KR20100131049A - Touch screen lcd having improved speed operation with maintaining touching position detection ability and driving method therefor - Google Patents

Abstract

PURPOSE: A touch screen liquid crystal display device and a driving method thereof are provided to improve an operation speed by controlling a read circuit to output an operation result at a precharge period. CONSTITUTION: A display panel displays an image according to driving data. A read circuit senses the voltage level of a data line. The read circuit outputs output data at a precharge period according to sensing data. A source driver blocks the connection of the data line at a sensing period. The source driver precharges the data line at the precharge period and provides driving data to the data line at a display period. A gate driver drives a pixel gate line and a sensing gate line. A controller controls the read circuit, the source driver, and the gate driver.

Description

Touch screen LCD having improved speed operation with maintaining touching position detection ability And Driving Method therefor}

In order to more fully understand the drawings used in the detailed description of the invention, a brief description of each drawing is provided.

1 is a view showing a touch screen liquid crystal display device of the present invention.

FIG. 2 is a diagram illustrating a part of the display panel of FIG. 1.

FIG. 3 is a diagram for describing the readout circuit of FIG. 1.

4 is a view illustrating a method of driving a touch screen liquid crystal display device according to an embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a touch screen liquid crystal display device and a driving method thereof, and more particularly, to a touch screen liquid crystal display device and a driving method thereof for improving the operation speed while maintaining a high contact position sensing force of an object.

Recently, due to the convenience of use, a touch screen liquid crystal display device having a touch screen function has been widely used. The touch screen uses a photo current generated according to light reflected by an object to be contacted (for example, a finger or a touch pen) to refer to a charge (herein, referred to herein as 'organic charge' for convenience of description). Generated and sensed the influence of the organic charge, and is driven in such a manner as to detect the position of the contacted object.

At this time, it is very important to improve the operation speed while maintaining a high connection position sensing force of the object.

SUMMARY OF THE INVENTION An object of the present invention is to provide a touch screen liquid crystal display device and a driving method thereof for improving the operation speed while maintaining a high sensing force of a connection position.

One aspect of the present invention for achieving the above technical problem relates to a touch screen liquid crystal display device. The touch screen liquid crystal display device of the present invention is a display panel arranged on a matrix structure consisting of a plurality of rows and a plurality of columns, each including a plurality of pixel units each including a sensing element and a pixel element. A row is specified by a pair of sensing gate lines and a pixel gate line, and a column of the display panel is the display panel specified by a data line, and the sensing element generates organic charge generated by contact of an object. And in response to activation of the sensing gate line in a predetermined sensing period, the organic charge is driven to reflect the data in the data line, and the pixel element is activated in response to activation of the pixel gate line in a predetermined display period. Display video according to driving data The display panel is driven so as to; A reading circuit which senses the voltage level of the data line before and after the reflection of the organic charge in the sensing section and stores the sensed data and outputs output data according to the sensing data in a predetermined precharge section; A source driver which is disconnected from the data line in the sensing period, precharges the data line in the precharge period, and provides the driving data to the data line in the display period; A gate driver driving the pixel gate line and the sensing gate line; And a control unit controlling driving of the read circuit, the source driver, and the gate driver.

One aspect of the present invention for achieving the above another technical problem relates to a driving method of a touch screen liquid crystal display device. In the driving method of the touch screen liquid crystal display device of the present invention, in response to activation of the sensing gate line, the organic charge of the sensing element is reflected as the voltage level of the data line in the sensing section, and in the readout circuit, A) detecting a voltage level of the data line before and after the organic charge is reflected and storing the detected voltage as sensed data; B) outputting output data according to the sensed data in the precharge section; And C) in the display period, activating the pixel gate line to display an image according to the driving data on the pixel device.

For a better understanding of the present invention and its operational advantages, and the objects attained by the practice of the present invention, reference should be made to the accompanying drawings, which illustrate preferred embodiments of the invention, and the accompanying drawings. In understanding each of the figures, it should be noted that like parts are denoted by the same reference numerals whenever possible.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a touch screen liquid crystal display device of the present invention. Referring to FIG. 1, the touch screen liquid crystal display device of the present invention includes a display panel 100, a readout circuit 200, a source driver 300, a gate driver 400, and a controller 500.

The display panel 100 includes a plurality of pixel units 110 arranged on a matrix structure consisting of rows and columns. The display panel 100 is described in detail with reference to FIG. 2.

