KR20150074257A - Touch display device and method for driving the same - Google Patents

Abstract

The present invention relates to a touch display device which enables to prevent the signal to noise ratio of a detection signal from being reduced by interference of common voltage generated from a display panel, and a method for driving the same. The touch display device of the present invention comprises: a touch panel having a plurality of driving lines and sensing lines crossing each other; a sensing data read circuit for sequentially providing a driving signal to the driving lines, and reading the sensing data detected from the sensing lines whenever the driving signal is provided to each driving line, and storing the same; a touch control unit for analyzing the sensing data from the sensing data read circuit in order to calculate touch coordinate information with respect to touch points in the touch panel; a display panel for displaying an image corrected based on the touch coordinate information from the touch control unit; and a noise removal unit for transmitting a cancellation signal having an inverted state with respect to the common voltage provided to the display panel, to one or more sensing lines.

Description

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

The present invention relates to a touch display device, and more particularly, to a touch display device and a driving method thereof that can prevent the signal-to-noise ratio of a sensing signal from being reduced due to interference of a common voltage generated from a display panel.

A display panel is positioned below the touch panel, and the common voltage generated from the display panel also affects the touch panel. In particular, this common voltage must have its original DC level, but is affected by the data voltage periodically changing in polarity and is distorted to an AC level with rising ripple and falling ripple, Line to distort the sensing signal on the sensing line. As a result, the signal-to-noise ratio of the sensing signal is lowered, which is a serious problem in determining whether or not to accurately touch and touch coordinates.

  SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and provides a touch display device and a method of driving the touch display device, which can remove a common voltage by applying a cancel signal having an inverted form to a common voltage to a sensing line. There is a purpose.

According to an aspect of the present invention, there is provided a touch display device including: a touch panel having a plurality of driving lines and a plurality of sensing lines intersecting with each other; A sense data read circuit that sequentially supplies drive signals to the drive lines and reads and stores sense data detected from the plurality of sense lines each time a drive signal is supplied to each drive line; A touch controller for analyzing sensed data from the sensed data lead circuit to calculate touch coordinate information for touch points on the touch panel; A display panel on which a corrected image is displayed based on touch coordinate information from the touch control unit; And a noise eliminator for transmitting the cancel signal having the inverted form to the common voltage supplied to the display panel to at least one of the sense lines.

And a reverser for inverting the common voltage to generate the offset signal.

Further comprising: a common voltage stabilizing unit for generating a feedback signal for stabilizing a common voltage supplied to the display panel; A feedback signal from the common voltage stabilization unit is used as the offset signal.

The noise removing unit may include at least one sensing line; A signal transmission line to which the canceling signal is applied; And a dielectric formed between the signal transmission line and the at least one sensing line.

And the noise removing unit is a capacitor connected between the signal transmission line to which the offset signal is applied and the at least one sensing line.

According to another aspect of the present invention, there is provided a method of driving a touch display device including a touch panel including a plurality of driving lines and a plurality of sensing lines intersecting with each other; A sense data read circuit that sequentially supplies drive signals to the drive lines and reads and stores sense data detected from the plurality of sense lines each time a drive signal is supplied to each drive line; A touch controller for analyzing sensed data from the sensed data lead circuit to calculate touch coordinate information for touch points on the touch panel; And a display panel on which an image corrected by the touch coordinate information from the touch control unit is displayed, comprising: preparing a display panel having an inverted shape with respect to a common voltage supplied to the display panel, To the mobile terminal.

And generating the cancel signal by inverting the common voltage before transmitting the cancel signal to at least one of the sense lines.

And the offset signal is a feedback signal generated to stabilize a common voltage supplied to the display panel.

The noise removing unit may include at least one sensing line; A signal transmission line to which the canceling signal is applied; And a dielectric formed between the signal transmission line and the at least one sensing line.

And the noise removing unit is a capacitor connected between the signal transmission line to which the offset signal is applied and the at least one sensing line.

The touch display apparatus and the driving method thereof according to the present invention have the following effects.

In the present invention, by generating a canceling signal in which the distorted common voltage is inverted through an inversion or the like and inverted by 180 degrees with respect to the common voltage, and the canceling signal is applied to the sense lines through the noise removing capacitor, The common voltage on the sense line can be removed. Therefore, the touch display apparatus and the driving method thereof according to the present invention can greatly improve the signal-to-noise ratio for the sensing signal.

