KR20150049038A - Display Device With Integrated Touch Panel And Method For Driving The Same - Google Patents

Abstract

The present invention relates to a display device. In particular, provided are a touch panel-integrated display device and a method for driving the same. An analog unit for receiving an analog sensing signal from a touch panel integrally formed with a panel and converting the analog sensing signal into a digital sensing signal is formed on a display driver IC mounted on the panel. During a touch sensing period, time is divided, and analog sensing signals are received from touch electrodes in group units. Then, the digital sensing signals are analyzed in the group units, thereby sensing a touch of the touch panel. To this end, the touch panel-integrated display device according to the present invention comprises: a panel having a pixel defined by a data line and a gate line crossing each other; a touch panel integrally formed with the panel and having g number of groups made of two or more touch electrodes; a display driver IC for dividing time during a touch sensing period, supplying a touch pulse in the group units, receiving analog sensing signals in the group units from the touch panel, and converting the analog sensing signals into digital sensing signals; and a touch IC for receiving the digital sensing signals in the group units, analyzing the digital sensing signals by using an analysis program using a self-cap technique, and sensing a touch of the touch panel.

Description

[0001] The present invention relates to a touch panel integrated type display device and a driving method thereof,

The present invention relates to a display device, and more particularly to a display device in which a capacitive touch panel is integrally formed.

Flat panel displays (FPDs) are used in various types of electronic products including mobile phones, tablet PCs, notebooks, and monitors. Examples of flat panel display devices include a liquid crystal display (LCD), a plasma display panel (PDP), and an organic light emitting display (OLED) (EPD: ELECTROPHORETIC DISPLAY) are also widely used.

Of the flat panel display devices (hereinafter, simply referred to as 'display devices'), liquid crystal displays are most widely commercialized at present because of their advantages of mass production technology, ease of driving means, and high image quality.

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

As a method for constructing the touch panel on a panel for displaying an image on a liquid crystal display device, there is an add-on type and an in-cell type.

Of these, the add-on type touch panel is manufactured independently of the panel, and then attached to the plane of the panel. Further, the in-cell type touch panel is formed integrally with the panel.

Particularly, in a liquid crystal display device applied to a portable terminal such as a smart phone, a touch panel is integrally formed inside the panel to make the portable terminal slim. This type of liquid crystal display device is referred to as a touch panel integrated display device.

FIG. 1 is an exemplary view showing a configuration of a conventional touch panel integrated type display device, and is an example of a configuration of a liquid crystal display device applied to a portable terminal such as a smart phone. FIG. 2 is an exemplary view showing a video display period and a touch sensing period in a conventional touch panel integrated display device.

1, a touch panel 31 including a plurality of touch electrodes 30 is embedded in a conventional touch panel integrated display device, particularly, a touch panel integrated display device applied to a portable terminal A display driver IC (DDI) 12 for controlling gate lines and data lines in the panel 11, a touch panel 31 formed inside the panel 11, A touch IC 14 and a touch IC 14 for driving the display IC 12 and the touch IC 14 are electrically connected to each other And a flexible printed circuit board (FPCB) 15 for connection.

In general, the touch panel integrated type display device uses a time division driving method using the touch electrode 30 as a common electrode during a display time period and using the touch electrode 30 as a touch electrode during a touch time period .

The method of constructing the touch panel may be classified into a self cap method and a mutual method.

In the conventional touch panel integrated type display device incorporating the touch panel 31 using the self cap method, as shown in FIG. 1, the number of the horizontal direction touch electrodes 30 n and the number m of the longitudinal direction touch electrodes 30 are taken into consideration, nxm number of touch electrode lines 32 are required.

In this case, the touch electrode lines 32 are independently drawn from the respective touch electrodes 30.

For example, in the case of the touch panel 31 in which the number of the horizontal direction touch electrodes n is 12 and the number of the vertical direction touch electrodes m is 20, a total of 240 (= 12) x 20 of touch electrode lines 32 may be formed on the touch panel 31 and 240 of the touch electrode lines 32 are connected to the display driver IC 12.

The display driver IC 12 is connected to the touch IC 14 through the 80 touch channel lines 16 formed on the flexible printed circuit board 15. In this case, the display driver IC 12 connects the 240 touch electrode lines 32 to the 80 touch channel lines 16 using three-to-one muxes.