FIG. 2 is a diagram illustrating a part of the display panel of FIG. 1. Referring to FIG. 2, a row of the display panel 100 includes a pair of sensing gate lines (GSk and GSk + 1 are representatively shown in FIG. 2) and a pixel gate line (in FIG. 2). , GPk, GPk + 1 are representatively shown). In this case, the sensing gate lines GSk and GSk + 1 and the pixel gate lines GPk and GPk + 1 are both lines driven by the gate driver 400 and may be commonly referred to as “gate lines”.

In the present specification, a gate line connected to the pixel element 111 is called a 'pixel gate line GPk, GPk + 1', and a gate line connected to the sensing element 113 is a 'sensing gate line GSk, GSk +. 1) is called.

A column of the display panel 100 is specified as a data line (in FIG. 2, Di and Di + 1 are representatively shown).

Each of the pixel units 110 includes the sensing element 111 and the pixel element 113. The sensing element 111 generates organic charge generated by contact of an object, and responds to activation of the sensing gate lines GSk and GSk + 1 in a predetermined sensing section P-SEN (see FIG. 3). In addition, the organic charge is driven to reflect the data lines Di and Di + 1.

Specifically, the sensing element 111 is composed of a transistor 111a and a sensing cell 111b. The sensing cell 111b generates organic charges according to the contact of an object, and also senses the organic charges. In addition, the transistor 111a responds to the organic charge sensed by the sensing cell 111b in response to activation of the sensing gate lines GSk and GSk + 1 in the sensing section P-SEN. Reflected to the data lines Di and Di + 1.

Here, the sensing element 111 generates an organic charge by a photo current generated according to light reflected by an object (for example, a finger or a touch pen) that is in contact with the light sensor ( Optical Sensor).

The pixel element 113 may display an image according to the driving data DAR in response to activation of the pixel gate lines GPk and GPk + 1 in a predetermined display period P-DIS (see FIG. 3). Driven.

Specifically, the pixel element 113 is composed of a transistor 113a and a pixel 113b. The transistor 113a is transmitted through the corresponding data lines Di and Di + 1 in response to the activation of the corresponding pixel gate lines GPk and GPk + 1 in the display period P-DIS. The driving data DAR is transmitted to the pixel 113b. The pixel 113b is driven to display an image according to the driving data DAR.

Referring back to FIG. 1, the read circuit 200 detects and detects a voltage level of the data lines Di and Di + 1 before and after the organic charge is reflected in the sensing section P-SEN. Data (in this specification, 'voltage level of the data line Di, Di + 1 before the organic charge is reflected' and 'voltage level of the data line Di, Di + 1 after the organic charge is reflected' The data is stored as 'any data' according to the difference between the output data DOUT and the output data DOUT according to the sensed data in a predetermined precharge period (P-PRE, see FIG. 3).

In addition, the source driver 300 is disconnected from the data lines Di and Di + 1 in the sensing period P-SEN, and the data line in the precharge period P-PRE. Di and Di + 1 are precharged, and the driving data DAR is provided to the data lines Di and Di + 1 in the display period P-DIS.

In this case, the precharge section P-PRE is performed between the sensing section P-SEN and the display section P-DIS.

In addition, it will be apparent to those skilled in the art that the precharge of the data lines Di and Di + 1 may be performed in various ways. For example, the data lines Di and Di + 1 may be controlled by a predetermined precharge voltage (eg, VCC / 2), and may be charged between a plurality of data lines Di and Di + 1. It may be performed by charge sharing.

Meanwhile, the sensing period P-SEN, the precharge period P-PRE, and the display period P-DIS are provided with an impedance state signal SOZ and a source enable provided to the source driver 300. It may be specified by the signal SOE.

In the present embodiment, when the impedance state signal SOZ is "H" and the source enable signal SOE is "L", it is specified as the sensing period P-SEN. When the impedance state signal SOZ is "L" and the source enable signal SOE is "H", it is specified as the precharge period P-PRE. When the impedance state signal SOZ and the source enable signal SOE are both “L”, the display period P-DIS is specified.

The gate driver 400 drives the sensing gate lines GSk and GSk + 1 and the pixel gate lines GPk and GPk + 1.

3 is a diagram for describing the read circuit 200 of FIG. 1, and a read circuit 200 corresponding to one data line Di is representatively shown.

Referring to FIG. 3, the read circuit 200 includes a charge integrated amplifier 210, a first current driver 220, a second current driver 230, and an operator 240.

