KR102377968B1 - Display device, driving integrated circuit, touch driving circuit and driving power circuit - Google Patents

Abstract

The present invention receives a driving voltage from a driving power circuit to generate a touch driving signal, driving a plurality of touch electrodes positioned on a panel with the touch driving signal, and generating an output control signal for controlling the output of the driving voltage to the driving power circuit Provided is a driving integrated circuit including a touch driving circuit for transmitting to the display and a data driving circuit for driving a display electrode positioned on a panel.

Description

Display device, driving integrated circuit, touch driving circuit and driving power circuit

The present invention relates to a display device, a driving integrated circuit, a touch driving circuit, and a driving power circuit for supplying driving power to these devices and circuits.

Electronic devices can operate in a sleep mode to reduce power consumption.

Electronic devices that have entered sleep mode return to operating mode in response to a specific signal. When it wakes up, the electronic device, such as a TV, returns from the sleep mode to the operation mode in response to the remote control signal.

Meanwhile, display devices that display an image using display electrodes and sense proximity or touch of an object using touch electrodes may also operate in a sleep mode to reduce power consumption. Such a display device can reduce power consumption by not driving the display electrode in the sleep mode. Alternatively, such a display device may reduce power consumption by stopping the operation of some processors.

The display device in the sleep mode may return to the operation mode in response to proximity or touch of an object. For example, when a touch of an object such as a finger is made to the display device in the sleep mode, the display device may detect the touch of the object and return to the operation mode from the sleep mode according to the detection result.

Since such a display device detects the touch of an object and switches the mode, the touch electrode is driven even in the sleep mode, but inefficient power consumption may occur during the driving process of the touch electrode in the sleep mode.

Against this background, it is an object of the present invention to reduce power consumption generated in the driving process of the touch electrode.

In order to achieve the above object, in one aspect, the present invention provides a panel including a plurality of touch electrodes, a driving power circuit for supplying a driving voltage, and a driving voltage supplied to generate a touch driving signal, and the touch driving signal Provided is a display device including a touch driving circuit for driving a touch electrode with a power supply circuit and transmitting an output control signal to a driving power circuit to control an output of a driving voltage.

In another aspect, the present invention provides an output control signal for generating a touch driving signal by receiving a driving voltage from a driving power circuit, driving a plurality of touch electrodes positioned on a panel with the touch driving signal, and controlling the output of the driving voltage Provided is a driving integrated circuit including a touch driving circuit that transmits the data to a driving power circuit and a data driving circuit that drives a display electrode positioned on a panel.

In another aspect, the present invention provides a touch electrode driving unit for receiving a driving voltage from a driving power circuit to generate a touch driving signal and driving a plurality of touch electrodes positioned on a panel with the touch driving signal, and an output of the driving voltage. Provided is a touch driving circuit including a signal transmission unit for transmitting an output control signal to be controlled to a driving power circuit.

In another aspect, the present invention provides a signal receiving unit for receiving an output control signal including an enable signal and a disable signal from a touch driving circuit for driving a plurality of touch electrodes located on a panel, and a touch according to the output control signal Provided is a driving power circuit including a driving voltage supply unit for controlling an output of a driving voltage supplied to the driving circuit.

As described above, according to the present invention, power consumption generated in the driving process of the touch electrode can be reduced. In particular, there is an effect that the display device can be driven for a long time with little energy by reducing power consumed in the sleep mode.

1 is a block diagram of a display device according to an exemplary embodiment.
2A and 2B are diagrams illustrating a driving voltage control flow between a touch driving circuit and a driving power circuit according to an exemplary embodiment.
3 is a diagram illustrating a detailed exemplary configuration of a driving power circuit including a DC/DC converter circuit.
FIG. 4 is a diagram illustrating an efficiency curve of the DC/DC converter circuit shown in FIG. 3 .
5 is a diagram illustrating a margin section between a sensing section and an output control signal.
6 is a diagram illustrating a margin section between a non-sensing section and an output control signal.
7 is a view for explaining a phenomenon in which an output capacitor in the driving power circuit is discharged.
8 is a view showing that the cut-off switch is located in the touch driving circuit.
9 is a diagram illustrating a timing relationship between a switchgating signal and peripheral signals.
10 is a diagram illustrating an embodiment in which two driving voltages and two output control signals are transmitted and received between a driving power circuit and a touch driving circuit.
11 is a diagram illustrating timing of an output control signal of FIG. 10 .