For example, the display driver IC 12 divides the touch sensing period into three parts, then divides 80 touch electrode lines of 240 touch electrode lines into 80 pieces of touch electrode lines every 1/3 touch sensing period And is connected to the touch channel lines 16.

The above-described conventional touch panel integrated display device has the following problems.

First, the conventional touch panel integrated type display device has a structure in which the display driver IC 12 mounted on the panel 11 and the touch IC 14 mounted on the flexible printed circuit board 15 ).

In this case, the conventional touch panel integrated display device includes, for example, as many as 240 touch electrode lines 32, as shown in FIG. 1, and the display driver IC 12 and the In order to electrically connect the flexible printed circuit board 15, 80 touch channel lines 16 and the touch IC 14 of a large size (6 x 6 mm ² ) are required.

Therefore, the flexible printed circuit board 15 applied to the conventional touch panel integrated display device has a bulky shape. Thus, the process of mounting the touch IC 14 on the flexible printed circuit board 15 or forming the touch channel lines 16 is complicated, and manufacturing cost is increased.

Second, as described above, an excessive number of the touch channel lines 16 and the touch IC 14 having a relatively large size are susceptible to an external physical shock. As a result, touch ghost noise (touch ghost noise) noise is likely to be induced.

Third, the touch IC 14 includes 80 pins in the above example. Therefore, there is a high possibility that defects are generated during the step of mounting the touch IC 14 on the flexible printed circuit board 15, and thus the defective rate of the touch panel integrated display device is also likely to increase.

Fourth, as shown in FIGS. 3A and 3B, the display driver IC 12 outputs the analog sense signals Data received during the touch sensing period, And then transmitted to the touch IC. 3 (a), MUX1 Sensing means receiving an analog sense signal from 80 touch electrodes 13 during the 1/3 touch sensing period, and MUX2 Sensing means receiving an analog sense signal during another 1/3 touch sensing period The MUX3 sensing means receiving an analog sense signal from the remaining 80 touch electrodes 13 during the remaining 1/3 touch sensing period, .

That is, in the conventional touch panel integrated type display device, the analog sense signals sensed during the touch sensing period are displayed during a new video display period (indicated as Display in FIG. 3 (a)) after the touch sensing period And transmits them collectively. Therefore, until the touch IC 14 receives all of the analog sense signals, the algorithm processing time, which is a period for determining whether or not the touch is detected, is delayed.

The latency of the algorithm processing time is lengthened, which slows down the touch response rate. In this case, implementation of a high report rate of 120 Hz may also be adversely affected.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a data transmission method and a data transmission method in which a conventional data transmission method generates a loss in time and deteriorates a touch characteristic such as a report rate and a latency, An object of the present invention is to provide a touch panel integrated display device and a method of driving the same that can minimize time loss and improve touch characteristics by adopting a driving method of transmitting data in parallel with touch sensing.

According to an aspect of the present invention, there is provided a touch panel integrated type display device including: a panel having pixels defined by intersections of a data line and a gate line; A touch panel having g groups formed by at least two or more touch electrodes formed integrally with the panel; A display driver for supplying touch pulses in units of groups and dividing time during a touch sensing period to receive analog sensing signals from the touch panel in units of groups and converting the analog sensing signals into digital sensing signals; IC; And a touch IC for receiving the digital sensing signals and analyzing the digital sensing signals using an analysis program using a self-capping method to detect whether or not the touch panel is touched.

According to an aspect of the present invention, there is provided a method of driving a touch panel integrated type display device including a display panel mounted on a panel having g groups formed by at least two or more touch electrodes, The driver IC supplying a common voltage to the touch electrodes formed on the panel; When the touch sensing period arrives, the display driver IC supplies a touch pulse in units of the group; Converting the analog sense signal into a digital sense signal by the display driver IC when the analog sense signal is received in the group unit; Transmitting the digital sensed signal to the touch IC by the display driver IC in units of the group; And analyzing the digital sensed signal by the touch IC in an analysis program using a self-cap method in units of the group to detect whether the touch panel is touched.

According to the present invention, the flexible printed circuit board can be simplified, and the design of the touch panel integrated display device can be changed into various forms.

