KR101674880B1 - Liquid Crystal Display Device With Interred Touch Screen And Method For Driving The Same - Google Patents

Abstract

More particularly, the present invention relates to a liquid crystal display, and more particularly, to a liquid crystal display device in which at least two or more touch electrodes of a touch screen using a self-capping method are connected to a group touch electrode switcher, The liquid crystal display device being capable of being applied to the touch electrodes of the touch screen. To this end, the touch screen built-in liquid crystal display device according to the present invention comprises: a panel having pixels defined by intersections of data lines and gate lines; A touch screen including a plurality of touch electrodes built in the panel and touch electrode wires connected to the plurality of touch electrodes; A display driver IC for controlling the data lines and the gate lines formed in the panel and applying a common voltage or a touch pulse to the touch electrodes; And a touch IC which is driven in a self-capping manner and detects whether the touch electrodes are touched by applying the touch pulse to the touch electrodes through the display driver IC.

Description

TECHNICAL FIELD [0001] The present invention relates to a liquid crystal display (LCD)

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device, and more particularly, to a liquid crystal display device in which a capacitive touch screen is integrated.

As a portable electronic device such as a mobile communication terminal or a notebook computer develops, a demand for a flat panel display device (Flat Panel DIPSlay Device) is increasing. Among such flat panel display devices, a liquid crystal display device (liquid crystal display device) is expanding in application field due to advantages of mass production technology, ease of driving means, high image quality, and large screen realization.

2. Description of the Related Art In recent years, a touch screen capable of inputting information directly by a user using a finger or a pen has been applied instead of an input device such as a mouse or a keyboard, which has been conventionally applied as an input device of a liquid crystal display device.

In particular, in the case of a portable terminal such as a smart phone, a touch screen built-in liquid crystal display device in which a touch screen is embedded in a liquid crystal panel for slimming is being developed in applying a touch screen to a liquid crystal display device.

FIG. 1 is a diagram illustrating a configuration of a conventional touch screen built-in liquid crystal display device, and is an example of a configuration of a portable terminal such as a smart phone. FIG. 2 is an exemplary diagram illustrating a timing at which a common voltage Vcom and a touch pulse are applied to a panel in a conventional touch screen built-in liquid crystal display device.

As shown in FIG. 1, a touch screen built-in type liquid crystal display device, which is applied to a portable terminal, includes a panel 10 in which a touch screen 60 is built, A display driver IC (DDI) 20 for controlling gate lines and data lines in the panel, and a touch screen driver IC (hereinafter, simply referred to as 'touch IC') for driving a touch screen inside the panel An FPC (Flexible Printed Circuit) 40 for DDI for connecting the display driver IC 20 and an external system, and an FPC 50 for a touch IC for connecting a touch screen with a touch IC have.

The method of configuring the touch screen may be classified into a self cap method and a mutual method.

In the conventional in-cell touch liquid crystal display device having a built-in touch screen using a self-cap type, as shown in FIG. 1, each of the touch electrodes 61, The number of the nxm line channels is required in consideration of the number of the horizontal direction touch electrodes n and the number of the vertical direction touch electrodes m.

Therefore, the number of effective channels of the corresponding touch IC 30 is n x m. If the number of channels of the touch IC 30 is insufficient, a plurality of touch ICs 30 must be used as shown in Fig. 1. In this case, the size and wiring process of the FPC 50 for a touch IC are complicated .

As shown in FIGS. 1 and 2, the touch screen built-in liquid crystal display device uses a touch electrode as a common electrode during an image display period, Time-division driving is necessary because it is used as an electrode.

That is, as shown in FIG. 2, a touch pulse is applied to the touch electrode through the channel of the touch IC 30 during the touch sensing period (Touch) (5.7 ms). If three touch ICs (IC1, IC2, IC3) 30 are used, as shown in FIG. 2, each of the three touch ICs IC1, IC2, ) (5.7 ms) to the corresponding touch electrode.

On the other hand, since the common voltage Vcom is applied to the touch electrode 61 through the channel of the touch IC during the video display period (Diplay) (11 ms), as shown in FIG. 1, The common voltage Vcom is supplied to the touch IC 30.

At this time, when the common voltage Vcom is a negative voltage, the touch IC 30 must be able to receive a negative voltage. However, the conventional touch ICs can not accommodate the negative voltage, and when the negative voltage can be accommodated, the manufacturing cost of the touch IC is increased.

Therefore, since the conventional touch ICs 30 supply the ground level (GND level) voltage to the panel 10 with the common voltage Vcom in the video display period, deterioration of the picture quality can be caused.