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the embodiments of the present invention, if it is determined that a detailed description of a related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the elements from other elements, and the essence, order, or order of the elements are not limited by the terms. When it is described that a component is “connected”, “coupled” or “connected” to another component, the component may be directly connected or connected to the other component, but another component is formed between each component. It should be understood that elements may also be “connected,” “coupled,” or “connected.” In the same vein, when it is described that a component is formed "on" or "below" another component, the component is both formed directly on the other component or indirectly through another component. should be understood as including

1 is a block diagram of a display device according to an exemplary embodiment.

Referring to FIG. 1 , the display device 100 includes a panel 110 , a data driving circuit 120 , a gate driving circuit 130 , a timing control circuit 140 , a touch driving circuit 150 , a processor 160 , It may include a driving power circuit 170 , a host 180 , and a logic power circuit 190 .

A plurality of data lines (DL) connected to the data driving circuit 120 are formed on the panel 110 , and a plurality of gate lines (GL) connected to the gate driving circuit 130 are formed. can be In addition, a plurality of pixels P corresponding to intersections of the plurality of data lines DL and the plurality of gate lines GL may be defined in the panel 110 .

In each of these pixels P, a first electrode (eg, a source electrode or a drain electrode) is connected to the data line DL, a gate electrode is connected to the gate line GL, and a second electrode (eg, a second electrode) is connected to the gate line GL. , a drain electrode or a source electrode) may be formed with a transistor connected to the display electrode.

Also, on the panel 110 , a plurality of touch electrodes TE may be formed to be spaced apart from each other. One pixel P may be located or a plurality of pixels P may be located in the region where the touch electrode TE is located.

The panel 110 may include a display panel (DP) and a touch screen panel (TSP), where the display panel (DP) and the touch panel (TSP) may share some components with each other. there is. For example, the plurality of touch electrodes TE may be one component of the display panel DP (eg, a common electrode to which a common voltage is supplied) and at the same time one component of the touch panel TSP (for sensing a touch). sensor electrode) for Since some components of the display panel DP and the touch panel TSP are shared with each other, the panel 110 is also called an integrated panel, but the present invention is not limited thereto. In addition, although an in-cell type panel is known as a form in which some components of the display panel DP and the touch panel TSP are shared with each other, this is only an example of the panel 110 described above. The applied panel 110 is not limited to such an in-cell type panel.

The data driving circuit 120 drives a display electrode (DE) (not shown) positioned in each pixel P to display a digital image in each pixel P of the panel 110 . The data driving circuit 120 may drive the display electrode DE by supplying the data signal Vdata to the data line DL.

The gate driving circuit 130 sequentially supplies the scan signal SCAN to the gate line GL to turn on or off the transistor located in each pixel P.

The gate driving circuit 130 may be located only on one side of the panel 110 as shown in FIG. 1 or may be divided into two and located on both sides of the panel 110 according to a driving method.

The timing control circuit 140 supplies various control signals to the data driving circuit 120 , the gate driving circuit 130 , and the touch driving circuit 150 .

The timing control circuit 140 includes a data control signal (DCS: Data) for controlling the data driving circuit 120 based on an external timing signal such as a vertical/horizontal synchronization signal, an image signal, and a clock signal input from the host 180 . Control Signal) and a gate control signal (GCS: Gate Control Signal) for controlling the gate driving circuit 130 may be output. Also, the timing control circuit 140 may output a touch control signal (TCS) for controlling the driving timing of the touch driving circuit 150 to the touch driving circuit 150 .

The timing control circuit 140 may determine a mode of the display device 100 and supply a mode signal representing the mode to the data driving circuit 120 , the gate driving circuit 130 , and the touch driving circuit 150 .

This mode may be determined by the host 180 . The host 180 determines the mode of the display device 100 and transmits information about the mode to the timing control circuit 140 , and the timing control circuit 140 may generate a mode signal based on the information. In addition, the timing control circuit 140 may supply these mode signals to the data driving circuit 120 , the gate driving circuit 130 , and the touch driving circuit 150 .

For example, the host 180 may determine the mode of the display device 100 as the sleep mode, and transmit a mode signal including the determined value to the timing control circuit 140 . In addition, the timing control circuit 140 controls the driving timing of the data driving circuit 120 , the gate driving circuit 130 , and the touch driving circuit 150 according to these mode signals or transmits these mode signals to the data driving circuit 120 . , to the gate driving circuit 130 and the touch driving circuit 150 to cause the corresponding circuit to operate in the sleep mode.

In the sleep mode, the data driving circuit 120 may not drive the display electrode DE. Also, in the sleep mode, the gate driving circuit 120 may not supply the scan signal SCAN to the gate line GL.