According to the present invention, since the number of touch channel lines and the size of the touch IC can be reduced, a touch panel integrated type display device resistant to external physical shocks can be manufactured. Thus, the touch ghost noise can be removed, and the touch quality can be improved.

According to the present invention, the area of the flexible printed circuit board can be reduced, and the defect rate in the process of mounting the touch IC on the flexible printed circuit board can be reduced. Therefore, the manufacturing cost of the touch panel integrated type display device can be reduced.

In addition, according to the present invention, it is possible to quickly determine whether or not a touch is made, and the latency can be shortened, thereby improving the touch response speed. Further, according to the present invention, it is possible to realize a high report rate of 120 Hz.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an exemplary view showing a configuration of a conventional touch panel integrated display device. Fig.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a touch-
3 is an exemplary view showing a panel configuration of a touch panel integrated display device according to the present invention.
4 is a view illustrating an internal configuration of a display driver IC and a touch IC applied to a touch panel integrated display device according to the present invention.
FIG. 5 is an exemplary view illustrating a video display period and a touch sensing period in the touch panel integrated display device according to the first exemplary embodiment of the present invention; FIG.
6 is an exemplary view illustrating a video display period and a touch sensing period in the touch panel integrated display device according to the second embodiment of the present invention;

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

Hereinafter, for convenience of explanation, the liquid crystal display device will be described as an example of the touch panel integrated display device according to the present invention, but the present invention is not limited thereto. That is, the present invention can be applied to various display devices capable of displaying an image using a common electrode and a common voltage.

3 is an exemplary view showing a panel configuration of a touch panel integrated display device according to the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a capacitive touch panel integrated type display device to which a self cap method is applied. 3, the touch panel integrated display device according to the present invention includes a touch panel 130 having a large number of touch electrodes 131, And one-to-one with the display driver IC 120 through the touch electrode lines 132. In the touch panel integrated display device according to the present invention, the display driver IC 120 is mounted on the flexible printed circuit board 150 through the touch channel lines 141 formed on the flexible printed circuit board 150 And is electrically connected to the touch IC 140.

The touch panel integrated display device according to the present invention is for reducing the number of the touch channel lines 141. In the display driver IC 120, an analog touch sensing unit for receiving the analog sense signal from the touch panel 130 and converting the analog sense signal into a digital sense signal is formed. During the touch sensing period, the display driver IC 120 selectively divides and sequentially drives the touch electrodes 131 connected to the group touch electrode switchers composed of MUXs, and during the display period, And the common voltage Vcom is simultaneously supplied to all the touch electrodes connected to the touch electrode switching units.

To this end, the touch panel integrated display device according to the present invention includes a panel 110 having pixels defined by the intersection of a data line (not shown) and a gate line (not shown) A touch panel 130 formed with n groups formed of at least two or more touch electrodes 131 and formed integrally with the panel 110 divides the time during the touch sensing period, A display driver IC 120 for supplying touch pulses and receiving analog sense signals in units of groups from the touch panel 130 and converting the analog sense signals into digital sense signals, A touch IC 130 for receiving digital sensing signals and analyzing the digital sensing signals using an analysis program using a self-capping method to detect whether the touch panel 130 is touched (140).

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 is provided with a plurality of data lines, a plurality of gate lines crossing the data lines, a plurality of thin films formed at the intersections of the data lines and the gate lines (TFT) (Thin Film Transistor), a plurality of pixel electrodes for charging a data voltage to the pixel, and a common electrode (touch electrode) 131 for driving the liquid crystal filled in the liquid crystal layer together with the pixel electrode are formed , The pixels are arranged in a matrix form by an intersection structure of the data lines and the gate lines.

In addition, a black matrix BM and a color filter are formed on the upper glass substrate of the panel 110.

A polarizing plate is attached to each of the upper glass substrate and the lower glass substrate and an alignment layer for setting a pretilt angle of the liquid crystal is formed on the inner surface of the upper glass substrate and the lower glass substrates in contact with the liquid crystal. A column spacer CS for maintaining a cell gap of the liquid crystal layer may be formed between the upper glass substrate and the lower glass substrate of the panel 110.

