KR20180002394A - Touch display device and driving method thereof - Google Patents

Abstract

The present invention provides a touch display device which separates a driving power of the touch display device and can prevent touch recognition from being delayed when converting into an active mode, and a driving method thereof. The touch display device according to the present invention comprises: a touch display panel driven in the active mode and a power saving mode; a system control part generating a power signal according to the active mode and the power saving mode; and a power supply part generating a first driving power and a second driving power by receiving the power signal.

Description

TECHNICAL FIELD [0001] The present invention relates to a touch display device and a method of driving the touch display device.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a touch display device, and more particularly, to a touch display device in which a driving power source is separated and a driving method thereof.

A touch display device is a display device in which a touch panel is installed in an image display device such as a liquid crystal display device, a field emission display device, a plasma display panel, an organic light emitting display device, etc., and the touch panel is pressed by a user to output predetermined information .

The above-described touch display device can be divided into an add-on type, an on-cell type, and an in-cell type according to its structure. In the top plate attaching type, the touch sensor module is attached to the upper plate of the display device after separately manufacturing the display device and the touch sensor module. The built-in top plate is a method of directly forming the touch sensor elements on the upper glass substrate surface of the display device. The built-in type incorporates touch sensor elements in the display device to achieve a thin display device and enhance durability.

Among them, the built-in touch display device is widely used because it can share a common electrode of a display device as a touch electrode and can be made thinner, and a touch device is formed inside the touch display device to enhance durability.

The built-in touch display device senses a change in the capacitance value of the touch block TB before and after the touch, thereby determining whether or not the conductive material is in contact with the touch pad. In the built-in touch display device, one frame period may be divided into a display period in which data of the input image is written to the pixels (PX) of the touch display device and a touch interval in which the touch is detected.

1 is a view schematically showing a conventional built-in touch display device.

As shown in FIG. 1, the conventional built-in touch display device includes a touch display panel 15, a touch control unit 13, a touch display panel 15, And a timing control section 11 for controlling the timing of the touch control section 13.

The timing controller 11 provides a gate signal GS and a data signal DS to the touch display panel 15 and provides a time division synchronous signal Tsync to the touch controller 13.

Here, the gate signal GS is a signal for controlling the gate line (not shown) of the touch display panel 15 and the data signal DS is a signal for outputting an input image to each pixel PX of the touch display panel 15 .

The time division synchronous signal (Tsync) is a signal for dividing the display section and the touch section.

The touch control unit 13 provides a touch signal TS to the touch display panel 15 to determine whether the touch display panel 15 is touched. In the touch period, the touch controller 13 provides a touch signal TS having a pulse shape to the touch display panel 15 and changes the touch signal TS (TS) according to the capacitance change of the touch block TB ) And detects whether or not the touch is detected.

In the touch display panel 15, the electrostatic capacity of the built-in touch block TB is changed by touching the user. It is possible to detect whether the touch is caused by such a change in capacitance.

The timing control unit 11, the touch control unit 13, and the touch display panel 15 of the touch display apparatus 10 are all supplied with one driving power source Vcc.

2 is a timing chart of driving power of a conventional touch display panel.

Referring to FIG. 2, the touch display device 10 converts into a sleep mode when there is no input from a user for a predetermined time.

For example, there is no input from the user for a predetermined time, and t ₀ Time mode to a sleep mode. The timing controller 11, the touch controller 13, and the touch panel 15, which receive the driving power Vcc, do not operate. In this case, the driving power source Vcc is not applied. At this time, mutual recognition through the touch signal (TS) between the touch display panel 15 and the touch control unit 13 is impossible.

After a certain time t ₁ The touch control unit 13 re-applies the driving power source Vcc to perform resetting and the touch control unit 13 must recognize the touch display panel 15 again . Accordingly, the touch detection is disabled for a predetermined time D, and the touch control unit 13 recognizes the touch display panel 15 only after the time t ₁ + D.

As a result, when the user leaves the sleep mode, the touch detection is not performed immediately, and the touch detection is not performed until a certain time D is reached.