The touch driving circuit 150 drives the plurality of touch electrodes TE positioned on the panel 110 . The touch driving circuit 150 drives the touch electrode TE by supplying a touch driving signal (TDS) to the touch electrode TE and receiving the response signal.

The touch driving circuit 150 may generate a sensed value for the touch electrode TE by using a response signal received from the touch electrode TE and transmit the sensed value to the processor 160 . In addition, the processor 160 may generate the touch coordinate data XY according to the sensed value. In addition, the processor 160 may transmit the generated touch coordinate data XY to the host 180 .

In the sleep mode, the processor 160 may not generate the touch coordinate data XY. In the sleep mode, the processor 160 may operate only a portion of signal transmission/reception with other circuits and may not operate a portion that generates the touch coordinate data XY. Through this, the processor 160 may reduce power consumption in the sleep mode. In an example in which the processor 160 does not generate the touch coordinate data XY in the sleep mode, the touch driving circuit 150 may not transmit a sensed value for the touch electrode TE to the processor 160 . Alternatively, the touch driving circuit 150 transmits the sensed value for the touch electrode TE to the processor 160 , but the processor 160 may ignore the sensed value.

The touch driving circuit 150 may cause the processor 160 to generate the touch coordinate data XY by transmitting a wake up signal (WUS) to the processor 160 in the sleep mode.

The touch driving circuit 150 may generate a sensing value for the touch electrode TE even in the sleep mode. However, in the sleep mode, the driving period of the touch electrode TE may be longer than the driving period in the operation mode in order to reduce power consumption.

When the sensing value of the touch electrode TE generated in the sleep mode is greater than the reference value, the touch driving circuit 150 may transmit the wakeup signal WUS to the processor 160 . The processor 160 may change the mode according to the reception of the wake-up signal WUS and generate the touch coordinate data XY.

A reference value serving as a condition for generating the wake-up signal WUS may change over time. The processor 160 may provide such a reference value to the touch driving circuit 150 . The processor 160 may temporarily change the mode from the sleep mode to the operation mode at regular time intervals to provide the changed reference value to the touch driving circuit 150 . In addition, the processor 160 may calculate a reference value in this operation mode and transmit the calculated reference value to the touch driving circuit 150 .

The touch driving circuit 150 is a configuration separate from the data driving circuit 120 and the gate driving circuit 130 , and may be outside the data driving circuit 120 and the gate driving circuit 130 . Alternatively, the touch driving circuit 150 may be implemented as an internal configuration of an integrated circuit including at least one of the data driving circuit 120 and the gate driving circuit 130 . Alternatively, the touch driving circuit 150 may be implemented by being included in one configuration of the data driving circuit 120 or the gate driving circuit 130 .

The data driving circuit 120 , the timing control circuit 140 , the touch driving circuit 150 , and the processor 160 may all be implemented as one integrated circuit. For example, referring to the example of the driving integrated circuit 200 indicated by a dotted line in FIG. 1 , the driving integrated circuit 200 includes a data driving circuit 120 , a timing control circuit 140 , a touch driving circuit 150 and The processor 160 is implemented together.

Meanwhile, the touch driving circuit 150 may recognize the proximity or touch of an object by detecting a change in capacitance of the touch electrode TE. The capacitive touch method may be, for example, a mutual capacitive touch method and a self-capacitive touch method. The touch driving circuit 150 may employ one of a mutual capacitive touch method and a self-capacitive touch method or may employ another touch method. However, in this specification, for convenience of description, it is assumed that the self-capacitive touch method is employed and the embodiment will be described.

The driving power circuit 170 may supply the driving voltage VD to the data driving circuit 120 and the touch driving circuit 150 . In addition, the logic power circuit 190 may supply the logic power VL to the touch driving circuit 150 and the processor 160 .

The touch driving circuit 150 may generate the touch driving signal TDS by using the driving voltage VD. Then, the touch driving circuit 150 uses this driving voltage VD to transmit the gating signal of the transistor for transmitting the touch driving signal TDS - the gating signal transmitted to the gate of the transistor to control the on/off of the corresponding transistor. can create

The data driving circuit 120 may use this driving voltage VD to drive the display electrode DE. For example, the data driving circuit 120 may generate the data signal Vdata supplied to the data line DL by using the driving voltage VD. Alternatively, the data driving circuit 120 may generate a gating signal of a transistor for transmitting the data signal Vdata by using the driving voltage VD.

The logic power circuit 190 may constantly supply the logic power VL to the touch driving circuit 150 and the processor 160 . On the other hand, the driving power circuit 170 may control the supply and blocking of the driving voltage VD according to an output control signal (OCS). For example, the output control signal OCS may include an enable signal and a disable signal. The driving power circuit 170 outputs the driving voltage VD according to the enable signal and drives it according to the disable signal. The voltage VD may not be output.

