KR20190016196A - Display driving device and display device including the same - Google Patents

Abstract

According to the present invention, disclosed is a display driving device for reducing EMI. The display driving device comprises: a clock data restoration circuit restoring a first clock signal from an input signal in which a clock is embedded in data; a read-out circuit sensing a touch of a display panel; and a selection unit providing either one of the first clock signal reconstructed by the clock data restoration circuit and a second clock signal generated inside the display driving device to the read-out circuit as a third clock signal for driving the read-out circuit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a display driving apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device, and more particularly, to a display driving device for driving a touch-sensitive display panel and a display device including the same.

The touch-sensitive display panel is being applied not only to portable terminals such as smart terminals but also to various electronic devices such as notebooks, monitors, and home appliances. Such a display panel can be divided into an add-on type and an in-cell type depending on the position of the touch sensor. In order to make the display panel slimmer, a conventional structure such as a common electrode is used as a touch sensing electrode An in-cell type touch technology which is utilized is applied to a display device.

The display driving apparatus for driving the display panel may include a lead-out circuit for sensing the touch of the display panel. The display driving apparatus according to the prior art receives a clock signal ECLK which is a TTL input of a single-ended type from the outside and drives a lead-out circuit. However, since the conventional display driver drives the readout circuit using a clock signal, which is a TTL input, it is disadvantageous in EMI (Electro Magnetic Interference).

SUMMARY OF THE INVENTION It is an object of the present invention to provide a display driving apparatus for reducing EMI and a display apparatus including the same.

A display driving apparatus according to an embodiment of the present invention includes: a clock data restoration circuit for restoring a first clock signal from an input signal in which a clock is embedded in data; A lead-out circuit for sensing a touch of the display panel; And a selection circuit for selecting one of the first clock signal reconstructed by the clock data reconstruction circuit and the second clock signal generated internally in order to drive the readout circuit to the readout circuit as a third clock signal, .

A display driving apparatus according to an embodiment of the present invention includes: a first clock source for generating a first clock signal from an input signal in which a clock is embedded in data; A second clock source for generating a second clock signal of a predetermined frequency by an internal oscillation; And a selector for selecting one of the first and second clock signals as a third clock signal and providing the third clock signal to a readout circuit for touch detection.

A display device according to an embodiment of the present invention includes a timing controller for providing an input signal with a clock embedded in data; And a second clock signal generator for generating a first clock signal based on the first clock signal or a second clock signal generated within the second clock signal according to a display on and off period, And a display driver that uses a signal to sense a touch.

According to embodiments of the present invention, since the touch of the display panel is detected using a clock signal reconstructed from an input signal having a clock embedded therein or an internally generated clock signal, a clock signal, which is a TTL input of a single- EMI can be reduced.

1 is a block diagram of a display driving apparatus and a display apparatus including the same according to an embodiment of the present invention.
2 is a timing chart for explaining the operation of FIG.
3 is a block diagram of a display driving apparatus and a display apparatus including the same according to another embodiment of the present invention.
4 is a diagram illustrating an input signal in which a clock signal is embedded in FIGS. 1 and 3. FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the terminology used herein is for the purpose of description and should not be interpreted as limiting the scope of the present invention.

The embodiments described in the present specification and the configurations shown in the drawings are preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention and thus various equivalents and modifications Can be.

1 is a block diagram of a display driving apparatus 20 and a display apparatus including the same according to an embodiment of the present invention.

1, the display device includes a timing controller 10, a display driving device 20, a microcontroller 30, and a display panel 40. [

The timing controller 10 receives image data and timing signals from a host system (not shown), performs image processing such as image quality compensation on the image data, and generates a differential signal (CEDA, CEDB) to the display driver 20. The display driver

The display driver 20 restores the first clock signal PCLK and the data DATA from the input signals CEDA and CEDB and outputs the restored first clock signal PCLK and data DATA to the display panel 20. [ (40) and detects the touch of the display panel (40) using the restored first clock signal (PCLK). Here, the display panel 40 is a display panel capable of touch sensing, and displays an image through a pixel array in which pixels are arranged in a matrix form, and can detect whether the touch is performed by a capacitance method using a common electrode and a touch electrode . Such a display driving apparatus 20 includes a clock data recovery circuit 22, a data driving circuit 24, an oscillator 32, a selector 34, and a lead-out circuit 36.