That is, the conventional touch screen built-in liquid crystal display device has the following problems.

First, as the number of touch channels mapped to the touch IC 30 increases, the number of touch ICs increases, thereby increasing the manufacturing cost.

Secondly, as the number of touch channels is increased, the area of the FPC 50 for a touch IC for connecting the touch screen to the touch IC is increased, which complicates the wiring process, thereby increasing the manufacturing cost.

Third, the selection of the touch IC 30 is limited in order to apply the (-) common voltage Vcom. In addition, when the conventional touch IC is applied, the display quality can be deteriorated.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to solve at least two or more touch electrodes of a touch screen using a self-capping method, The liquid crystal display device being capable of being applied to the touch electrodes of the touch screen.

According to an aspect of the present invention, there is provided a touch screen built-in liquid crystal display device including: a panel having pixels defined by intersections of a data line and a gate line; A touch screen including a plurality of touch electrodes built in the panel and touch electrode wires connected to the plurality of touch electrodes; A display driver IC for controlling the data lines and the gate lines formed in the panel and applying a common voltage or a touch pulse to the touch electrodes; And a touch IC which is driven in a self-capping manner and detects whether the touch electrodes are touched by applying the touch pulse to the touch electrodes through the display driver IC.

According to another aspect of the present invention, there is provided a method of driving a touch screen built-in liquid crystal display device, the method including driving a 0th touch synchronous signal and a 0th channel switching signal by at least two or more touch electrode lines, Connecting the common voltage generator to all of the touch electrode lines connected to the group touch electrode switcher when the group touch electrode switchers are connected to the group touch electrode switchers, And when the first touch synchronizing signal and the first channel switching signal are transmitted to each of the group touch electrode switches, a touch IC using the cap scheme is applied to the touch electrode switching And sequentially connecting the plurality of touch electrode lines to the plurality of touch electrode lines connected to the plurality of touch electrode lines.

Here, the number of the touch electrode lines connected to the group touch electrode switches may be a multiple of the number of the touch IC channels connecting the group touch electrode switches and the touch IC. The step of connecting the common voltage generator to all of the touch electrode lines may include generating the 0th touch synchronizing signal when the video display period arrives and transmitting the 0th touch synchronizing signal to the first switch of each of the group touch electrode switches Generating the zeroth channel switching signal and transmitting the zeroth channel switching signal to a second switch of the group touch electrode switch; The first switch is switched according to the 0th touch synchronous signal and is connected to the common voltage generator, and the second switch is switched according to the 0th channel switching signal, so that all the touch electrode wirings ; And from the common voltage generator to the touch electrode lines through the touch electrode lines connected to the first switch, the second switch, and the second switch of the group touch electrode switcher And supplying a common voltage to the touch electrodes. Wherein the step of sequentially connecting the touch IC to the touch electrode lines connected to the touch electrode switching unit includes generating a first touch synchronizing signal when the image display period ends and the touch display period comes, Transmitting the first channel switching signal to the first switch and generating a first channel switching signal to the second switch; The first switch is switched according to the first touch synchronizing signal and is connected to the touch IC, and the second switch is switched according to the first channel switching signal to switch all the touch electrode wirings Sequentially connecting the plurality of optical fibers to each other; Sequentially supplying a touch pulse applied from the touch IC to all the touch electrode wirings while the second switching unit is sequentially connected to all the touch electrode wirings; And sensing whether the touch IC touches the touch electrode connected to the touch electrode lines using the touch pulse. Wherein the second switch is sequentially connected to all the touch electrode lines connected to the group touch electrode switch, the first switch is switched according to the first touch synchronizing signal and is connected to the touch IC ; During the first period divided by the number (n) of the touch electrode lines connected to the group touch electrode switch during the touch sensing period, the second switch is switched according to the first channel switching signal, To the first touch electrode line among the first touch electrode lines; The second switching unit is switched according to a second channel switching signal to be connected to a second one of the plurality of touch electrode lines during a second period subsequent to the first period; And the second switching unit is switched according to an n-channel switching signal to be connected to an nth touch electrode wiring among the touch electrode wirings during an n-th period subsequent to the second period.

According to the above-mentioned solution, the present invention provides the following effects.

That is, according to the present invention, at least two or more touch electrodes of a touch screen using a self-cap scheme are connected to a group touch electrode switcher, and a common voltage or a drive voltage is applied to each touch electrode through a switch, The number of channels of the touch IC itself or the number of the touch IC itself can be reduced.