The touch driving circuit 150 may control the driving voltage VD output of the driving power circuit 170 by transmitting the output control signal OCS to the driving power circuit 170 . The touch driving circuit 150 may transmit the output control signal OCS only in the sleep mode. Alternatively, the driving power circuit 170 controls the output of the driving voltage VD only in the sleep mode according to the output control signal OCS, and in other modes (eg, operation mode) other than the sleep mode, the output control signal OCS. may not be received or may be ignored.

The host 180 may also transmit a power control signal (PCS) to the driving power circuit 170 . The driving power circuit 170 may control the output of the driving voltage VD according to the power control signal PCS.

The driving power circuit 170 may control the output of the driving voltage VD by combining the power control signal PCS received from the host 180 and the output control signal OCS received from the touch driving circuit 150 . there is. For example, the driving power circuit 170 may output the driving voltage VD when both the power control signal PCS and the output control signal OCS have a high level. In addition, the driving power circuit 170 may not output the driving voltage VD when any one of the power control signal PCS and the output control signal OCS indicates a low level.

On the other hand, the driving power circuit 170 outputs the driving voltage VD to the touch driving circuit 150 in the sensing section in which the touch electrode is driven and is driven by the touch driving circuit 150 in the non-sensing section in which the touch electrode is not driven. The voltage VD may not be output. Then, the touch driving circuit 150 outputs an enable signal to the driving power circuit 170 in the sensing section so that the driving power circuit 170 operates as described above and outputs a disable signal to the driving power circuit in the non-sensing section. (170) can be output.

2A and 2B are diagrams illustrating a driving voltage control flow between a touch driving circuit and a driving power circuit according to an exemplary embodiment.

Referring to FIGS. 2A and 2B , the touch driving circuit 150 includes a touch electrode driving unit 152 that drives the touch electrode TE with a touch driving signal TDS, and an enable signal ES and a disable signal DS. ) may include a signal transmission unit 154 for transmitting the output control signal (OCS) including the. In addition, the driving power circuit 170 includes a signal receiving unit 174 that receives an output control signal OCS including an enable signal ES and a disable signal DS and a driving voltage according to the output control signal OCS. It may include a driving voltage supply unit 172 for controlling the output of (VD).

Referring to FIG. 2A , in the sensing period in which the touch electrode TE is driven, the signal transmitter 154 of the touch driving circuit 150 may transmit the enable signal ES to the driving power circuit 170 . In addition, the signal receiving unit 174 of the driving power circuit 170 receives the enable signal ES from the touch driving circuit 150 , and the driving voltage supplying unit 172 according to the enable signal ES in response to the touch driving circuit The driving voltage VD is output as (150).

Referring to FIG. 2B , in the non-sensing section in which the touch electrode TE is not driven, the signal transmitter 154 of the touch driving circuit 150 may transmit the disable signal DS to the driving power circuit 170 . . And, the signal receiving unit 174 of the driving power circuit 170 receives the disable signal DS from the touch driving circuit 150, and the driving voltage supply unit 172 according to the disable signal DS, the driving voltage ( VD) may not be output.

According to this driving voltage control flow, the driving power circuit 170 outputs the driving voltage VD in the sensing section in which the touch electrode TE is driven and the driving voltage VD in the non-sensing section in which the touch electrode TE is not driven. By not outputting VD), power consumption can be reduced.

In general, since the touch electrode TE is not driven in the non-sensing period, it may be considered that there is no power consumption in the touch driving circuit 150 . However, since there are various leakage current paths inside the touch driving circuit 150 , power consumption occurs in the touch driving circuit 150 even in the non-sensing section. The driving power circuit 170 may not output the driving voltage VD in the non-sensing section in order to reduce such power consumption occurring in the non-sensing section.

Meanwhile, the driving power circuit 170 may not generate the driving voltage VD according to the output control signal OCS. The driving power circuit 170 may generate a driving voltage VD by converting a voltage transmitted from the outside, for example, a battery voltage. The driving voltage VD is generated according to the output control signal OCS. can be controlled For example, when the enable signal ES is received as the output control signal OCS, the driving power circuit 170 generates the driving voltage VD, and when the disable signal DS is received, the driving voltage (VD) may not be created.

The driving power circuit 170 may include a DC/DC converter circuit including a power semiconductor (PS). This DC/DC converter circuit converts power even when there is little or no load (in the case of no load). consume In particular, when the maximum efficiency point of the DC/DC converter circuit is set to an operation mode other than sleep mode or a sensing section that is not a non-sensing section, the efficiency of the DC/DC converter circuit becomes worse when there is little or no load. It can consume a lot of power.