The present invention provides a touch display device and a method of driving the touch display device, which can prevent a delay in touch recognition when the driving power source of the touch display device is disconnected and switched to the active mode.

According to an aspect of the present invention, there is provided a touch display apparatus including a touch display panel, a system control unit, and a power supply unit.

The touch display panel is driven in an active mode and a power saving mode.

The system control unit generates a power supply signal according to the active mode and the power saving mode.

The power supply unit receives the power supply signal and generates a first driving power and a second driving power.

The first driving power source is provided to the power control unit, and the second driving power source is provided to the touch control unit.

It is not necessary to recognize the touch control unit again when the touch display device according to the present invention is switched to the active mode, so that the touch display panel can perform touch detection without delay.

1 is a view schematically showing a conventional built-in touch display device.
2 is a timing chart of driving power of a conventional touch display panel.
FIG. 3 is a view illustrating a touch display device according to an embodiment of the present invention, and FIG. 4 is a view illustrating a touch display panel and a plurality of drivers according to an embodiment of the present invention.
5 is a diagram illustrating time-division driving of a touch display panel according to an embodiment of the present invention.
6 is a timing chart showing internal signals of the touch display device according to the embodiment of the present invention.
7 is a flowchart illustrating a method of driving a touch display apparatus according to an embodiment of the present invention.
8 is a view illustrating a touch display apparatus according to another embodiment of the present invention.
9 is a timing chart showing internal signals of a touch display apparatus according to another embodiment of the present invention.
10 is a flowchart illustrating a method of driving a touch display device according to another embodiment of the present invention.

Hereinafter, a touch display device according to an embodiment of the present invention will be described in detail with reference to FIGS. 3 to 6. FIG.

FIG. 3 is a view illustrating a touch display device according to an embodiment of the present invention, and FIG. 4 is a view illustrating a touch display panel and a plurality of drivers according to an embodiment of the present invention.

3, the touch display apparatus 100 according to the embodiment of the present invention includes a touch display panel 110, a plurality of drivers 121, 123, and 125 for driving the touch display panel 110, A system controller 150 for controlling all components of the touch panel 110 and a plurality of control units 131, 133 and 135 for controlling the plurality of drivers 121, 123 and 125, a power supply unit 140, do.

The plurality of drivers 121, 123 and 125 include a touch driver 121, a gate driver 123 and a data driver 125. The plurality of controllers 131, 133, and 135 may include a power controller 131, A timing control unit 135, and a touch control unit 133. [

4, the touch display panel 110 includes a plurality of gate lines GL and a plurality of data lines DL formed in a matrix form on a substrate (not shown) using glass or plastic . A plurality of pixels PX are defined at the intersections of the gate lines GL and the data lines DL. A common electrode (not shown) facing the pixel electrode (not shown) of the pixel PX is divided to form a plurality of touch blocks TB. Each of the touch blocks TB is electrically connected to the touch driver 121 through a touch line TL. These touch lines TL all have the same width and the same line resistance and can be made of a material with low transmittance.

Each of the plurality of pixels PX may include a thin film transistor (not shown) and a liquid crystal capacitor (not shown). In the thin film transistor, the gate electrode is connected to the gate line GL, the source electrode is connected to the data line DL, and the drain electrode is connected to the pixel electrode. In the display period D _A of the active mode, the thin film transistor is turned on by the gate voltage supplied through the gate line GL, and the data supplied through the data line DL And transmits the voltage to the pixel electrode. In the liquid crystal capacitor, the data voltage provided to the pixel electrode through the thin film transistor and the common voltage Vcom provided to the touch block TB through the touch line TL form an electric field, So that the image is displayed.

The touch display device 100 according to the embodiment of the present invention is not limited to the liquid crystal display device. However, the touch display device 100 is not limited to the OLED display, the electrophoretic display device (EPD) , A plasma display panel (PDP), or the like.

5 is a diagram illustrating time-division driving of a touch display panel according to an embodiment of the present invention.