The present invention relates to a touch panel integrated display device in which touch electrodes 131 constituting the touch panel 130 are included in the panel 110 as described above.

Next, the touch panel 130 performs a function of detecting whether or not the user touches the touch panel 130. Particularly, the touch panel 130 applied to the present invention may be a capacitive touch panel using a Self Cap . The touch panel 130 includes a plurality of touch electrodes 131 and a plurality of touch electrode lines 132.

Each of the plurality of touch electrodes 131 may be formed over a plurality of pixels formed on the panel 110. During the touch sensing period, the touch electrodes 131 sense the presence or absence of a touch by a touch pulse supplied from the touch IC 140. During the image display period, And performs the function of driving the liquid crystal together with the electrodes.

One end of each of the plurality of touch electrode lines 132 is connected to the touch electrode 131 and the other end is connected to the display driver IC 120 through a non-display region of the panel 110 have.

3, the display driver IC 120 controls the data line and the gate line and supplies a common voltage or a touch pulse to the touch electrode 131. As shown in FIG. 3, (130) and the touch IC (140).

The display driver IC 120 outputs a gate control signal GCS and a data control signal DCS using a timing signal transmitted from an external system (not shown) to output an image to the panel 110 And performs a function of rearranging the input image data signals according to the structure of the panel 110.

In addition, the display driver IC 120 supplies a common voltage to the touch electrodes 131 during a video output time for outputting an image. During the touch sensing period for sensing a touch, To the touch electrodes (131).

Also, the display driver IC 120 connects the touch electrodes 131 and the touch IC 140 to each other. That is, the analog sense signal sensed through the touch electrodes 131 is converted into a digital sense signal by the display driver IC 120 and then transmitted to the touch IC 140 through the display driver IC 120 Respectively.

For example, as shown in FIG. 3, when the number of the touch electrodes 131 constituting the touch panel 130 is 240, the number of the touch electrode lines 132 is also 240. As shown in FIG. 3, the 240 touch electrode lines 132 are connected to the display driver IC 120 in a non-display area formed on an outer frame of the panel 110. In this case, the number of touch channel lines 141 formed on the flexible printed circuit board 150 and electrically connecting the display driver IC 120 to the touch IC 140 is about 2 to 7 .

For example, in a conventional touch panel integrated type display device, when the number of touch electrode lines or the number of touch electrodes is 240, the number of touch channel lines connecting the display driver IC and the touch IC is 240 Or about 240 / n 10. Here, n is the number of MUXs formed in the display driver IC, that is, the number of touch electrodes connected to the switcher, which is only about two to five. Also, the number of 10 is the number of communication lines required for communication between the display driver IC and the touch IC. Therefore, in the conventional touch panel integrated type display device, when n is 3, about 90 touch channel lines are formed on a flexible printed circuit board that electrically connects the display driver IC and the touch IC .

However, in the touch panel integrated type display device according to the present invention, the touch channel lines 141 for transmitting the digital sense signal and about one to four touch channel lines 141 for connecting the display driver IC 120 and the touch IC 140, Approximately two to seven touch channel lines 141 including touch channel lines 141 required for communication between the display driver IC 120 and the touch IC 140 are electrically connected to each other Is formed on the flexible printed circuit board 150.

As described above, the specific reason why the number of the touch channel lines 141 formed on the flexible printed circuit board 150 can be reduced will be described in detail with reference to FIG.

Particularly, the display driver IC 120 supplies touch pulses in units of groups by dividing time during the touch sensing period, receives analog sensing signals from the touch panel 110 in groups, Converts the analog sense signals into digital sense signals, and transmits the digital sense signals to the touch IC 140 in groups.

Finally, the touch IC 140 receives the digital sensing signal transmitted from the display driver IC 120, analyzes the digital sensing signal using an analysis program using a self-capping scheme, 130 of the touch panel.

In particular, the touch IC 140 receives the digital sensing signals in units of the groups, analyzes the digital sensing signals using an analysis program using a self-capping method, and detects whether the touch panel is touched.

In this case, the digital sensing signals of the group unit may be transmitted to the touch IC 140 during the touch sensing period.