3 is a diagram illustrating a detailed exemplary configuration of a driving power circuit including a DC/DC converter circuit, and FIG. 4 is a diagram illustrating an efficiency curve of the DC/DC converter circuit shown in FIG.

Referring to FIG. 3 , the driving voltage supply unit 172 of the driving power circuit 170 controls the on/off of the DC/DC converter circuit 320 including the power semiconductor PS and the power semiconductor PS. circuit 310 may be included.

The DC/DC converter circuit 320 included in the driving voltage supply unit 172 may generate the driving voltage VD by converting a voltage transmitted from the outside, for example, the battery voltage Vbat. The DC/DC converter circuit 320 may include a power semiconductor (PS), a diode (D), an output inductor (L) and an output capacitor (C) to convert the battery voltage (Vbat) into a driving voltage (VD). can The DC/DC converter circuit 320 may convert an input voltage, for example, a battery voltage Vbat, into a driving voltage VD by turning the power semiconductor PS on and off at a predetermined period.

At this time, as the power semiconductor (PS) is turned on and off periodically, a switching loss occurs, and this switching loss appears larger when there is little or no load. Referring to FIG. 4 , it can be seen that the efficiency of the DC/DC converter circuit 320 is the worst in the non-sensing section in which the load of the DC/DC converter circuit 320 is the smallest.

Referring back to FIG. 3 , the driving power circuit 170 drives the DC/DC converter circuit 320 in the sensing section to reduce the loss (eg, switching loss) caused by the DC/DC converter circuit 320 . and the DC/DC converter circuit 320 may not be driven in the non-sensing period. From another point of view, the driving power circuit 170 may generate the driving voltage VD in the sensing section and not the driving voltage VD in the non-sensing section.

The PS control circuit 310 included in the driving voltage supply unit 172 may control the power semiconductor PS included in the DC/DC converter circuit 320 through the switch control signal Gs, and the driving voltage supply unit ( 172) may control the driving of the DC/DC converter circuit 320 through the switch control signal Gs. From another point of view, the driving voltage supply unit 172 may control the generation of the driving voltage VD through the switch control signal Gs.

The signal receiving unit 174 of the driving power circuit 170 receives the output control signal OCS from the touch driving circuit 150 , and the output control signal OCS may be transmitted to the driving voltage supply unit 172 . In addition, the PS control circuit 310 of the driving voltage supply unit 172 continuously turns off the power semiconductor PS when the disable signal DS is included in the output control signal OCS in such a way that the DC/DC converter The circuit 320 may be controlled not to generate the driving voltage VD.

Meanwhile, since a predetermined delay may occur in signal transmission and voltage supply, a certain margin period may exist between the sensing period and the output control signal.

5 is a diagram illustrating a margin section between a sensing section and an output control signal, and FIG. 6 is a diagram illustrating a margin section between a non-sensing section and an output control signal.

Referring to FIG. 5 , the enable signal ES may be transmitted with constant margin periods MJ1 and MJ2 before and after the sensing period. Specifically, the enable signal ES may be transmitted before the start time of the sensing period by the first margin period MJ1. In addition, the enable signal ES may be transmitted until later than the end time of the sensing period by the second margin period MJ2.

Meanwhile, the start time of the sensing period may be determined according to the touch enable signal T-EN generated by the timing control circuit 140 . The timing control circuit 140 generates a touch enable signal T-EN to control the driving timing for the touch electrode TE, and the touch driving circuit 150 uses the touch enable signal T-EN. A sensing section can be formed within the enable section of

A section in which the enable signal ES is transmitted in the output control signal OCS may also be determined according to the touch enable signal T-EN. For example, the touch driving circuit 150 may generate the enable signal ES with a predetermined offset interval OFFS1 and OFFS2 from the enable period of the touch enable signal T-EN.

Meanwhile, referring to FIG. 6 , the touch driving circuit 150 may transmit the disable signal DS in part or all of the non-sensing period in which the touch electrode TE is not driven. As a specific example, the disable signal DS may be transmitted with constant margin periods MJ1 and MJ2 before and after the non-sensing period. The disable signal DS may be transmitted later by the second margin period MJ2 than the start time of the non-sensing period, and the transmission may be terminated earlier than the end time of the non-sensing period by the first margin period MJ1.

A section in which the disable signal DS is transmitted from the output control signal OCS may also be determined according to the touch enable signal T-EN. The touch driving circuit 150 may generate the disable signal DS at regular offset intervals OFFS1 and OFFS2 based on the touch enable signal T-EN.