The clock data restoring circuit 22 restores the first clock signal PCLK and the video and control data DATA from the input signals CEDA and CEDB and outputs the restored first clock signal PCLK, DATA to the data driving circuit 24 and provides the restored first clock signal PCLK to the selector 34. [

The data driving circuit 24 provides the display panel 40 with the source signal Sn corresponding to the gray level value of the video data. The data driving circuit 24 includes a latch unit (not shown) for latching image data, a digital-to-analog converter (not shown) for converting the image data into a source signal Sn corresponding to the gray level value of the image data, And an output buffer (not shown) for buffering and outputting data to the display panel 40.

The oscillator 32 generates a second clock signal OSC_CLK having a preset frequency by the internal oscillation and provides it to the selector 34. The oscillator 32 can be configured to generate the second clock signal OSC_CLK during the display off period and disabled during the display on period. The display-off period may be defined as a period during which the input signals CEDA and CEDB are not input to the display driving device 20 as the shutdown period in which the timing controller 10 is off, May be defined as a period in which the input signals CEDA and CEDB are input to the display panel 40 and an image is displayed on the display panel 40. [ In one example, the oscillator 32 may be configured to receive the control signal CS from the microcontroller 30. [ The oscillator 32 may be enabled or disabled in response to the control signal CS. Here, the control signal CS has a logic level for disabling the oscillator 32 during the display on period and a logic level for enabling the oscillator 32 during the off period of the display.

The selector 34 selects one of the first clock signal PCLK reconstructed by the clock data reconstructing circuit 22 or the second clock signal OSC_CLK generated by the oscillator 32 by the touch of the display panel 40 And provides the third clock signal (CLK) to the readout circuit 36. The third clock signal (CLK) The selector 34 selects the first clock signal PCLK as the third clock signal CLK in the display-on period and the second clock signal OSC_CLK as the third clock signal CLK in the display-off period. Select.

For example, the selector 34 selects one of the first clock signal PCLK and the second clock signal OSC_CLK as the third clock signal CLK in response to the control signal CS of the microcontroller 30 And provides the third clock signal (CLK) to the lead-out circuit (36). The control signal CS has a logic level for selecting the first clock signal PCLK in the display on period and a logic level for selecting the second clock signal OSC_CLK in the off period of the display. That is, the selector 34 provides the first clock signal PCLK recovered from the input signal during the display-on period to the lead-out circuit 36 as the third clock signal CLK, And provides the second clock signal OSC_CLK generated at the set frequency to the readout circuit 36 as the third clock signal CLK.

The readout circuit 36 senses the touch of the display panel 40 using the third clock signal CLK provided from the selector 34 and outputs sensed data Tdata. The sensing data (Tdata) may be provided to the microcontroller (30). Here, the display panel 40 has a touch-compatible display function and may include touch electrodes included in the pixel array. For example, each of the touch electrodes is connected to the lead-out circuit 36 through signal lines, and may be formed to have a predetermined size including a plurality of pixels in consideration of a touch point size. The readout circuit 36 provides the touch drive signal Tx to the touch electrode of the display panel 40 in response to the clock signal CLK of the selector 34 and outputs the feedback signal Rx from the touch electrode . The lead-out circuit 36 can differentially amplify the touch driving signal Tx and the feedback signal Rx for each touch electrode and sense whether the touch is caused by a capacitance change due to the touch.

The readout circuit 36 provides the touch driving signal Tx to the touch electrode of the display panel 40 in response to the first clock signal PCLK selected as the third clock signal CLK in the display on period, And receives the feedback signal Rx from the touch electrode of the panel 40. [ The lead-out circuit 36 converts the feedback signal Rx into sense data Tdata, which is a digital signal, and provides it to the microcontroller 30. The microcontroller 30 can detect whether the display panel 40 is touched or touched by the change of the sensing data Tdata due to the capacitance change due to the touch. For example, the readout circuit 36 may include a divider that divides the restored first clock signal PCLK into a predetermined value, To provide a touch drive signal Tx.