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

FIG. 4 is a diagram illustrating an internal configuration of a display driver IC and a touch IC applied to the touch panel integrated type display device according to the present invention. FIG. 5 is a diagram illustrating an internal structure of a touch panel integrated type display device according to the first embodiment of the present invention. FIG. 6 is an exemplary view illustrating a video display period and a touch sensing period in the touch panel integrated display device according to the second exemplary embodiment of the present invention. Referring to FIG. 5A and 6A, MUX1 Sensing refers to receiving analog sense signals from the first group described above during a 1/3 touch sensing period, MUX2 Sensing refers to another Means receiving the analog sense signal from the second group during the 1/3 touch sensing period and MUX3 Sensing means receiving the analog sense signal from the third group during the remaining one third touch sensing period. The touch pulse is simultaneously supplied to the group. The group is composed of two or more touch electrodes and can be variously defined.

The touch panel integrated display device according to the present invention includes the touch panel 130 composed of the panel 110, the touch electrodes 131 and the touch electrode lines 132, An IC (DDI: Display Driver IC) 120, and the touch IC 140. The display driver IC 120 and the touch IC 140 are electrically connected through the touch channel lines 141 formed on the flexible printed circuit board 150. 3, the panel driver 110, the touch electrode 131, and the touch electrode lines 132 are described in detail below. Hereinafter, the display driver IC 120 and the touch IC (140) will be described in detail.

The display driver IC 120 will now be described.

As described above, the display driver IC 120 drives the data lines and the gate lines formed on the panel 110, and the common voltage or the common voltage is applied to the touch electrodes 131 used as a common electrode 4, the common voltage generating unit 124, the touch synchronizing signal generating unit 122, the channel switching signal generating unit 123, the switching unit 125, and the controller (not shown) 121, and an analog unit 129. [ In addition, the display driver IC 120 further includes a gate driver for supplying a scan signal to the gate line, a data driver for supplying a video data signal to the data line, and a timing controller for controlling the components can do. However, the configurations and functions of the gate driver, the data driver, and the timing controller are the same as or similar to those of the gate driver, the data driver, and the timing controller, which are provided in a general display device and a general touch panel integrated display device A detailed description thereof will be omitted.

In the following description, the number of the touch electrode lines 132 or the number of the touch electrodes 131 (hereinafter simply referred to as 'the total number of touch electrodes') is 240, 240 touch electrode lines 132 are connected to the switching unit 125 and 80 analog channel lines 129a are formed between the switching unit 125 and the analog unit 129 The display driver IC 120 and the touch IC are described as an example in which five touch channel lines 141 are formed between the analog unit 129 and the touch IC 140. [ That is, the total number of touch electrodes is 240, the number of the analog channel lines 129a between the switching unit 125 and the analogue unit 129 is 80 (hereinafter, simply referred to as the number of analog channel lines) , And the ratio of the total number of touch electrodes to the number of analog channel lines is 3: 1. However, the ratio of the total number of touch electrodes to the number of analog channel lines may be n: 1 (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 n is the number of the touch electrode lines 132 connected to each of the group touch electrode switches 126 formed in the switching unit 125. The touch electrode lines 132 connected to the group touch electrode switch 126 are hereinafter simply referred to as mux channels. Accordingly, in the display driver IC 120 shown in FIG. 4, each of the group touch electrode switches 126 is connected to three mux channels.

4, the display driver IC 120 includes a common voltage generating unit 124 for generating a common voltage to be supplied to the touch electrode 131, at least two of the touch electrode lines 132, A plurality of group touch electrode switching units 126 connected to the plurality of touch electrode lines, a switching unit 125 for dividing a time during the touch sensing period, An analog unit 129 for converting the analog sense signals transmitted in the group unit from the touch panel 130 through the switching unit 125 into the digital sense signals, For generating a touch synchronizing signal for connecting the touch electrode lines 132 to the common voltage generator 124 or for connecting the touch electrode lines 132 to the analog voltage generator 124, The group touch electrode switch 126 may be connected to all the touch electrode lines 132 during the video output time of the call generator 122 and the group touch electrode switch 126 may be turned on during the touch sensing period, And a channel switching signal generator 128 for generating a channel switching signal for connecting the touch electrode lines 132 connected to each of the plurality of touch electrode lines 132 to the analog unit 129 on a group basis.