Meanwhile, in the embodiment described with reference to FIG. 3 , the driving power circuit 170 may output the driving voltage VD through the output capacitor C while including the output capacitor C . However, when the output capacitor (C) is connected to the touch electrode driving unit 152 of the touch driving circuit 150, the current flows through the leakage current path existing in the touch driving circuit 150, the output capacitor (C) Charges accumulated in the can be discharged. In other words, even in a situation where the driving power circuit 170 does not generate the driving voltage VD, power may be consumed while the output capacitor C is discharged.

7 is a view for explaining a phenomenon in which an output capacitor in the driving power circuit is discharged.

Referring to FIG. 7 , the driving voltage supply unit 172 included in the driving power circuit 170 may not generate the driving voltage VD by turning off the power semiconductor PS. However, even in a mode in which the driving power circuit 170 does not generate the driving voltage VD by turning off the power semiconductor PS, a constant charge may be accumulated in the output capacitor C. And, when the output capacitor (C) is connected to the touch electrode driving unit 152 of the touch driving circuit 150, the output capacitor (C) by the leakage current path Rleak located in the touch electrode driving unit 152 can be discharged.

When the charge of the output capacitor C is discharged, power corresponding to the amount of discharged charge must be additionally generated to generate a normal driving voltage VD again. This additionally generated power is one factor that increases power consumption.

When the charge of the output capacitor C is discharged, the risk of circuit damage due to an inrush current also increases. When the generation of the driving voltage VD is started, the DC/DC converter circuit 320 rapidly uses a large amount of current to charge the discharged output capacitor C, which may result in inrush current.

The display device 100 may further include a cut-off switch in a path through which the driving voltage VD is transmitted from the driving power circuit 170 to the touch driving circuit 150 to prevent the output capacitor C from being discharged. In addition, the display device 100 can completely block the driving voltage VD transmitted to the touch driving circuit 150 using such a cut-off switch, thereby preventing the output capacitor C from being discharged.

The cut-off switch may be located in the driving power circuit 170 , in the touch driving circuit 150 , or between the driving power circuit 170 and the touch driving circuit 150 .

When the cut-off switch is located in the driving power circuit 170 , one side of the cut-off switch may be connected to the touch driving circuit 150 and the other end may be connected to the driving voltage supply unit 172 . In addition, when the cut-off switch is positioned between the driving power circuit 170 and the touch driving circuit 150 , one side of the cut-off switch may be connected to the driving power circuit 170 and the other end may be connected to the touch driving circuit 150 .

8 is a view showing that the cut-off switch is located in the touch driving circuit.

Referring to FIG. 8 , one side of the cut-off switch SW may be connected to the driving power circuit 170 and the other side may be connected to the touch electrode driver 152 .

The switch gating signal GPWT for controlling the on/off of the blocking switch SW may be generated by the signal transmission unit 154 .

The cut-off switch SW may be turned off in part or all of the non-sensing period in which the touch electrode is not driven. Through this, it is possible to prevent discharge of the driving power circuit 170 due to the leakage current path Rleak.

The switch gating signal GPWT for controlling the cutoff switch SW may be synchronized with the output control signal OCS.

9 is a diagram illustrating a timing relationship between a switchgating signal and peripheral signals.

Depending on the type of the cut-off switch SW, the cut-off switch SW may be turned off by a high-level signal, and the cut-off switch SW may be turned off according to a low-level signal. The example shown in FIG. 9 shows that the cut-off switch SW is turned off by a high-level signal.

Referring to FIG. 9 , the switch gating signal GPWT may be synchronized with the output control signal OCS. When the output control signal OCS is the enable signal ES, the switch gating signal GPWT is a low level signal, and when the output control signal OCS is the disable signal DS, the switch gating signal GPWT is a high level signal. It could be a signal.

In this example, the cutoff switch SW may be turned off in response to the disable signal DS.

Meanwhile, in the above description, it is not assumed that the driving voltage VD is a single voltage. The driving voltage VD output from the driving power circuit 170 may include two or more driving voltages having different voltage levels. The output control signal OCS also does not assume a single signal. The touch driving circuit 150 may output two or more output control signals having different timings.

10 is a diagram illustrating an embodiment in which two driving voltages and two output control signals are transmitted/received between a driving power circuit and a touch driving circuit.