In addition, the present invention provides an effect that a general-purpose touch IC can be used without any restriction if a control unit capable of controlling the group touch electrode switcher and the group touch electrode switcher is incorporated in the display driver IC.

FIG. 1 is a view showing a configuration of a conventional touch screen built-in liquid crystal display device. FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a touch panel.
3 is a diagram illustrating a panel configuration of a touch screen built-in liquid crystal display device according to the present invention.
4 is an exemplary view showing an internal configuration of a display driver IC applied to a touch screen built-in liquid crystal display device according to the present invention.
FIG. 5 is an exemplary diagram illustrating a timing at which a common voltage Vcom and a touch pulse are applied to a panel in a touch-screen built-in liquid crystal display device according to the present invention. FIG.

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

3 is a diagram illustrating a panel configuration of a liquid crystal display device with a built-in touch screen according to the present invention.

[0001] The present invention relates to a capacitive touch screen built-in liquid crystal display device employing a self cap method, and a touch screen built-in liquid crystal display device requires a large number of channels, do.

That is, the present invention is to reduce the number of channels of the touch IC or the number of touch ICs and to achieve rapid commercialization, and it has a built-in mux in the display driver IC and connects to group touch electrode switches And the common voltage Vcom is simultaneously applied to all the touch electrodes connected to the group touch electrode switches during the video display period.

For this, as shown in FIG. 3, the touch screen built-in liquid crystal display according to the present invention includes a panel 110 formed with pixels defined by the intersection of a data line and a gate line, A touch screen 130 formed of touch electrode 131 and touch electrode wirings connected to the touch electrodes, a data line and a gate line formed in the panel, and a common voltage is applied to the touch electrode And a touch IC 140 for sensing whether the touch electrode is touched by applying a touch pulse to the plurality of touch electrodes. Here, the touch IC 140 may be connected to the display driver IC 120 through the FPC 150 for a touch IC, or may be formed inside the display driver IC.

First, the panel 110 may be configured such that a liquid crystal layer is formed between two glass substrates.

In this case, the lower glass substrate of the panel 110 includes a plurality of data lines, a plurality of gate lines crossing the data lines, a plurality of TFTs (Thin Film Transistors) formed at intersections of the data lines and the gate lines, , A plurality of pixel electrodes for charging the data voltage to the pixel, and a common electrode (touch electrode) for driving the liquid crystal filled in the liquid crystal layer together with the pixel electrode, by the intersection structure of the data lines and the gate lines The pixels are arranged in a matrix form.

A black matrix (BM) and a color filter are formed on the upper glass substrate of the panel 110.

Polarizing plates POL1 and POL2 are attached to the upper glass substrate and the lower glass substrate of the panel 110, respectively, and an alignment film is formed on the inner surface of the panel 110 in contact with the liquid crystal to set the pretilt angle of the liquid crystal. A column spacer CS for maintaining a cell gap of the liquid crystal cell may be formed between the upper glass substrate and the lower glass substrate of the panel 110. [

That is, the present invention relates to a touch screen built-in liquid crystal display device including a touch electrode constituting a touch screen in a panel as described above.

Next, the touch screen 130 performs a function of detecting whether or not the user touches the touch screen 130. Particularly, the touch screen 130 applied to the present invention is a capacitive touch screen using a self cap scheme . The touch screen 130 includes a plurality of touch electrodes 131 and a plurality of touch electrode wires 132.

Each of the plurality of touch electrodes may be formed over a plurality of pixels formed on the panel. The touch electrode 131 senses whether or not it is touched by the touch pulse applied from the touch IC during the touch sensing period and drives the liquid crystal along with the pixel electrode formed in each pixel during the display period .

Each of the plurality of touch electrode wirings 132 is connected to the touch electrode 131, and the end of the plurality of touch electrode wirings 132 is connected to the display driver IC 120 through a non-display region of the panel.

3, the display driver IC 120 controls the data lines and the gate lines, and applies a common voltage or a touch pulse to the touch electrodes. As shown in FIG. 3, And the touch IC 140, respectively.

That is, the display driver IC 120 generates a gate control signal (GCS) and a data control signal (DCS) by using a timing signal transmitted from an external system to output an image to the panel, And performs the function of rearranging the signals according to the structure of the panel.

The display driver IC 120 applies a common voltage to the touch electrodes 131 during an image display period for outputting an image, and during a touch sensing period for sensing a touch, And a function of supplying a touch pulse to the touch electrode 131.