Here, the group includes at least two or more touch electrodes 131. In the following description, the first group to the g-th group are formed on the touch panel 130 or the panel 110, and the present invention will be described as an example. Touch pulses are supplied to the touch electrodes 131 belonging to each of the groups at the same time. The groups may be the touch electrode subgroups MUX1, MUX2, MUX3 shown in FIG. In addition, the groups may be formed in the touch electrode subgroups MUX1, MUX2, and MUX3. For example, the first to the g-th groups may be formed in the first touch electrode sub-group MUX1, the first to the g-th groups may be formed in the second touch electrode sub-group MUX2, The first to the g-th groups may also be formed in the touch electrode sub-group MUX3. As described above, the touch pulses are simultaneously supplied to the same groups.

First, the common voltage generator 124 generates a common voltage to be supplied to the touch electrodes 131, which is also operated as a common electrode. That is, in the present invention, the touch electrodes 131 perform a function of sensing touch and a function of supplying a common voltage to the pixels. The display driver IC 120 divides the video output time and the touch sensing time and supplies the common voltage generated in the common voltage generator 124 to the touch electrodes 131 during the video output time, During the touch sensing time, the touch pulse generated by the analog unit 129 is supplied to the touch electrodes 131.

Secondly, the touch synchronizing signal generator 122 connects the touch electrode 131 to the common voltage generator 124 or connects the touch electrode 131 to the analog controller 129 according to the video output period and the touch sensing period. And generates a touch synchronizing signal for connecting the touch screen to the touch screen.

For example, the touch synchronous signal generating unit 122 switches the switching unit 125 using the 0th touch synchronous signal ('0') at the video output time so that the common electrodes 131 And is connected to the common voltage generator 124. In this case, the common voltage Vcom is supplied to the common electrodes 131.

The touch synchronizing signal generating unit 122 may switch the switching unit 125 using the first touch synchronizing signal '1' during the touch sensing time so that the touch electrodes 131 are turned on / 129). In this case, the touch electrodes 131 function 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. [

Third, the channel switching signal generator 123 switches the switching unit 125 using the 0th channel switching signal '00' during the video output time, and the switching unit 125 switches all the common electrodes (131). In this case, since the switching unit 125 is connected to the common voltage generator 124 by the 0th touch synchronous signal '00', the common voltage Vcom is applied to all the common electrodes 131, Respectively.

The channel switching signal generating unit 123 may switch the switching unit 125 using the first channel switching signal '01' for one third (n = 3) of the touch sensing times, Unit 125 to select only the first mux channel among the mux channels.

After the first channel switching signal is output, the channel switching signal generator 123 generates the channel switching signal 125 'using the second channel switching signal' 10 'during another 1/3 period of the touch sensing time, ) So that the switching unit 125 selects only the second mux channel among the mux channels.

The channel switching signal generating unit 123 generates the switching signal by using the third channel switching signal '11' during the third 1/3 period of the touch sensing time after the second channel switching signal is output, And allows the spoofing unit 125 to select only the third mux channel among the mux channels.

In this case, since the switching unit 125 is connected to the analog unit 129 by the first touch synchronous signal ('1'), A pulse is supplied.

3, the touch electrodes 131 connected to the first mux channels selected by the switching unit 125 by the first channel switching signal are connected to one side of the panel 110 The first touch electrode sub-group MUX1 may be formed.

As shown in FIG. 3, the touch electrodes 131 connected to the second mux channels selected by the switching unit 125 by the second channel switching signal are divided into a plurality of 2 touch electrode sub-group MUX2. In particular, the second touch electrode sub-group MUX2 may be formed adjacent to the first touch electrode sub-group MUX1.

As shown in FIG. 3, the touch electrodes 131 connected to the third MUX channels selected by the switching unit 125 by the third channel switching signal are divided into a plurality of 3 touch electrode sub-group MUX3. In particular, the third touch electrode sub-group MUX3 may be formed adjacent to the second touch electrode sub-group MUX3.