5, in the touch display panel 110 according to the embodiment of the present invention, one frame is written to each pixel PX of the touch display panel 110, The display sections D _A and D _s and the touch block TB and the touch lines TL are driven and time-divisionally driven by the touch periods T _A and T _S for detecting the touch. That is, each of the plurality of touch blocks TB may be operated as a common electrode in the display periods D _A and D _s and may be operated as a touch electrode that detects a user's touch in the touch periods T _A and T _s .

In order to reduce power consumption, the touch display panel 110 is divided into an active mode in which an image is implemented according to an input image and a sleep mode in which an image is not implemented. If there is no user input for a predetermined time in the touch display device 100, the touch display panel 110 is driven in a sleep mode. While not implement an image in the display region (D _s) of the sleep mode (Sleep mode), the power saving mode, the touch intervals (T _s) of the (Sleep mode) in the touch detection function in order to recognize the user's touch is still active, .

6 is a timing chart showing internal signals of the touch display device according to the embodiment of the present invention.

Referring to FIG. 3, the system control unit 150 controls all the components of the touch display device 100. The system control unit 150 provides a power supply signal VS to the power supply unit 140 according to an external input. Here, the external input may correspond to the touch operation of the user and the connection of the external terminal.

6, when the user's input is not in the active mode for a predetermined period of time (when the User signal is low level), the system controller 150 controls the power supply unit 140 to a low level power supply signal VS. Here, a certain time without an input of a user in an active mode is defined as a power saving standby time Tsd. That is, the system controller 150 outputs the power supply signal VS from the high level to the low level when there is no input from the user during the power saving standby time Tsd that is initially set in the active mode. Thereafter, the system controller 150 outputs the power supply signal VS from the low level to the high level when the system controller 150 senses the input of the user (when the User signal is at the high level). Here, the input time point of the user and the conversion time point of the power supply signal VS may have a certain time difference. This time difference is called an activation delay time Tad and is a time required for processing the image information so that the touch display panel 110 can implement an image in an active mode.

The power supply unit 140 supplies power to the power control unit 131 and the touch control unit 133 so that the touch display panel 110 can be driven. That is, the power supply unit 140 supplies the first driving power V1 to the power control unit 131 and the second driving power V2 to the touch control unit 133.

Referring to FIG. 6, the voltage of the first driving power supply V1 is determined according to the power supply signal VS provided from the system controller 150. FIG. The first driving power supply V1 maintains a high level voltage when the power supply signal VS is at a high level and the first driving power supply V1 is at a low level when the power supply signal VS is at a low level. / RTI > On the other hand, the second driving power supply V2 always maintains a high level voltage.

The second driving power supply V2 always maintains the high level voltage so that the touch control unit 133 is always driven so that the system control unit 150 and the touch control unit 133 are activated in the active mode (Active mode). Therefore, even when the active mode is switched to, the system controller 150 does not need to recognize the touch controller 133 again, so that the touch display panel 110 can perform touch detection without delay.

The power control unit 131 receives the first driving power V1 from the power supply unit 140 and supplies the display power Vd to the timing control unit 135 and outputs the mode synchronization signal Msync to the touch control unit 133. [ . Although not shown, the power control unit 131 converts power to not only the timing control unit 135 but also the plurality of driving units 121, 123, and 125 according to the standards of the respective driving units. The display power supply Vd is obtained by converting the first driving power V1 according to the power supply standard of the timing controller 135 and is a low level voltage in the sleep mode according to the first driving power V1 Maintains high level voltage in active mode.

Here, the mode synchronizing signal Msync is a signal to inform the touch controller 133 of the mode of the touch panel 110. The power controller 131 controls the mode synchronizing signal of high level in the active mode Level mode synchronizing signal Msync in the power saving mode (Sleep mode).