The display driver IC 120 performs a function of connecting the touch electrode 131 and the touch IC 140. That is, the sense signal sensed through the touch electrode 131 is transmitted through the touch driver IC 120 IC 140 and analyzed.

On the other hand, when the number of the touch electrodes 131 constituting the touch screen 130 is 240, the number of the touch electrode wires 132 is also 240. The 240 touch electrode wirings 132 are connected to the display driver IC 120 in a non-display area formed on the outer frame of the panel, as shown in FIG. In this case, the channel number of the touch IC 140 connected to the display driver IC 120 is 80. That is, in the related art, the number of the touch electrode wiring 132 or the touch electrode 131 is the same as the channel number of the touch IC. However, in the present invention, The number of the electrodes 131 is reduced to 1/3 of the number of the electrodes 131.

Finally, when a touch pulse is applied to the touch electrode 131, the touch IC senses a capacitance change of the capacitance of the touch electrode and detects whether the touch electrode is touched.

The specific configuration and functions of the display driver IC 120 and the touch IC 140 as described above will be described in detail below with reference to FIGS. 4 and 5. FIG.

FIG. 4 is a view illustrating a structure of a display driver IC applied to a touch-screen-incorporated liquid crystal display device according to the present invention. FIG. Touch Pulse) is applied to the panel.

As described above, the touch screen built-in liquid crystal display device according to the present invention includes the touch panel 130 including the panel 110, the touch electrode 131 and the touch electrode wiring 132, a display driver IC (DDI) (IC) 120 and a touch IC 140. [0033]

3, the display driver IC 120 and the touch IC 140 will be described in detail below. The panel driver 110, the touch electrode 131, and the touch driver 132 are described in detail with reference to FIG.

First, the display driver IC 120 drives the data lines and gate lines formed on the panel and drives the touch electrodes 131, which are also used as common electrodes, as shown in FIG. 4. As shown in FIG. 4, And may include a common voltage generator 124, a touch synchronous signal generator 122, a channel switching signal generator 123, a switching unit 125, and a controller 121. In addition, the display driver IC 120 further includes a gate driver for applying a scan signal to a gate line, a data driver for applying a video data signal to the data line, and a timing controller for controlling the components. A detailed description of the components is omitted.

In the following description, the present invention is described as an example in which the ratio of the number of the touch electrode wirings 132 to the number of wiring between the touch IC 140 and the display driver IC 120 is 3: 1. That is, in the following description, the number of the touch electrode wiring 132 or the number of the touch electrode 131 (hereinafter simply referred to as the "total number of channels") is 240 and the wiring between the touch IC 140 and the display driver IC 120 (Hereinafter simply referred to as "number of touch IC channels") is 80, and the ratio of the total number of channels to the number of touch IC channels is 3: 1. However, the ratio of the total number of channels to the number of touch IC channels may be n: 1 (where n is a natural number of 2 or more) such as 2: 1, 4: 1, 5: In the following description, n is simply called mux channel number.

The common voltage generator 124 of the display driver IC performs a function of generating a common voltage to be applied to the touch electrode 131, which is also operated as a common electrode. That is, in the present invention, the touch electrode 131 performs a function for sensing a touch and a function for supplying a common voltage to a pixel, and the display driver IC 120 distinguishes between a video display period and a touch sensing period A common voltage generated by the common voltage generator 124 is applied to the touch electrode 131 during the video display period and a touch pulse transmitted from the touch IC 140 is applied to the touch electrode 131, .

The touch synchronous signal generating unit 122 of the display driver IC generates a touch signal for connecting the touch electrode 131 to the common voltage generator 124 or connecting the touch IC 131 to the touch IC 140 according to the video display period and the touch sensing period. And performs a function of generating a synchronization signal. That is, in the video display period, the touch synchronous signal generating unit 122 switches the switching unit 125 using the 0th touch synchronous signal ('0'), and the common electrode 131 is connected to the common voltage generating unit 124 ). In this case, the common voltage Vcom is applied to the common electrode 131. [

The touch synchronous signal generating unit 122 switches the switching unit 125 using the first touch synchronous signal '1' between the touch detectors so that the common electrode is connected to the touch IC 140. In this case, the touch electrode 131 functions as a touch sensor.

The touch synchronous signal generating unit 122 may generate and output the touch synchronous signals as described above under the control of the controller 121. [

The channel switching signal generating unit 123 of the display driver IC switches the switching unit 125 using the 0th channel switching signal '0' during the video display period so that the switching unit selects all the common electrodes 131 do. In this case, the common voltage Vcom is applied to all the common electrodes 131 since the switching unit 125 is connected to the common voltage generation unit 124 by the 0th touch synchronous signal ('0'). At this time, since the channel switching signal generator outputs only a signal corresponding to '0' or '1', it can be configured using one bit.

