch scan signal according to the touch synchronization signal of the reference frequency during the signal period and stops generation of the touch scan signal according to the touch synchronization signal of the modulation frequency during the no-signal period;
a data driver for generating a data signal using the image data and the data control signal;
a gate driver for generating a gate signal using the gate control signal;
A touch display panel that displays an image using the gate signal and the data signal and senses a touch using the touch scan signal
A touch display device comprising a.
Generates a touch synchronization signal in the form of a square wave of high level and low level during a signal period to which an image signal is supplied, and generates the touch synchronization signal in the form of a high-level DC voltage during a no-signal period in which the image signal is not supplied, a timing controller for generating image data, a data control signal, and a gate control signal by using the image signal and a plurality of timing signals;
During the signal period, a touch scan signal is generated according to the low-level touch synchronization signal in the form of a square wave; a microcomputer that stops generation;
a data driver for generating a data signal using the image data and the data control signal;
a gate driver for generating a gate signal using the gate control signal;
A touch display panel that displays an image using the gate signal and the data signal and senses a touch using the touch scan signal
A touch display device comprising a.

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