The timing control unit 135 receives a timing signal (not shown) transmitted from an external system (not shown) and generates a gate control signal GCS, a data control signal DCS, and a time division synchronous signal Tsync. The gate control signal GCS is output to the gate driver 123 and the data control signal DCS is output to the data driver 125 through the EPI wiring pair. Division synchronizing signal Tsync for time-dividing one frame into display periods D _A and D _s and touch periods T _A and T _s in accordance with the timing signal to the touch controller 133. Here, the timing signal may be a horizontal synchronization signal Hsync, a vertical synchronization signal Vsync, a data enable signal DE, and a clock signal CLK.

The timing controller 135 generates digital image data (RGB) from a video signal (not shown) transmitted from an external system and outputs it to the data driver 125 through an EPI wiring pair.

The touch control unit 133 receives the time division synchronous signal Tsync and provides the touch signal TS to the touch driver 121 for driving the touch of the touch display panel 110. In addition, it receives the mode synchronizing signal Msync, recognizes the touch signal TS, and determines whether or not the touch control unit 133 is reset. More specifically, when the mode synchronization signal Msync is at a high level, the touch control unit 133 senses the touch signal TS. When the touch signal TS is not recognized, the touch controller 133 performs a reset. When the touch signal TS is recognized, the touch controller 133 detects a touch. On the other hand, when the mode synchronizing signal Msync is at the low level, the touch controller 133 does not recognize the touch signal TS and waits until the mode synchronizing signal Msync becomes high level.

The touch controller 133 compares the touch signal TS transmitted from the touch driver 121 and generates touch coordinates when the touch signal TS is recognized while the mode synchronizing signal Msync is at the high level. Since the touch voltage (not shown) applied to the touch block TB differs depending on the presence or absence of the user's touch, the respective touch signals TS have different widths of signals. The widths of the plurality of touch signals TS are compared with each other to finally generate touch coordinates.

Also, the touch controller 133 receives power from the second driving power source V2. That is, since the second driving power source V2 is a high-level voltage in the active mode and the sleep mode, the touch controller 133 is in an active mode and a sleep mode It is always driven. Thus, the system control unit 150 and the touch control unit 133 can communicate in advance before the active mode in the sleep mode. Therefore, even when the active mode is switched to, the system controller 150 does not need to recognize the touch controller 133 again so that the touch display panel 110 can perform touch detection without delay.

In response to the gate control signal GCS provided from the timing controller 135, the gate driver 123 sequentially applies the gate signal GL in the display period D _A of the active mode through the gate line GL, It is possible to output the gate voltage. Accordingly, the thin film transistor connected to each gate line GL is turned on by one horizontal period. Here, the gate driver 123 may include a plurality of shift registers (not shown) connected to the plurality of gate lines GL, and may be configured as a GIP (Gate In Panel) mounted in the touch display panel 110 .

Here, the gate control signal GCS includes a gate start pulse GSP, a gate shift clock GSC, and a gate output enable signal GOE. The gate start pulse GSP is applied to the shift register of the gate driver 123 as a signal for determining when to output the gate voltage to the first gate line GL. The gate shift clock GSC is commonly applied to each shift register and is a clock signal that enables a next shift register (not shown). The gate output enable signal GOE controls the output of the shift register.

The data driver 125 converts the digital image data RGB supplied from the timing controller 135 through the EPI wiring pair into the analog data voltage according to the data control signal DCS. The data driver 125 applies the analog data voltage to the pixel electrode of each pixel PX through the data line DL in the active mode display period D _A.

The data control signal DCS includes a source start pulse SSP, a source shift clock SSC and a source output enable signal SOE. The source start pulse SSP determines the sampling start timing of the video data RGB of the data driver 125. The source shift clock SSC is a clock signal for controlling the data sampling operation in the data driver 125. The source output enable signal SOE controls the output of the data driver 125.