The channel switching signal generating unit 123 switches the switching unit 125 using the first channel switching signal '01' during 1/3 (n) of the touch sensing period, So that only the first mux channel Ch1 is selected among the mux channels.

In addition, the channel switching signal generator 123 generates a channel switching signal ('10') for another 1/3 (n) of the touch sensing period after the first channel switching signal is output, 125 so that the switching unit 125 selects only the second mux channel Ch2 among the mux channels.

In addition, the channel switching signal generator 123 generates a third channel switching signal '11' for another 1/3 (n) of the touch sensing period after the second channel switching signal is output, 125 so that the switching unit 125 selects only the second mux channel Ch3 among the mux channels.

In this case, since the switching unit 125 is connected to the touch IC 140 by the first touch synchronizing signal ('1'), a touch pulse is applied to each mux channel from the touch IC.

The control unit 121 of the display driver IC controls the functions of the touch synchronous signal generating unit 122 and the channel switching signal generating unit 123 as described above. The controller may also transmit the signals as described above to the touch IC so that the touch IC can oscillate the touch pulse on each mux channel during the touch sensing period.

The switching unit 125 of the display driver IC is directly connected to the touch electrode lines 132. In the example described above, the group touch electrode switch 126, which is connected to the three touch electrode lines, 80 < / RTI >

4, the total number of channels is 240, the number of touch IC channels is 80, and the ratio of the total number of channels to the number of touch IC channels is 3: 1. Therefore, the switching unit 125 is provided with 80 group touch electrode switching units 126 that are the same as the number of touch IC channels, and each group touch electrode switching unit 126 is connected to three touch electrode lines 132 .

Here, each of the three touch electrode wirings 132 connected to each group touch electrode switching unit 126 is referred to as a first mux channel, a second mux channel, and a third mux channel. That is, all the Mux channels of all the group touch electrode switches 126 are selected by the 0th channel switching signal ('00'), and all the group touch electrode switches 126 'are selected by the first channel switching signal' Only the first mux channels of all the group touch electrode switches 126 are selected by the second channel switching signal ('10'), and only the second mux channels of all the group touch electrode switches 126 are selected by the second channel switching signal Only the third mux channel among all the group touch electrode switchers 126 is selected by the signal '11'. Here, the first to third MUX channels are defined as touch electrode wirings, which are defined to distinguish the touch electrode wirings connected to the respective group touch electrode switches 126.

The group touch electrode switch 126 again includes a first switch 127 and a second switch 128.

The first switch 127 may be configured as a Mux. One end of the first switch is connected to the common voltage generator 124 and the touch IC 140 and the other end is connected to the second switch 128. The touch switch And connects one of the common voltage generator 124 and the touch IC 140 to the second switch 128.

The second switch 128 may also be configured as a Mux. One end of the second switch is connected to the first switch 127 and the other end of the second switch is connected to the first, second, and third MUX channels as described above. The channel switching signal generator 123 to switch any one of the common voltage generator 124 or the touch IC 140 to at least one of the first mux channel, the second mux channel, and the third mux channel .

Next, the touch IC 140 senses whether or not the touch electrode 131 is touched. Particularly, in the present invention using the self-capping method, the amount of change of the touch pulse applied to each touch electrode, It is possible to detect whether or not the touch is detected.

3, the touch IC 140 is connected to the touch electrodes 131 through the display driver IC 120, and has 80 touch IC channels in the embodiment of the present invention . Accordingly, the touch IC is connected to the display driver IC 120 through 80 wirings.

The touch IC may be connected to the display driver IC 120 through a flexible printed circuit (FPC) 150 as shown in FIG. 4, but may be formed inside the display driver IC 120 It is possible.

In any case, the touch IC 140 applied to the present invention is connected to the touch electrode 131 formed on the panel through the display driver IC 120.

A driving method of a touch-screen built-in liquid crystal display device having the above-described configuration will now be described.

In the first step, when the operation time of the touch-screen-integrated liquid crystal display device according to the present invention is an image display period, the touch sync signal generating unit 122 generates a touch sync signal ' 0 'to the first switching unit 127 of each group touch electrode switch 126 constituting the switching unit 125. The channel switching signal generating unit 123 generates the channel switching signal' 0 ' ('00') to the second switching unit 128 of each group touch electrode switch 126 constituting the switching unit 125.