The readout circuit 36 provides the touch driving signal Tx to the touch electrode of the display panel 40 in response to the second clock signal OSC_CLK selected as the third clock signal CLK in the display off period, A feedback signal Rx is received from the touch electrode of the panel 40 and it is possible to detect whether or not the display panel 40 is touched by the capacitance change due to the touch. In the display off period, since only the touch of the display panel 42 is detected, even if the second clock signal OSC_CLK of the oscillator 32 fluctuates, it is possible to sufficiently detect whether or not the touch panel is touched. For example, it is possible to detect whether or not a user touches the touch panel during a display-off period to perform a knock-on function of a smart phone or the like that allows the screen to be knocked on when the liquid crystal screen is turned off.

The readout circuit 36 detects the touch of the display panel 40 in response to the first clock signal PCLK selected as the third clock signal CLK in the display on period and outputs the third clock signal CLK in response to the second clock signal OSC_CLK selected as the clock signal CLK. Here, the first clock signal PCLK may be divided into a preset value in the display-on interval.

The microcontroller 30 provides the control signal CS to the selection unit 34 of the display driver 20. [ The microcontroller 30 controls the selecting unit 34 to select the second clock signal OSC_CLK generated by the oscillator in the display-off period. The microcontroller 30 controls the selector 34 to select the first clock signal PCLK restored by the clock data recovery circuit 22 during the display-on period. In one example, the microcontroller 30 may provide a low logic level control signal CS during the display on period and a high logic level control signal CS during the display off period. Then, the selector 34 selects the first clock signal PCLK in response to the low logic level control signal CS in the display-on period, and responds to the high logic level control signal CS in the display- To select the second clock signal OSC_CLK. Here, the control signal CS may be transmitted as a control packet through an interface between the microcontroller 30 and the display driving device 20, for example, SPI. The microcontroller 30 receives the sensed data Tdata from the lead-out circuit 36 and determines whether the display panel 40 is touched or touched by the change of the sensed data Tdata due to the touch have.

According to the present embodiment, the clock data recovery circuit 22 for recovering the first clock signal PCLK from the input signals CEDA and CEDB during the display-on period is used as the first clock source, And uses the oscillator 32, which generates the second clock signal OSC_CLK at the frequency, as the second clock source.

2 is a timing chart for explaining the operation of FIG.

1 and 2, the display driving apparatus 20 drives the lead-out circuit 36 using the first clock signal PCLK recovered from the input signals CEDA and CEDB during the display-on period, And drives the readout circuit 36 using the second clock signal OSC_CLK of the oscillator 32 during the display off period. For example, sensing whether the display panel 42 is touched during the display-off period can be used to perform a knock-on function of a smart phone or the like that knocks the screen in a state in which the liquid crystal screen is turned off. In the display off period, since the touch panel only detects whether the display panel 40 is touched, it can sufficiently detect whether the touch panel is touched by using the second clock signal OSC_CLK of the oscillator 32.

The present embodiment divides the first clock signal PCLK recovered from the input signals CEDA and CEDB during the display-on period and outputs the first clock signal PCLK to the display panel 40 using a divided internal clock signal And whether or not touch coordinates are detected. Touch coordinates can be used by the host system to execute commands or applications associated with touch coordinates. The host system can be a tablet or smart phone system, a computer, a TV system, a set-top box, and the like. A divider (not shown) for dividing the restored first clock signal PCLK may be included in the lead-out circuit 36. Or the divider may be included in the clock data recovery circuit 22 or may be located between the clock data recovery circuit 22 and the lead-out circuit 36.

3 is a block diagram of a display driving apparatus and a display apparatus including the same according to another embodiment of the present invention. The configuration overlapping with the embodiment of FIG. 1 is replaced or briefly described with reference to FIG.

3, the display device includes a timing controller 10, a display drive device 20, and a display panel 40. [

The timing controller 10 performs image processing such as image quality compensation on the image data, generates control data for controlling the operation timing of the display driving apparatus 20, and outputs the image and control data and the clock to a differential input signal (CEDA, CEDB). Then, the timing controller 10 provides differential input signals (CEDA, CEDB) in which the clock is embedded in the data to the display driving apparatus 20. [

The display driver 20 restores the first clock signal PCLK and the data DATA from the input signals CEDA and CEDB and outputs the restored first clock signal PCLK and the data DATA to the display panel 20, (40) and controls whether the display panel (40) is touched by using the first clock signal (PCLK). Such a display driving apparatus 20 includes a clock data recovery circuit 22, a data driving circuit 24, an oscillator 32, a selector 34, and a lead-out circuit 36.