The touch driver 121 can output the common voltage Vcom to each touch block TB through the touch line TL in response to the touch signal TS provided from the touch controller 133. [ More specifically, the touch driver 121 outputs the common voltage Vcom of the DC waveform to the respective touch blocks TB in the display period D _A of the active mode. Thus, the liquid crystal is moved through the electric field due to the data voltage applied to the pixel electrode and the common voltage Vcom applied to the touch block TB, which is a common electrode. Further, the touch driver 121 outputs a touch driving voltage (not shown), which is a common voltage Vcom of the sensing waveform, in each of the touch periods T _A and T _s to each touch block TB. As a result, the touch voltage is charged in the touch block TB, which is the touch electrode. Here, the touch controller 133 and the touch driver 121 can exchange information by communicating using a SPI (Serial Peripheral Interface) method.

The touch driver 121 may receive the touch voltage Vt of each touch block TB in the touch interval and convert the touch voltage Vt into a touch signal TS. The touch signal TS is output to the touch control unit 133 so as to generate touch coordinates. The touch voltage may be different for each touch block (TB) due to a change in capacitance of the touch block (TB) depending on whether the user touches the touch pad (TB). According to the method of forming the capacitance, the touch display device of mutual capacitance type and the touch display device of self capacitance type can be divided.

Between the touch line TL and the touch driver 121, two or more touch lines TL are connected to one output channel of the touch driver 121 to reduce the number of output channels of the touch driver 121 (Not shown) can be added.

As described above, since the second driving power source V2 is a high level voltage in the active mode and the sleep mode, the touch display apparatus 100 according to the present invention having the above- , The touch controller 133 is always driven in an active mode and a sleep mode. Thus, the system control unit 150 and the touch control unit 133 can communicate in advance before the active mode in the sleep mode. Accordingly, the system controller 150 does not need to recognize the touch controller 133 again, so that the touch display panel 110 can perform touch detection without delay.

7 is a flowchart illustrating a method of driving a touch display apparatus according to an embodiment of the present invention.

Hereinafter, a method of driving the touch display device according to the embodiment of the present invention will be described with reference to FIG.

A method (S100) of driving a touch display device according to an embodiment of the present invention includes a step of driving a touch controller (S110), a mode synchronizing signal inspecting step (S120), a touch signal inspecting step (S130), and a touch sensing step do.

The touch control unit driving step S110 is a step in which the touch control unit 133 receives power from the second driving power source V2 and is driven. Since the second driving power source V2 is a high level voltage in the active mode and the sleep mode, the touch controller 133 is always driven.

The mode synchronizing signal inspecting step S120 is a step of judging the voltage level of the mode synchronizing signal Msync provided by the power control unit 131 described above. More specifically, when the mode synchronizing signal Msync is at a high level, the step of inspecting the touch signal TS is executed. If the mode synchronizing signal Msync is at a low level, (S120) is executed again. In other words, when the mode synchronizing signal Msync, which is a signal for notifying the touch control panel 133 of the mode of the touch panel 110, is at a high level, that is, the touch signal TS only in the active mode . Conversely, when the mode synchronizing signal Msync becomes low level, that is, in the sleep mode, it stands by.

The touch signal inspection step S130 is a step in which the touch controller 133 recognizes the touch signal TS. More specifically, when the touch signal TS is not recognized, the touch control unit 133 is reset (S131). If the touch signal TS is recognized, the touch sensing unit 140 ). Here, the touch signal inspection step S130 is executed only in the active mode due to the previous mode synchronous signal inspection step S120. Accordingly, power is applied to both the touch controller 133 and the touch driver 121, and the touch signal TS is always sensed in the normal driving state, thereby performing the touch sensing step S140.

Finally, in the touch sensing step S140, the touch controller 133 compares the touch signal TS transmitted from the touch driver 121 to generate touch coordinates.

In the method of driving a touch display device according to an embodiment of the present invention configured as described above, the touch signal TS is detected only in the active mode by inspecting the mode synchronizing signal Msync before the touch signal inspecting step S130 In the sleep mode, the touch control unit 133 does not perform a reset. Accordingly, the system controller 150 does not need to recognize the touch controller 133 again when switching to the active mode, so that the touch display panel 110 can perform touch detection without delay.

Hereinafter, a touch display device according to another embodiment of the present invention will be described in detail.