The charge integrated amplifier 210 integrates and converts a current component of the data line Di into a voltage component and amplifies the converted voltage component of the data line Di. In a preferred embodiment, the output of the charge integrated amplifier 210 is reset to the reference voltage VREF in response to the reset signal RESET.

The first current driver 220 is driven to enhance the driving capability of the output of the charge integrated amplifier 210 in response to the activation of the first sensing signal SH1. The second current driver 230 is driven to enhance the driving capability of the output of the charge integrated amplifier 210 in response to the activation of the second sensing signal SH2.

In this case, the first sensing signal SH1 is activated before reflecting the organic charge generated in the sensing cell 111b (see FIG. 2) to the data line Di according to the contact of an object. That is, activation of the first sensing signal SH1 is generated as a pulse before activation of the sensing gate line GSk. Accordingly, the voltage level VSEN1 corresponding to the voltage level of the data line Di before the organic charge is reflected is stored in the capacitor 221 of the first current driver 220.

The second sensing signal SH2 is activated after reflecting the organic charge generated in the sensing cell 113b to the data line Di according to the contact of an object. That is, activation of the second sensing signal SH2 is generated as a pulse after activation of the sensing gate line GSk. Accordingly, the voltage level VSEN2 corresponding to the voltage level of the data line Di after the organic charge is reflected is stored in the capacitor 231 of the second current driver 230.

In the present specification, the sensing data D-SEN may be a difference between the voltage level VSEN1 of the capacitor 221 and the voltage level VSEN2 of the capacitor 231.

The calculator 240 calculates outputs of the first current driver 220 and the second current driver 230. The calculator 240 outputs the calculation result as the output data DOUT in response to the output start signal XST activated in the precharge period P-PRE. In this case, the output data DOUT represents a change in current and / or voltage component of the sensing line Si due to the organic charge.

Referring back to FIG. 1, the controller 500 may include the reset signal RESET, the first and second detection signals SH1 and SH2, the impedance state signal SOZ and the source enable signal SOE. Is generated to control the read circuit 200, the source driver 300, and the gate driver 400.

In this case, the controller 500 controls the readout circuit 200 to sense the voltage level of the data line before and after the reflection of the organic charge and to store the sensed data in the sensing section P-SEN. In the display period P-DIS, the driving data DAR is provided to the data line Di, and the source driver 300 is controlled to display an image accordingly.

In the touch screen liquid crystal display device of the present invention, the timing at which the output data DOUT is output is not overlapped with the timing at which the source driver 300 provides the driving data DAR on the data line Di. Contact position sensing force can be maintained. In addition, while the data line Di is precharged between the sensing section P-SEN and the display section P-DIS, that is, to output the calculation result in the precharge section P-PRE. By controlling the readout circuit 200, the operation speed is significantly improved.

4 is a view illustrating a method of driving a touch screen liquid crystal display device according to an embodiment of the present invention, which is a driving method for the touch screen liquid crystal display device of FIG. 1.

Referring to FIG. 4, the driving of the touch screen liquid crystal display device according to the present invention may be divided into the sensing period P-SEN, the precharge period P-PRE, and the display period P-DIS. have.

In the sensing period P-SEN, the connection between the source driver 300 (see FIG. 1) and the data lines Di and Di + 1 is cut off. In response to the activation of the sensing gate line GSk, the organic charge of the sensing element 111 is reflected as the voltage level of the data line Di, and in the readout circuit 200, the organic charge Senses the voltage level of the data line before and after reflection of the data line and stores it as the sensing data D-SEN.

The operation of the main signals of the present invention in the sensing period P-SEN will be described in detail as follows.

At a time t11, the reset signal RESET is activated, and the voltage level of the data line Di is reset. At the time t12, the reset signal RESET is deactivated to "L".

Then, at time t13, the first sensing signal SH1 is activated in the form of a pulse. That is, the first sensing signal SH1 is activated by a pulse before the sensing gate line GSk. In this case, the first current driver 220 of the read circuit 200 may set the voltage level VSEN1 according to the level of the data line Di before the organic charge of the sensing element 111 is reflected. Store at 221.