In the second step, the first switches 127 are switched according to the 0th touch synchronous signal ('0') and are connected to the common voltage generator 124, and the second switches 128 are connected to the 0th channel switching It is switched according to the signal and is connected to all the MUX channels.

The common voltage Vcom generated from the common voltage generator 124 is supplied to the switch unit 125 through the switching unit 125 so that the touch screen is configured To be applied to all the touch electrodes 131. The application timing of the common voltage Vcom is shown in Fig. That is, the common voltage Vcom is applied to the touch electrode 131 during the video display period of 11 ms.

In the fourth step, when the video display period ends and the touch display period comes, the touch synchronous signal generating unit 122 generates the first touch synchronous signal ('1') under the control of the control unit 121 To the first switch 127 of each group touch electrode switch 126 constituting the switching unit 125 and the channel switching signal generating unit 123 generates the first channel switching signal '01' And transmits them to the second switch 128 of each group touch electrode switch 126 constituting the switching unit 125.

In a fifth step, the first switches 127 are switched according to the first touch synchronizing signal ('1') to be connected to the touch IC 140, and the second switches 128 are connected to the first channel switching signal And are then coupled to the first mux channels.

The first touch pulse generated from the touch IC 140 is applied to the touch screen through the switching unit 125. In this case, And is applied to the touch electrodes connected to the first mux channels among all the touch electrodes 131 constituting the touch electrode. The application timing of the first touch pulse (Touch) is shown in Fig. That is, during a period corresponding to 1/3 of the touch sensing period of 5.7 ms, the first touch pulse is applied to the touch electrodes 131 connected to the first mux channel CH1. To this end, the control unit 121 may transmit a control signal requesting the first touch pulse driving to the touch IC.

The touch IC 140 generates a first touch pulse through 80 touch IC channels. At this time, since each touch IC channel is connected to the previously set touch electrode, It is possible to determine whether or not the touch electrode connected to the corresponding IC channel is touched by using the change amount of the capacitor of the IC channel or the like.

In the seventh step, the first touch pulse is applied to the touch electrodes connected to the first mux channels during 1/3 of the entire touch sensing period, and then, according to the control of the controller 121, The signal generating unit 123 generates a second channel switching signal '10' and transmits the signal to the second switch 128 of each group touch electrode switch 126 constituting the switching unit 125. At this time, the touch synchronizing signal generating unit 122 still generates the first touch synchronizing signal '1' and outputs the first touch synchronizing signal '1' to the first switching unit 127 of each group touch electrode switching unit 126 constituting the switching unit 125 ).

In the eighth step, the first switches 127 are switched according to the first touch synchronous signal ('1') applied continuously and are connected to the touch IC 140, and the second switches 128 are connected to the second Is switched according to the channel switching signal ('10') and is connected to the second mux channels.

The second touch pulse generated from the touch IC 140 is applied to the touch screen through the switching unit 125 as a result of the connection of the respective group touch electrode switches 126 as described above. And is applied to the touch electrodes connected to the second mux channels among all the touch electrodes 131 constituting the touch electrode. The application timing of the second touch pulse Touch is shown in Fig. That is, the second touch pulse is applied to the touch electrodes 131 connected to the second mux channel CH2 during a period corresponding to the second 1/3 of the touch sensing period of 5.7 ms. To this end, the control unit 121 may transmit a control signal requesting the first touch pulse driving to the touch IC.

Since the touch IC 140 oscillates the second touch pulse with 80 touch IC channels, each touch IC channel is connected to the previously set touch electrode, It is possible to determine whether or not the touch electrode connected to the corresponding touch IC channel is touched by using the change amount of the capacitor of the channel.

In the tenth step, the second touch pulse is applied to the touch electrode connected to the second mux channels during another 1/3 of the entire touch sensing period according to the above process, and then, according to the control of the control unit 121, The channel switching signal generating unit 123 generates a third channel switching signal 11 'and transmits the third channel switching signal' 11 'to the second switch 128 of each group touch electrode switch 126 constituting the switching unit 125 do. At this time, the touch synchronizing signal generating unit 122 still generates the first touch synchronizing signal '1' and outputs the first touch synchronizing signal '1' to the first switching unit 127 of each group touch electrode switching unit 126 constituting the switching unit 125 ).

In operation 11, the first switches 127 are switched according to the first touch synchronizing signal ('1') applied continuously and are connected to the touch IC 140, and the second switches 128 are connected to the third Is switched according to the channel switching signal '11' and is connected to the third MUX channels.