However, the description overlapping with the touch display device according to the embodiment of the present invention will be omitted.

8 is a view illustrating a touch display apparatus according to another embodiment of the present invention.

8, the touch display device 200 according to another embodiment of the present invention includes a touch display panel 210, a plurality of drivers 221, 223, and 225 for driving the touch display panel 210, A system controller 250 for controlling all the components of the plurality of control units 231, 233 and 235, the power supply unit 240 and the touch display panel 210 for controlling the plurality of drivers 221, 223 and 225, .

The plurality of driving units 221, 223 and 225 include a touch driving unit 221, a gate driving unit 223 and a data driving unit 225. The plurality of control units 231, 233 and 235 are connected to a power control unit 231, A timing control unit 235, and a touch control unit 233. [

9 is a timing chart showing internal signals of a touch display apparatus according to another embodiment of the present invention.

Referring to FIG. 8, the system control unit 250 controls all components of the touch display device 200. The system controller 250 provides the first power supply signal VS1 and the second power supply signal VS2 to the power supply unit 240 according to an external input. Here, the external input may correspond to the touch operation of the user and the connection of the external terminal.

9, in the active mode, when the user's input is not input for a predetermined time (when the User signal is low level), the system controller 250 switches the power mode to the power mode Level first power supply signal VS1 and a low-level second power supply signal VS2 to the second power supply unit 240. [ Although not shown in the drawing, the first power supply signal VS1 and the second power supply signal VS2 may not be simultaneously switched to the low level. Here, a certain time without an input of a user in an active mode is defined as a power saving standby time Tsd. That is, when there is no user input during the power saving standby time Tsd set in the active mode, the system controller 250 sets the first power supply signal VS1 and the second power supply signal VS2 to high level To a low level.

Then, the system controller 250 outputs the first power supply signal VS1 and the second power supply signal VS2 from the low level to the high level when the system controller 250 senses the input of the user (when the User signal is high level). Here, there may be a certain time difference between the input timing of the user and the conversion timing of the first power supply signal VS1 and the second power supply signal VS2. The time difference between the input time of the user and the first power supply signal VS1 is defined as the first activation delay time Tad1 and the time difference between the input time of the user and the second power supply signal VS2 is defined as the second activation delay time Tad2, . Here, the first activation delay time Tad1 may be longer than the second activation delay time Tad2. This is because it is necessary for the system control unit 250 to recognize the touch control unit 233 before the image is implemented.

The power supply unit 240 supplies power to the power control unit 231 and the touch control unit 233 so that the touch display panel 210 can be driven. That is, the power supply unit 240 supplies the first driving power V1 to the power control unit 231 and the second driving power V2 to the touch control unit 233.

Referring to FIG. 9, the voltage of the first driving power supply V1 is determined according to the first power supply signal VS1 provided from the system controller 250. FIG. When the first power supply signal VS1 is at the high level, the first driving power supply V1 maintains the high level voltage. When the first power supply signal VS1 is at the low level, The voltage of the low level is maintained.

The voltage of the second driving power source V2 is determined according to the second driving power source V2 and the second power source signal VS2 provided from the system control unit 250. [ The second driving power supply V2 maintains a high level voltage when the second power supply signal VS2 is at a high level and the second driving power supply V2 is at a low level when the second power supply signal VS2 is at a low level. The voltage of the low level is maintained. Since there is a time difference between the first power supply signal VS1 and the second power supply signal VS2, there is also a time difference between the first driving power supply V1 and the second driving power supply V2. Accordingly, the first driving power source V1 is always at a low level voltage in the power saving mode, while the second driving power source V2 is at the low level voltage in the power saving mode and in some intervals, . Herein, a period in which the second driving power source V2 is at a low level voltage is defined as a first period T1, and a period in which the second driving power source V2 is at a high level voltage is defined as a second period T2 define. At the end of the second period, the active mode is switched to the active mode and the second driving power source V2 is kept at the high level voltage. Here, the time of the second section T2 is different for each experimental model. In the case of the first model, the second section T2 corresponds to 2.8 seconds to 4 seconds. In the case of the second model, the second section T2 ) Ranged from 6.5 to 14.6 seconds.