The sensing gate line GSk is activated at a time point t14 after the first detection signal SH1 is generated as a pulse. Subsequently, after time t15 when the sensing gate line GSk is inactivated, at time t16, the second sensing signal SH2 is activated in the form of a pulse. That is, the second sensing signal SH2 is activated by a pulse after the sensing gate line GSk is activated. In this case, the second current driver 230 of the readout circuit 200 is applied to the level of the data line Di after the organic charge of the sensing element 111 connected to the sensing gate line GSk is reflected. The voltage level VSEN2 is stored in the capacitor 231.

Subsequently, in the precharge period P-PRE, the data line Di is precharged. In addition, while the data line Di is precharged, the readout circuit 200 outputs output data DOUT according to the sensing data D-SEN.

In the present embodiment, in response to the output start signal XST activated in the precharge section P-PRE (t21), the readout circuit 200 according to the sensing data D-SEN The operation result is output as the output data DOUT (t22).

In the display period P-DIS, driving data DAR are provided to the data line Di. In addition, in the display period P-DIS, the pixel gate line GPk is activated (t31) to display an image according to the driving data DAR on the pixel element 113.

According to the touch screen liquid crystal display device of the present invention as described above, the timing for outputting the output data DOUT is not overlapped with the timing at which the source driver 300 provides the driving data DAR to the data line Di. Contact position sensing force of a high object can be maintained. In addition, while the data line Di is precharged between the sensing section P-SEN and the display section P-DIS, that is, to output the calculation result in the precharge section P-PRE. By controlling the readout circuit 200, the operation speed is significantly improved.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (8)

In the touch screen liquid crystal display device, A display panel arranged on a matrix structure consisting of a plurality of rows and a plurality of columns, each including a plurality of pixel units including sensing elements and pixel elements, wherein the rows of display panels comprise a pair of sensing gate lines; The display panel is specified by a pixel gate line, and a column of the display panel is specified by a data line, wherein the sensing element generates organic charge generated by contact of an object, and the sensing gate is detected in a predetermined sensing section. In response to the activation of the line, the organic charge is driven to reflect the data line, and the pixel element is driven to display an image according to driving data in response to the activation of the pixel gate line in a predetermined display period. The display panel; A reading circuit which senses the voltage level of the data line before and after the reflection of the organic charge in the sensing section and stores the sensed data and outputs output data according to the sensing data in a predetermined precharge section; A source driver which is disconnected from the data line in the sensing period, precharges the data line in the precharge period, and provides the driving data to the data line in the display period; A gate driver driving the pixel gate line and the sensing gate line; And And a controller for controlling driving of the readout circuit, the source driver, and the gate driver. The method of claim 1, wherein the precharge section is And a touch screen between the sensing section and the display section. The method of claim 1, wherein the readout circuit A charge integrated amplifier configured to integrate current components of the data line and amplify the voltage components into voltage components; A first current driver driven to enhance driving capability of an output of the charge integrated amplifier in response to a first sense signal; A second current driver driven to enhance driving capability of an output of the charge integrated amplifier in response to a second sensed signal; And A calculator for calculating outputs of the first current driver and the second current driver, The calculator And a calculation result is output in the precharge section. The method of claim 3, wherein the calculator And outputting the calculation result as the output data in response to an output start signal activated in the precharge section. The method of claim 3, Activation of the first detection signal is A pulse is generated prior to activation of the sensing gate line, Activation of the second detection signal is And a pulse generated after activation of the sensing gate line. A method of driving a touch screen liquid crystal display device including a display panel, a readout circuit, and a source driver, wherein the display panel is arranged on a matrix structure having a plurality of rows and a plurality of columns, each of which includes a sensing element and a pixel element. A plurality of pixel units, wherein the row of pixel units is specified by a pair of sensing gate lines and pixel gate lines, and a column of the pixel units is specified by a data line of the touch screen liquid crystal display device. As a driving method, the sensing element generates organic charge generated by contact of an object, and the source driver is disconnected from the data line in a predetermined sensing period, and the data line in a predetermined precharge period. Precharges the display In the driving method of the touch screen liquid crystal display device for providing driving data to the data line in the interval, In the sensing period, in response to the activation of the sensing gate line, the organic charge of the sensing element is reflected as the voltage level of the data line, and in the readout circuit, the voltage of the data line before and after the reflection of the organic charge A) detecting the level and storing it as sense data; B) outputting output data according to the sensed data in the precharge section; And And displaying the image according to the driving data on the pixel element by activating the pixel gate line in the display section. The method of claim 6, wherein the precharge section is And a driving period between the sensing section and the display section. The method of claim 6, wherein the step B) And outputting the output data in response to a predetermined output start signal.

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