The third touch pulse generated from the touch IC 140 is applied to the touch screen through the switching unit 125 as a result of connecting each of the group touch electrode switches 126 as described above to the twelfth step. And is applied to the touch electrodes connected to the third mux channels among all the touch electrodes 131 constituting the touch electrode. The application timing of the third touch pulse (Touch) is shown in Fig. That is, the third touch pulse is applied to the touch electrodes 131 connected to the third mux channel CH3 during a period corresponding to the third third of the touch sensing period of 5.7 ms. To this end, the control unit 121 may transmit a control signal requesting the first touch pulse driving to the touch IC.

Since the touch IC 140 oscillates the third touch pulse with 80 touch IC channels, each touch IC channel is connected to the previously set touch electrode, It is possible to determine whether or not the touch electrode connected to the corresponding touch IC channel is touched by using the change amount of the capacitor of the channel.

Thereafter, the present invention repeatedly performs the first to twelfth steps as described above.

The liquid crystal display with built-in touch screen according to the present invention as described above will be summarized as follows.

That is, according to the present invention, a conventional all-channel simultaneous sensing method is converted into a selective sensing method through a mux, and the number of touch IC channels (n) Can be reduced. For example, in the above description, since the number of mux channels is 3, the number of touch IC channels can be reduced to 80, which is 1/3 (n) of the total number of channels 240.

In addition, the present invention is characterized in that a display driver IC (DDI) has a built-in Mux, which makes it easy to apply a product to a product without depending on reliability and implementation plan.

The present invention is also applicable to a display device in which a common voltage generator is serially connected to muxes (first and second switching devices) 127 and 128 so that a mux All of the MUX channels of the first and second switching units 127 and 128 can output the common voltage Vcom to the panel.

Since the common voltage Vcom is conventionally output from the display driver IC DDI to the panel via the touch IC, it is determined whether or not the touch IC is driven according to the output voltage of the common voltage Vcom. . However, the present invention enables the independent touch IC (IC) and the common voltage (Vcom) drive by incorporating the common voltage switches 127 and 128 in the display driver IC (DDI). Particularly, in the video display period of the present invention, the common voltage Vcom is outputted through the common voltage switch Vcom switch (first switch) 127, and the n: 1 muxes 127, 128 to output common voltages to all the channels of the muxes 127, 128.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

110: Panel 120: Display Driver IC
130: touch electrode 140: touch IC
150: FPC for touch IC 121:
122: Touch synchronous signal generating unit 123: Channel switching signal generating unit
124: common voltage generator 125:
126: Group touch electrode switching device 127: First switching device
128: second switching device

Claims (18)