In this way, the second driving power supply V2 maintains the high level voltage in the second section T2 of the power saving mode, thereby causing the touch control section 233 to be re-driven before being switched to the active mode. Therefore, before the system controller 250 determines the connection state of the touch controller 233, the touch controller 233 may reset the system controller 250 before the system controller 250 switches to the active mode, 233) need not be reconnected. Accordingly, when switching to the active mode, the system controller 250 already connects the touch controller 233 to allow the touch display panel 210 to perform touch detection without delay.

The power control unit 231 receives the first driving power V1 from the power supply unit 240 and supplies the display power Vd to the timing control unit 235 and outputs the mode synchronizing signal Msync to the touch control unit 233. [ . Although not shown, the power supply control unit 231 converts power to not only the timing control unit 235 but also the plurality of driving units 221, 223, and 225 according to the specifications of each driving unit. Here, the display power supply Vd is obtained by converting the first driving power V1 according to the power supply standard of the timing controller 235 and is a low level voltage in the sleep mode according to the first driving power V1 Maintains high level voltage in active mode.

Here, the mode synchronizing signal Msync is a signal for informing the touch controller 233 of the mode of the touch panel 210. The power controller 231 controls the mode synchronizing signal of the high level in the active mode Level mode synchronizing signal Msync in the power saving mode (Sleep mode).

The touch control unit 233 receives the time division synchronous signal Tsync and provides the touch signal TS to the touch driver 221 for driving the touch of the touch display panel 210. [ In addition, it receives the mode synchronization signal (Msync), recognizes the touch signal TS, and determines whether or not the touch control unit 233 is reset. More specifically, when the mode synchronizing signal Msync is at a high level, the touch controller 233 senses the touch signal TS. When the touch signal TS is not recognized, the touch control unit 233 performs reset. When the touch signal TS is recognized, the touch sensing unit 233 senses the touch. On the other hand, when the mode synchronizing signal Msync is at a low level, the touch controller 233 does not recognize the touch signal TS and waits until the mode synchronizing signal Msync becomes high level.

Also, the touch controller 233 receives power from the second driving power source V2. Accordingly, the touch controller 233 is not driven in the first power saving mode T1 but is driven in the second power saving mode T2 and the active mode. In this way, the second driving power supply V2 maintains the high level voltage in the second section T2 of the power saving mode, thereby causing the touch control section 233 to be re-driven before being switched to the active mode. Therefore, before the system controller 250 determines the connection state of the touch controller 233, the touch controller 233 may reset the system controller 250 before the system controller 250 switches to the active mode, 233) need not be reconnected. Accordingly, when switching to the active mode, the system controller 250 already connects the touch controller 233 to allow the touch display panel 210 to perform touch detection without delay.

10 is a flowchart illustrating a method of driving a touch display device according to another embodiment of the present invention.

Hereinafter, a method of driving the touch display device according to another embodiment of the present invention will be described with reference to FIG.

The method S200 of driving the touch display device according to another embodiment of the present invention includes a step S210 of inputting a user, a step S220 of driving a touch controller, a step S230 of inspecting a mode synchronizing signal, a step S240 of inspecting a touch signal, And a touch sensing step S250.

The user input step S210 is a step of inputting a user's touch in a sleep mode. Here, it is possible to input an external terminal other than the touch.

The touch control unit driving step S220 is a step in which the touch control unit 243 receives power from the second driving power supply V2 and is driven. The second driving power supply V2 is a low level voltage in the first power saving mode T1 and maintains a high level voltage in the second power saving mode T2 and the active mode. Accordingly, the touch controller 233 is not driven in the first power saving mode T1 but is driven in the second power saving mode T2 and the active mode.