1 is a view illustrating a touch display device according to an embodiment of the present invention.
2 is a view showing a detailed configuration inside the touch panel of Fig. 1; Fig.
3 is a diagram for explaining a method for generating an offset signal;
4 is a diagram for explaining another method for generating an offset signal;
5 is a circuit diagram showing a circuit configuration between one sense line and a noise removing capacitor
6 is a view for explaining a method of forming a capacitor for removing noise
FIG. 7 is a table for comparing the signal-to-noise ratio before and after application of the offset signal

FIG. 1 is a view showing a touch display device according to an embodiment of the present invention, and FIG. 2 is a view showing the detailed structure of the inside of the touch panel of FIG.

1, the touch display apparatus according to the first embodiment of the present invention includes a touch panel 100, a sensed data lead circuit 101, a touch control unit 103, and a noise removing unit (NE) do.

The touch panel 100 includes a plurality of driving lines DRL1 to DRL5 crossing each other and a plurality of sensing lines SSL1 to SSL5. Each of the driving lines DRL1 to DRL5 is composed of a plurality of driving electrodes DE electrically connected to each other through a connection electrode CE. Each drive electrode DE has a rhombic shape. Each of the sensing lines SSL1 to SSL5 is formed of a plurality of sensing electrodes SE electrically connected to each other. Each sensing electrode SE has a rhombic shape.

FIG. 1 shows an example in which a plurality of driving lines DRL1 to DRL5 and a plurality of sensing lines SSL1 to SSL5 are formed on the same layer, and a driving electrode DE at a portion where a driving line and a sensing line cross each other, Are electrically connected to each other by a connecting electrode (CE) located on a different layer.

As shown in FIG. 2, a sense capacitor Cs is formed between the drive line and the sense line. When a specific portion of the touch panel 100 is touched by a finger or the like, the capacitance of the sense capacitor Cs located at the touched point changes. The coordinates of the touch position and the touch position are determined by the capacitance change of the sense capacitor Cs.

The sense data read circuit 101 sequentially supplies the drive signals DS1 to DS5 to the drive lines DRL1 to DRL5. In FIG. 1, five driving lines DRL1 to DRL5 are shown as an example. The first to fifth driving lines DRL1 to DRL5 are connected to the first driving line DRL1 to the fifth driving line DRL5 ). To this end, the sense data read circuit 101 sequentially supplies drive signals from the first drive line DRL1 to the fifth drive line DRL5.

Each time the drive signal is supplied to each drive line, the sense data read circuit 101 reads the sense signals detected from the plurality of sense lines SSL1 to SSL5, digitizes the read sense signals, And stores them in the inside. In FIG. 1, five sensing lines (SSL1 to SSL5) are shown as an example, and each time a driving signal is applied to one driving line, five sensing lines (SSL1 to SSL5) The sense signals SS1 to SS5 are read from the sense data read circuit 101. [ The sense data read circuit 101 digitizes each of the five sense signals SS1 to SS5, generates five sense data corresponding thereto, and stores the generated five sense data therein.

The sense data read circuit 101 includes a drive line scan section 101a and a data lead section 101b as shown in FIG.

The driving line scanning unit 101a sequentially supplies the driving signals to the driving lines DRL1 to DRL5 and the data reading unit 101b supplies a driving signal to the plurality of driving lines DRL1 to DRL5 The sensing signals detected from the sensing lines SSL1 to SSL5 are converted into digital signals and stored therein.

The touch control unit 103 analyzes the sensed data from the sensed data lead circuit 101 and calculates touch coordinate information for the touch points on the touch panel 100. [

1 and 2, a display panel is disposed under the touch panel 100, and the display unit of the touch panel is displayed on a display unit of the touch panel 103 based on the touch coordinate information from the touch control unit 103 The image is displayed.

The noise eliminator NE is for eliminating the noise applied to the sense lines SSL1 to SLL5, which applies the cancel signal Inv-Vcom supplied from the outside to at least one sense line. Here, the noise is due to the distortion of the common voltage applied to the display panel, and the cause of the distortion of the common voltage will be described as follows.