The clock data restoring circuit 22 restores the first clock signal PCLK and the data DATA from the input signals CEDA and CEDB and outputs the restored first clock signal PCLK and data DATA to the data driving circuit And supplies the restored first clock signal PCLK to the selector 34. [

Then, the clock data restoring circuit 22 provides the lock signal LOCK to the selector 34. Here, the lock signal LOCK has different logic levels depending on the display on and off periods. For example, the clock data restoring circuit 22 provides the selector 34 with a lock signal LOCK of a high logic level during the period during which the differential input signals CEDA and CEDB are received, that is, during the display on period, A low level lock signal LOCK can be provided to the selector 34. [

The oscillator 32 generates a second clock signal OSC_CLK of a preset frequency by the internal oscillation and provides the second clock signal OSC_CLK to the selector 34. In one example, the oscillator 32 may be configured to be disabled during the display on period and enabled during the display off period. In one example, the oscillator 32 may be configured to receive the control signal CS from the microcontroller 30. [ The oscillator 32 may be enabled or disabled in response to the control signal CS. Here, the control signal CS has a logic level for disabling the oscillator 32 during the display on period and a logic level for enabling the oscillator 32 during the off period of the display. Selects one of the first clock signal PCLK and the second clock signal OSC_CLK as the third clock signal CLK in response to the lock signal LOCK and outputs the third clock signal CLK to the readout circuit 36). For example, the selector 34 selects the first clock signal PCLK in response to the lock signal LOCK of the high logic level during the display-on period, and outputs the lock signal LOCK of the low logic level And selects the second clock signal OSC_CLK in response. That is, the selector 34 selects the first clock signal PCLK restored by the clock data recovery circuit 22 as the third clock signal CLK in the display-on period, (OSC_CLK) as the third clock signal (CLK), and provides the third clock signal (CLK) to the lead-out circuit (36).

The readout circuit 36 detects the touch of the display panel 40 in response to the first clock signal PCLK or the second clock signal OSC_CLK provided as the third clock signal CLK from the selector 34 do. For example, the readout circuit 36 provides the touch driving signal Tx to the touch electrode of the display panel 40 in response to the first clock signal PCLK during the display-on period, And provides the touch driving signal Tx to the touch electrode of the display panel 40 in response to the signal OSC_CLK. The readout circuit 36 receives the feedback signal Rx from the touch electrode of the display panel 40 and senses whether the display panel 40 is touched by the capacitance change due to the touch.

The readout circuit 36 detects the touch of the display panel 40 in response to the first clock signal PCLK selected as the third clock signal CLK in the display on period and outputs the third clock signal CLK in response to the second clock signal OSC_CLK selected as the clock signal CLK. Here, the first clock signal PCLK may be divided into a preset value in the display-on interval.

4 is a diagram illustrating input signals (CEDA and CEDB) in which a clock signal is embedded in FIGS. 1 and 3. FIG.

Communication of data between the timing controller 10 and the display driving device 20 can be implemented in various ways. The present embodiment can transmit input signals (CEDA, CEDB) in a CEDS (Clock Embedded Data Signaling) manner. The CEDS scheme can be defined as a communication scheme in which data is packetized and transmitted so that the clock (CK) has a format embedded in the data.

As shown in FIG. 4, the input signal (CED A / B) in which the clock CK is embedded can be transmitted as data packets. For example, one packet may have 28 UI (unit interval), and each packet may contain 4 UI delimiters and 24 UI data. The delimiter of 4UI includes dummy (DMY) and clock (CK), and the data of 24UI can include image and control data. In FIG. 4, the delimiter is 4-bit data represented by "0011". Of the 4-bit data, "00" is a bit corresponding to the dummy DMY and "11" is a bit corresponding to the clock CK. The delimiter may be applied with the same number of bits and the same data value for all packets.

The clock data restoration circuit 22 can distinguish the packet data through the dummy bit DMY input as "00" and the edge of the first clock signal PCLK through the clock CK input as "11" And restore the first clock signal (PCLK) having 28 UI through the internal logic circuit. The clock data restoring circuit 22 can generate the sampling clock signals using the first clock signal PCLK and recover the data using the sampling clock signals.