The mode synchronizing signal checking step S230 is a step of judging the voltage level of the mode synchronizing signal Msync provided from the power source controller 231. [ More specifically, when the mode synchronizing signal Msync is at a high level, the step S240 of inspecting the touch signal TS is performed. When the mode synchronizing signal Msync is at a low level, (S230). That is, when the mode synchronizing signal Msync, which is a signal for notifying the touch control panel 233 of the mode of the touch panel 210, is at the high level, that is, the touch signal TS only in the active mode . Conversely, when the mode synchronizing signal Msync becomes low level, that is, in the sleep mode, it stands by.

The touch signal inspection step S240 is a step in which the touch control unit 233 recognizes the touch signal TS. More specifically, when the touch signal TS is not recognized, the touch control unit 233 is reset (S241). When the touch signal TS is recognized, the touch sensing unit S23 ). Here, the touch signal inspection step S240 is performed only in the active mode due to the previous mode synchronous signal inspection step S230. Accordingly, power is applied to both the touch controller 233 and the touch driver 221, and the touch signal TS is always sensed in the normal driving state, and the touch sensing operation S250 is performed.

Finally, in the touch sensing step S250, the touch controller 233 compares the touch signals TS transmitted from the touch driver 221 to generate touch coordinates.

In the method of driving a touch display device according to another embodiment of the present invention configured as described above, the mode signal Msync is checked before the touch signal inspection step S240, In the sleep mode, the touch control unit 233 does not perform a reset operation. Thus, the system controller 250 does not have to recognize the touch controller 233 again when switching to the active mode, so that the touch display panel 210 can perform touch detection without delay.

While a number of embodiments have been described in detail above, it should be construed as being illustrative of preferred embodiments rather than limiting the scope of the invention. Therefore, the invention should not be construed as limited to the embodiments described, but should be determined by equivalents to the appended claims and the claims.

100, 200: touch display device 110, 210: touch display panel
131, 231: power control section 133, 233: touch control section
135, 235: timing control section 140, 240: power supply section
150, 250:

Claims (10)

A touch display panel driven in an active mode and a power saving mode;
A system controller for generating a power supply signal according to the active mode and the power saving mode; And
And a power supply for receiving the power supply signal and generating a first driving power and a second driving power,
Wherein the first driving power source is provided to a power control unit, and the second driving power source is provided to a touch control unit. The method according to claim 1,
Wherein the first driving power source is a high level voltage in the active mode and a low level voltage in the power saving mode,
And the second driving power source is a high level voltage in the active mode and the power saving mode. The method according to claim 1,
Wherein the power saving mode comprises a first period and a second period,
Wherein the first driving power source is a high level voltage in the active mode and a low level voltage in the power saving mode in accordance with the power source signal,
Wherein the second driving power source is a high level voltage in a second period of the active mode and the power saving mode according to the power supply signal and a low level voltage in a first period of the power saving mode. The method according to claim 1,
Wherein the power control unit receives the first driving power and supplies a mode locking signal to the touch control unit. 5. The method of claim 4,
Wherein the mode synchronizing signal is high level in the active mode, low level in the power saving mode,
And the touch control unit is operated according to the high-level mode synchronizing signal. A method of driving a touch display device including a touch display panel driven in an active mode and a power saving mode,
Driving the touch control unit in the power saving mode;
Checking the mode synchronization signal by the touch control unit;
Checking the touch signal by the touch control unit; And
And the touch control unit sensing a touch of a user. The method according to claim 6,
Wherein the touch control unit driving step receives the second driving power of high level in the active mode and the power saving mode to drive the touch control unit. The method according to claim 6,
The power saving mode includes a first period and a second period,
Wherein the touch control unit driving step receives the second driving power of the high level in the active mode and the second period of the power saving mode to drive the touch control unit. The method according to claim 6,
The mode synchronization signal checking step
When the mode synchronization signal is at a high level, the touch signal inspection step is executed
And when the mode synchronizing signal is at a low level, re-executing the mode synchronizing signal inspecting step. The method according to claim 6,
The touch signal inspection step
If the touch signal is not recognized, the touch control unit is reset
And when the touch signal is recognized, performing the touch sensing step.

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