Generally, when an electric field in the same direction is continuously applied to a liquid crystal layer formed on a display panel, the liquid crystal layer is deteriorated. In order to prevent this deterioration, the polarity of the data voltage applied to the data line periodically changes. If the common voltage is greater than the common voltage applied to the common electrode, the data voltage becomes positive. If the common voltage is lower than the common voltage, the data voltage becomes negative. However, a coupling phenomenon occurs due to the parasitic capacitance formed at a portion where the common electrode and the data line cross each other, and the common voltage is distorted due to the polarity of the data voltage due to the coupling phenomenon. In other words, although the original common voltage is a direct-current voltage having a constant direct-current level, the common voltage is pulled up or down in the direction of the rising ripple and the falling ripple of the positive polarity data voltage and the negative polarity data voltage, The branch is distorted by the signal. The common voltage of the distorted AC type is applied to the sensing line of the touch panel 100 to distort the sensing signals on the sensing line.

In order to minimize the influence of the common voltage applied to the sense line, the noise remover NE outputs a cancel signal (Inv-Vcom) having a form inverted by 180 degrees with respect to the common voltage, that is, To at least one sensing line. Accordingly, the rising ripple and the falling ripple of the common voltage applied to the sense line can be removed by the falling ripple and the rising ripple of the cancel signal having the opposite form. Therefore, the influence of the common voltage can be removed from the sensing line, thereby preventing the sensing signal from being distorted.

The noise removing unit NE may include at least one noise removing capacitor Cne. In FIG. 2, two noise removing capacitors Cne are connected to two sense lines SS3 and SS4 Respectively. Although not shown, it is also possible that the noise removing capacitors Cne are connected to every sense line one by one. When a plurality of noise removing capacitors Cne are provided, each one of the terminals is connected to the corresponding sensing line, but each of the other terminals is commonly connected to one signal transmission line STL. The aforementioned cancel signal Inv-Vcom is applied to this signal transmission line STL.

3 is a diagram for explaining a method for generating the cancel signal (Inv-Vcom).

The display panel DP includes a lower substrate SUB having a plurality of gate lines GL and a plurality of data lines DL intersecting with each other and a lower substrate SUB (Not shown), wherein a common electrode CME is formed on the upper substrate. The inverter INV receives the disturbed common voltage Vcom from the common electrode CME and inverts it to generate the offset signal Inv-Vcom.

4 is a diagram for explaining another method for generating an offset signal.

The above-described distortion of the common voltage Vcom also affects the gate signal applied to the gate line GL. That is, due to the distortion of the common voltage Vcom, the low voltage of the gate signal is pulled up or pulled down in the direction of the rising ripple and the falling ripple of the positive data voltage and the negative data voltage and is distorted into a signal having an AC level.

The common voltage generating unit CVG senses a ripple in a low voltage of the gate signal and generates a feedback signal FBS having a magnitude opposite to the ripple. The feedback signal FBS is applied to the common electrode CME to remove the ripple of the common voltage Vcom applied on the common electrode CME. The cancel signal Inv-Vcom in the present invention can be replaced with the feedback signal FBS output from the common voltage generator CVG.

5 is a diagram showing a circuit configuration between one sense line SSL and a noise removing capacitor Cne.

As shown in FIG. 5, one sensing line SSL includes resistance components and capacitor components by a plurality of resistors R1 and R2 and capacitors C1, C2, and C3. The sensing signal applied to the sensing line SSL is input to the data reading unit 101b through an operational amplifier (OA).

On the other hand, the distorted common electrode Vcom generated from the common electrode CME of the display panel DP is supplied to the sensing line SSL through the ground and the capacitors C2 and C3, And the offset signal Inv-Vcom having a 180-degree phase reversal with respect to the common electrode Vcom is applied to the signal transmission line STL. This cancel signal Inv-Vcom is transmitted through the noise canceling capacitor Cne to the sense line SSL. Thus, the distorted common voltage Vcom applied to the sensing line SSL can be eliminated. On the other hand, when the common voltage Vcom is not distorted and the DC voltage is maintained, the common voltage Vcom of the DC level can not pass through the noise removing capacitor Cne. Therefore, when the common voltage maintains the normal DC level, the common voltage Vcom is blocked from being input to the sensing line SSL.