Referring to FIG. 10 , the driving power circuit 170 may supply a first driving voltage VD1 and a second driving voltage VD2 to the touch driving circuit 150 . In addition, the touch driving circuit 150 includes a first output control signal OCS1 for controlling the output of the first driving voltage VD1 and a second output control signal OCS2 for controlling the output of the second driving voltage VD2 may be transmitted to the driving power circuit 170 .

The driving power circuit 170 may supply the first driving voltage VD1 and the second driving voltage VD2 having different voltage levels to the touch driving circuit 150 . At this time, the driving power circuit 170 controls the output of the first driving voltage VD1 according to the first output control signal OCS1 and the output of the second driving voltage VD2 according to the second output control signal OCS2. can be controlled.

The first output control signal OCS1 and the second output control signal OCS2 may have different timings. In other words, the first output control signal OCS1 and the second output control signal OCS2 may be out of synchronization.

11 is a diagram illustrating timing of an output control signal of FIG. 10 .

Referring to FIG. 11 , the first output control signal OCS1 includes a first enable signal ES1 and a first disable signal DS1 , and the second output control signal OCS2 includes a second enable signal ( ES2) and a second disable signal DS2.

The first enable signal ES1 and the second enable signal ES2 may be transmitted to the driving power circuit 170 in different sections. For example, the first enable signal ES1 and the second enable signal ES2 may be transmitted with a sensing period and a constant margin period. However, in this case, the margin sections MJ1 and MJ2 between the sensing section and the first enable signal ES1 may be different from the margin sections MJ3 and MJ4 between the sensing section and the second enable signal ES2. .

The first disable signal DS1 and the second disable signal DS2 may be transmitted to the driving power circuit 170 in different sections. For example, the first disable signal DS1 and the second disable signal DS2 may be transmitted with a non-sensing period and a constant margin period. However, at this time, the margin sections MJ1 and MJ2 between the non-sensing section and the first disable signal DS1 may be different from the margin sections MJ3 and MJ4 between the non-sensing section and the second disable signal DS2. can

Timings of the first output control signal OCS1 and the second output control signal OCS2 may be determined based on the touch enable signal T-EN, and in this case, the first output control signal OCS1 and the second output The control signal OCS2 may have different timings from the touch enable signal T-EN by having different offset intervals OFFS1 and OFFS2, OFFS3 and OFFS4.

The first driving voltage VD1 and the second driving voltage VD2 transmitted to the touch driving circuit 150 may be used at different times. In this case, the touch driving circuit 150 may optimize power consumption by controlling the respective outputs of the driving voltages VD1 and VD2.

Terms such as "include", "comprise" or "have" described above mean that the corresponding component may be embedded unless otherwise stated, so it does not exclude other components. It should be construed as being able to further include other components. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs, unless otherwise defined. Terms commonly used, such as those defined in the dictionary, should be interpreted as being consistent with the meaning of the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present invention.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Claims (31)