The first clock signal PCLK restored by the clock data restoring circuit 22 is provided to the lead-out circuit 36 during the display-on period and can be used to detect whether the display panel 40 is touched or not have. The first clock signal PCLK may be divided into a preset value for use in sensing the touch panel and touch coordinates of the display panel 40. For example, when the data transfer rate is 2.0 Gb / s, the first clock signal PCLK has a frequency of 71.4 MHz and can be divided into an internal clock signal having a frequency of 17.85 Mhz. When the data transfer rate is 1.2 Gb / s, the first clock signal PCLK has a frequency of 42.8 Mhz, and can be divided into an internal clock signal having a frequency of 21.4 MHz or a frequency of 10.4 MHz. The first clock signal PCLK reconstructed from the input signals CEDA and CEDB in which the clock is embedded in the data or the second clock signal OSC_CLK generated in the interior of the display panel 40 Since the touch is detected, the EMI according to the clock signal (ECLK) which is a TTL input of the single-ended type can be reduced.

10: timing controller 20: display driving device
30: Microcontroller 40: Display panel
22: clock data restoring circuit 24: data driving circuit
32: Oscillator 34:
36: Lead-out circuit

Claims (15)

A clock data restoration circuit for restoring a first clock signal from an input signal having a clock embedded therein;
A lead-out circuit for sensing a touch of the display panel; And
And a selector for providing either one of the first clock signal reconstructed by the clock data reconstruction circuit and the second clock signal generated internally to the readout circuit as a third clock signal for driving the readout circuit, ;
And the display driver. The apparatus according to claim 1,
And selects the second clock signal as the third clock signal corresponding to a period during which the clock is not received. The apparatus according to claim 1,
And selects the first clock signal as the third clock signal during the display-on period and selects the second clock signal as the third clock signal during the display-off period. The method according to claim 1,
And an oscillator for generating the second clock signal of a predetermined frequency and providing the second clock signal to the selection unit. The apparatus according to claim 1,
And receives a control signal having a different logic level corresponding to the display-on period and the display-off period from the microcontroller, respectively. 6. The apparatus according to claim 5,
A display for selecting the first clock signal in response to the control signal at a logic level corresponding to the display on period and for selecting the second clock signal in response to the control signal at a logic level corresponding to the display off period, drive. The method according to claim 1,
Wherein the first clock signal restored from the input signal is divided into a predetermined value during a turn-on period of the display, and the readout circuit is driven by using the divided internal clock signal. The method according to claim 1,
Wherein the clock data restoration circuit provides the selection unit with a lock signal having different logic levels corresponding to the display on and off periods respectively,
Wherein the selection unit selects the first clock signal in response to the lock signal of the logic level corresponding to the display-on period and outputs the second clock signal in response to the lock signal of the logic level corresponding to the display- To the display driver. A first clock source for generating a first clock signal from an input signal having a clock embedded in the data;
A second clock source for generating a second clock signal of a predetermined frequency by an internal oscillation; And
A selector for selecting any one of the first and second clock signals as a third clock signal and providing the third clock signal to a readout circuit for touch detection;
And the display driver. 10. The apparatus according to claim 9,
And selects the second clock signal as the third clock signal corresponding to a period during which the clock is not received. 10. The apparatus according to claim 9,
And selects the first clock signal as the third clock signal during the display-on period and selects the second clock signal as the third clock signal during the display-off period. A timing controller for providing an input signal with a clock embedded in the data; And
And selects either the first clock signal or the second clock signal internally generated as the third clock signal according to the display on and off periods, and the third clock signal A display driver for use in sensing a touch;
. 13. The method of claim 12,
And a microcontroller for providing the display driver with the control signals having different logic levels corresponding to the display on and off periods, respectively,
Wherein the display driver selects the first clock signal in the display-on period and the second clock signal in the display-off period as the third clock signal in response to the control signal. 13. The display driving apparatus according to claim 12,
A clock data recovery circuit for recovering the first clock signal and data from the input signal;
A data driving circuit for providing source signals corresponding to the gradation of the data to the display panel;
A lead-out circuit for sensing a touch of the display panel; And
And selects either the first clock signal reconstructed by the clock data reconstruction circuit or the second clock signal internally generated as the third clock signal to drive the readout circuit, To the readout circuit;
. 15. The method of claim 14,
Wherein the clock data restoration circuit provides a lock signal having different logic levels to the selector in accordance with the display on and off periods,
And the selection unit selects the first clock signal in the display-on period and the second clock signal in the display-off period as the third clock signal in response to the lock signal.

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