A panel having a data line and a gate line;
A touch screen including a plurality of touch electrodes built in the panel and touch electrode wires connected to the plurality of touch electrodes;
A display driver IC for applying a common voltage or a touch pulse to the touch electrodes; And
And a touch IC for sensing whether the touch electrodes are touched by applying the touch pulse to the touch electrodes through the display driver IC,
Wherein the touch IC senses whether a touch is generated by using a change amount of a capacitance according to a touch pulse applied to each touch electrode. The method according to claim 1,
Wherein the touch IC is embedded in the display driver IC or connected to the display driver IC by an FPC for a touch IC. The method according to claim 1,
Wherein the number of the touch electrode lines is a multiple of the number of the touch IC channels connecting the display driver IC and the touch IC. The method of claim 3, wherein
Wherein the display driver IC and the touch IC are electrically connected through a flexible printed circuit board. The method of claim 3,
The display driver IC includes:
A common voltage generator for generating a common voltage to be supplied to the touch electrode;
And a plurality of group touch electrode switching units connected to at least two of the touch electrode lines, wherein the common voltage generating unit or the touch IC is connected to the touch electrode lines via the group touch electrode switches ;
A touch synchronizing signal generator for generating a touch synchronizing signal for connecting the touch electrode wires to the common voltage generator or connecting the touch electrode wires to the touch IC; And
The touch electrode lines of the group touch electrode switches are connected to all the touch electrode lines during the video display period and the touch electrode lines connected to the group touch electrode switches are sequentially connected to the touch IC during the touch sensing period And a channel switching signal generating unit for generating a channel switching signal for causing the liquid crystal display unit to display the liquid crystal display panel. 6. The method of claim 5,
Wherein each of the group touch electrode switchers of the switching unit comprises:
Wherein the common voltage generator and the touch IC are connected to one end of the common voltage generator and the touch IC and the other end of the touch voltage is switched by the touch synchronous signal generator, A first switch for connecting to the other end; And
And the other end of the touch switch is connected to at least two of the touch electrode lines and is switched by the channel switching signal so that the common voltage generating unit or the touch IC And a second switching unit for connecting one of the plurality of touch electrodes to at least one of the touch electrode lines connected to the other end. When the video display period comes, each of the group-touch-electrode switching units connected to at least two of the plurality of touch electrodes applies a common voltage to the at least two touch- Lt; / RTI > And
When the touch sensing time comes, each of the group touch electrode switchers sequentially connects the touch IC to the touch electrodes in groups, and the touch IC uses the change amount of the capacitance according to the touch pulse applied to each touch electrode And detecting whether the touch panel is touching the touch panel. 8. The method of claim 7,
Wherein the number of the touch electrodes connected to the group touch electrode switching units is a multiple of the number of touch IC channels connecting the group touch electrode switches and the touch IC. 8. The method of claim 7,
Wherein the step of connecting the common voltage generator to all of the touch electrode lines comprises:
When the video display period arrives, a 0 th touch synchronous signal is generated and transmitted to the first switch of each of the group touch electrode switches, and a 0 th channel switch signal is generated, Transmitting to a second switch;
The first switch is switched according to the 0th touch synchronous signal and is connected to the common voltage generator, and the second switch is switched according to the 0th channel switching signal, so that all the touch electrode wirings ; And
Wherein the common voltage generating unit is connected to the touch electrode lines through the first switcher of the group touch electrode switcher, the second switcher, and the touch electrode lines connected to the second switcher And supplying a common voltage to the touch electrodes. 10. The method of claim 9,
And sequentially connecting the touch IC to the touch electrode lines connected to the group touch electrode switch,
Generating a first touch synchronizing signal and transmitting the first touch synchronizing signal to the first switch, generating a first channel switching signal, and transmitting the first touch switching signal to the second switch, when the image display period ends and the touch sensing period arrives ;
The first switch is switched according to the first touch synchronizing signal and is connected to the touch IC, and the second switch is switched according to the first channel switching signal to switch all the touch electrode wirings Sequentially connecting the plurality of optical fibers to each other;
Sequentially supplying a touch pulse applied from the touch IC to all the touch electrode wirings while the second switching unit is sequentially connected to all the touch electrode wirings; And
And sensing whether the touch IC is touching the touch electrode connected to the touch electrode lines using the touch pulse. 11. The method of claim 10,
Wherein the second switching unit is sequentially connected to all the touch electrode lines connected to the group touch electrode switch,
The first switch being switched according to the first touch synchronizing signal and being connected to the touch IC;
During the first period divided by the number (n) of the touch electrode lines connected to the group touch electrode switch during the touch sensing period, the second switch is switched according to the first channel switching signal, To the first touch electrode wiring among the first touch electrode wiring;
The second switching unit is switched according to a second channel switching signal to be connected to a second one of the plurality of touch electrode lines during a second period subsequent to the first period; And
And the second switching unit is switched according to an n-th channel switching signal to be connected to the nth touch electrode wiring among the touch electrode wirings during an n-th period following the second period, Way. And a switching unit for transmitting a common voltage to the touch electrodes during the video display period and for transmitting the touch pulses to the touch electrodes by groups of touch electrodes,
Wherein the switching unit sequentially transmits the touch pulse to the groups,
Wherein the touch driver detects the touch by using a change amount of a capacitance according to the touch pulse applied to each touch electrode. 13. The method of claim 12,
And a touch IC for supplying the touch pulse. 13. The method of claim 12,
Wherein the switching unit is connected to a touch IC that supplies the touch pulse through a flexible printed circuit board. 13. The method of claim 12,
And a data driver for applying image data signals to the data lines provided on the panel on which the touch electrodes are arranged. 14. The method of claim 13,
Wherein the switching unit includes a plurality of group touch electrode switching units connected to at least two of the touch electrode lines connected to the respective touch electrodes,
Wherein each of the group touch electrode switchers connects all the touch electrode lines to a common voltage generator for generating the common voltage during an image display period,
Wherein each of the group touch electrode switching devices connects the touch electrode lines sequentially to the touch IC during a touch sensing period. The method according to claim 1,
The touch IC supplies the touch pulse to the display driver IC,
And the display driver IC supplies the touch pulse to the touch electrodes. 8. The method of claim 7,
Wherein the touch IC supplies the touch pulse to the display driver IC, and the display driver IC supplies the touch pulse to the touch electrodes.

Images