a panel including a plurality of touch electrodes;
a data driving circuit for driving the display electrodes positioned on the panel;
a driving power circuit for supplying a driving voltage; and
A touch driving circuit receiving the driving voltage to generate a touch driving signal, driving the touch electrode with the touch driving signal, and transmitting an output control signal to the driving power circuit to control the output of the driving voltage
including,
The output control signal includes an enable signal and a disable signal,
The touch driving circuit starts transmitting the disable signal to the driving power circuit in a sleep mode in which the display electrode is not driven. delete According to claim 1,
Further comprising a processor for generating touch coordinate data according to the sensed value of the touch electrode,
The touch driving circuit,
The display device generates the sensed value according to a response signal received from the touch electrode and transmits the sensed value to the processor. 4. The method of claim 3,
The touch driving circuit,
The display device transmits a wake-up signal to the processor when the sensing value of the touch electrode is greater than a predetermined value in the sleep mode. 4. The method of claim 3,
The touch driving circuit,
The display device does not transmit the sensed value of the touch electrode to the processor in the sleep mode. According to claim 1,
The driving voltage is supplied to the touch driving circuit and the data driving circuit. According to claim 1,
The display device further comprising a logic power circuit for supplying logic power to the touch driving circuit. According to claim 1,
A display device in which the driving voltage is supplied when the enable signal is transmitted, and the driving voltage is not supplied when the disable signal is transmitted. 9. The method of claim 8,
A display device in which the disable signal is transmitted in part or all of a non-sensing section in which the touch electrode is not driven. 9. The method of claim 8,
Further comprising a cut-off switch located in a path through which the driving voltage is supplied from the driving power circuit to the touch driving circuit,
The blocking switch blocks the path in response to the disable signal. A touch driving signal is generated by receiving a driving voltage from the driving power circuit, a plurality of touch electrodes positioned on the panel are driven with the touch driving signal, and an output control signal for controlling the output of the driving voltage is sent to the driving power circuit a touch driving circuit that transmits; and
A data driving circuit for driving the display electrodes located on the panel
including,
The output control signal includes an enable signal and a disable signal,
and the touch driving circuit starts transmitting the disable signal to the driving power circuit in a sleep mode in which the display electrode is not driven. delete 12. The method of claim 11,
Further comprising a processor for generating touch coordinate data according to the sensed value of the touch electrode,
The touch driving circuit,
A driving integrated circuit for generating the sensed value according to a response signal received from the touch electrode and transmitting a wakeup signal to the processor when the sensed value is greater than a predetermined value. 12. The method of claim 11,
A driving integrated circuit in which the driving voltage is supplied when the enable signal is transmitted and the driving voltage is not supplied when the disable signal is transmitted. 15. The method of claim 14,
Further comprising a timing control circuit for generating a touch enable signal for controlling the driving timing for the touch electrode,
The touch driving circuit,
A driving integrated circuit for generating the enable signal at a predetermined offset interval from an enable period of the touch enable signal. a touch electrode driver receiving a driving voltage from a driving power circuit to generate a touch driving signal and driving a plurality of touch electrodes positioned on the panel with the touch driving signal; and
A signal transmission unit for transmitting an output control signal for controlling the output of the driving voltage to the driving power circuit
including,
The output control signal includes an enable signal and a disable signal,
In a sleep mode in which the display electrode positioned on the panel is not driven, the signal transmitter starts transmitting the disable signal to the driving power circuit in the sleep mode in which the display electrode is not driven. 17. The method of claim 16,
A touch driving circuit in which the driving voltage is supplied when the enable signal is transmitted, and the driving voltage is not supplied when the disable signal is transmitted. 18. The method of claim 17,
The signal transmission unit
A touch driving circuit for transmitting the enable signal in a sensing section for driving the touch electrode. 19. The method of claim 18,
The signal transmission unit,
A touch driving circuit for transmitting the enable signal with a predetermined margin period before and after the sensing period. 18. The method of claim 17,
The signal transmission unit,
A touch driving circuit for transmitting the disable signal in part or all of the non-sensing section. 17. The method of claim 16,
One side is connected to the driving power circuit and the other side further includes a cut-off switch connected to the touch electrode driving unit,
A touch driving circuit in which the cut-off switch is turned off in part or all of a non-sensing section in which the touch electrode is not driven. 22. The method of claim 21,
A switch gating signal for controlling on/off of the cut-off switch is synchronized with the output control signal. delete 17. The method of claim 16,
The touch electrode driving unit,
receiving a first driving voltage and a second driving voltage from the driving power circuit;
The signal transmission unit,
A touch driving circuit for transmitting a first output control signal for controlling an output of the first driving voltage and a second output control signal for controlling an output of the second driving voltage. 25. The method of claim 24,
The first output control signal and the second output control signal are out of synchronization with the touch driving circuit. 17. The method of claim 16,
The touch electrode driving unit,
Sensing a touch or proximity of an object to the panel according to a response signal received from the touch electrode,
The signal transmission unit,
A touch driving circuit for outputting a wake-up signal to another processor when a touch or proximity to the panel is sensed. a signal receiving unit for receiving an output control signal including an enable signal and a disable signal from a touch driving circuit for driving a plurality of touch electrodes located on the panel; and
A driving voltage supply unit for controlling the output of the driving voltage supplied to the touch driving circuit according to the output control signal
including,
The signal receiver starts to receive the disable signal in a sleep mode in which the display electrode positioned on the panel is not driven. 28. The method of claim 27,
The driving voltage supply unit,
A driving power circuit that outputs the driving voltage when the enable signal is received and does not output the driving voltage when the disable signal is received. 28. The method of claim 27,
The driving voltage supply unit,
A driving power circuit comprising a DC/DC converter circuit including a power semiconductor and controlling generation of the driving voltage through control of the power semiconductor. 28. The method of claim 27,
One side further includes a cut-off switch connected to the touch driving circuit and the other side is connected to the driving voltage supply,
The cut-off switch is a driving power circuit that is turned off in response to the disable signal. 28. The method of claim 27,
The signal receiving unit,
receiving a first output control signal and a second output control signal from the touch driving circuit;
The driving voltage supply unit,
supplying a first driving voltage and a second driving voltage having different voltage levels to the touch driving circuit, controlling the output of the first driving voltage according to the first output control signal, and controlling the output of the first driving voltage according to the second output control signal A driving power circuit for controlling the output of the second driving voltage.

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