On the other hand, the drawing number V1 in Fig. 5 supplies power as a power source through the sense line SSL.

6 is a view for explaining a method of forming the noise removing capacitor Cne.

The noise removing capacitor Cne according to the present invention includes a sensing electrode SE constituting a sensing line, a signal transmission line STL facing the sensing electrode SE, And a second dielectric (DIE2) located between the sensing electrode SE and the signal transmission line STL. That is, the noise removing capacitor Cne is generated at a portion where the sensing electrode SE, the signal transmission line STL, and the dielectric DE2 overlap. Unexplained, drawing number DIE1 means the first dielectric.

It is also possible to use a separate single-piece capacitor instead of the structure shown in FIG. 6 to connect between the sensing line (or sensing electrode) and the signal transmission line STL.

7 is a table for comparing the signal-to-noise ratio (SNR) before and after application of the offset signal.

As shown in FIG. 7, when the offset signal is not applied, the influence of the noise (that is, the distorted common voltage) is largely affected, so that the magnitude of the signal sensed by the touch (Y axis of the graph) It can be seen that the SNR values are quite low.

However, when the offset signal is applied, the image of the noise is considerably reduced, so that the size of the signal sensed by the touch is considerably low in the absence of the touch. Also, after the touch is generated, it can be seen that the signal detected by the touch is significantly increased. Thus, it can be seen that the SNR value is considerably high.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents. Will be clear to those who have knowledge of.

DS #: 1st driving signal DRL #: 1st driving line
SS #: Detection signal SSL #: Detection line
101: sense data read circuit 101a: drive line scan section
101b: Data lead section 103: Touch control section
100: touch panel SE: sensing electrode
DE: drive electrode NE: noise rejection
Cne: capacitor for removing noise STL: signal transmission line
Inv-Vcom: offset signal

Claims (10)

A touch panel having a plurality of driving lines and a plurality of sensing lines intersecting with each other;
A sense data read circuit that sequentially supplies drive signals to the drive lines and reads and stores sense data detected from the plurality of sense lines each time a drive signal is supplied to each drive line;
A touch controller for analyzing sensed data from the sensed data lead circuit to calculate touch coordinate information for touch points on the touch panel;
A display panel on which a corrected image is displayed based on touch coordinate information from the touch control unit; And
And a noise eliminator for transmitting an offset signal having an inverted form to the common voltage supplied to the display panel, to at least one of the sensing lines. The method according to claim 1,
And a reverser for inverting the common voltage to generate the cancel signal. The method according to claim 1,
Further comprising: a common voltage stabilizing unit for generating a feedback signal for stabilizing a common voltage supplied to the display panel; And,
And a feedback signal from the common voltage stabilization unit is used as the offset signal. The method according to claim 1,
Wherein the noise eliminator comprises:
At least one sense line;
A signal transmission line to which the canceling signal is applied; And
And a dielectric formed between the signal transmission line and the at least one sensing line. The method according to claim 1,
Wherein the noise removing unit is a capacitor connected between a signal transmission line to which the offset signal is applied and the at least one sensing line. A touch panel having a plurality of driving lines and a plurality of sensing lines intersecting with each other; A sense data read circuit that sequentially supplies drive signals to the drive lines and reads and stores sense data detected from the plurality of sense lines each time a drive signal is supplied to each drive line; A touch controller for analyzing sensed data from the sensed data lead circuit to calculate touch coordinate information for touch points on the touch panel; And preparing a display panel on which an image corrected by the touch coordinate information from the touch controller is displayed,
And transmitting an offset signal having an inverted form to the common voltage supplied to the display panel, to at least one of the sensing lines. The method according to claim 6,
Further comprising the step of inverting the common voltage to generate the offset signal prior to transmitting the offset signal to at least one sensing line. The method according to claim 6,
Wherein the cancel signal is a feedback signal generated to stabilize a common voltage supplied to the display panel. The method according to claim 6,
Wherein the noise eliminator comprises:
At least one sense line;
A signal transmission line to which the canceling signal is applied; And
And a dielectric formed between the signal transmission line and the at least one sensing line. The method according to claim 6,
Wherein the noise removing unit is a capacitor connected between a signal transmission line to which the offset signal is applied and the at least one sensing line.

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