In addition, the touch electrode subgroups MUX1, MUX2, and MUX3 may form a touch electrode group. FIG. 3 shows two touch electrode large groups GA and GB. In this case, the first touch electrode subgroup GA includes the first touch electrode subgroup MUX1, the second touch electrode subgroup MUX2, and the third touch electrode subgroup MUX3. The second touch electrode subgroup GB also includes another first touch electrode subgroup MUX1, another second touch electrode subgroup MUX2, and another third touch electrode subgroup MUX3 . In FIG. 3, two touch electrode groups GA and GB are shown, but three or more touch electrode groups may be formed on the touch panel 130. FIG.

The touch electrode 131 is divided into at least two touch electrode large groups GA and GB and the touch electrode large groups GA and GB are divided from one side of the touch panel 130 to the other side Direction. For example, in FIG. 3, the first touch electrode group GA is formed on the left side of the touch panel 130, and the second touch electrode group GB is formed on the right side of the touch panel 130 Respectively.

The touch electrodes 131 included in the touch electrode group GA or GB may correspond to the number n of touch electrode lines connected to the group touch electrode switch 126, And the touch electrode subgroups MUX1, MUX2, and MUX3. The touch electrode subgroups MUX1, MUX2, and MUX3 may be sequentially disposed from one side of the touch electrode group GA or GB to the other side.

Fourth, the controller 121 controls the functions of the touch synchronous signal generator 122 and the channel switching signal generator 123. Also, the controller 121 may transmit the touch synchronizing signal indicating the touch sensing period to the analog unit 129 and the touch IC 140. In this case, a touch channel line 141 for transmitting the touch synchronous signal to the touch IC 140 may be formed on the flexible printed circuit board 141.

Fifth, the switching unit 125 is directly connected to the touch electrode lines 132. In particular, in the above-described example, the switching unit 125 is connected to three touch electrode lines (mux channels) Group touch electrode switchers 126. [0033]

4, the number of the touch electrode lines 132 is 240, and the number of the analog channel lines 129a connecting the switching unit 125 and the analog unit 129 Is 80, and the ratio of the total number of touch electrodes to the number of analog channel lines is 3: 1.

Accordingly, the switching unit 125 is provided with 80 group touch electrode switching units 126, which are the same as the number of analog channel lines, and each of the group touch electrode switching units 126 includes three touch electrode lines (Not shown).

Here, each of the three touch electrode lines 132 connected to the group touch electrode switch 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 switching Only the first mux channels among the group tap electrode switches 126 are selected and only the second mux channels among all the group touch electrode switches 126 are selected by the second channel switching signal ' Only the third mux channels among all the group touch electrode switches 126 are selected by the third channel switching signal '11'.

Here, the first to third MUX channels are defined as the touch electrode lines 132 and are used to distinguish the touch electrode lines connected to the respective group touch electrode switches 126.

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

The first switch 127 may be a mux. One end of the first switch 127 is connected to the common voltage generating unit 124 and the analog unit 129 and the other end is connected to the second switch 128. The first switch may be switched by the touch synchronous signal generator 122 to connect any one of the common voltage generator 124 or the analog switch 129 to the second switch 128 .

The second switch 128 may also be a mux. One end of the second switch is connected to the first switch 127 and the other end is connected to the first, second and third mux channels. The second switching unit 128 is switched by the channel switching signal generating unit 123 so that any one of the common voltage generating unit 124 or the analogue unit 129 is switched to the first mux channel , The second mux channel, and the third mux channel.

During the touch sensing period, the group touch electrode switch 126 switches the touch pulse 131 to the touch electrodes 131 included in one of the touch electrode subgroups MUX1, MUX2, and MUX3, And then supplies the touch pulse to the touch electrodes included in another touch electrode subgroup.

For example, in the touch panel built-in type display device shown in FIGS. 3 and 4, the group touch electrode switch 126 switches the first touch electrode group GA, And the first touch electrode subgroup (MXU1) formed in the second touch electrode subgroup (GB), after the touch pulse is supplied to the first touch electrode subgroup (MXU1) And the second touch electrode sub-group (MUX2) formed in the second touch electrode sub-groups (GB), and during the remaining 1/3 period, the first touch electrode sub-group (GA) The touch pulse can be supplied to the third touch electrode sub-group MUX3 formed in the second touch electrode sub-groups GB.

In this case, the group touch electrode switches connected to the touch electrode large group GA or GB form a switch group A or B, and the switch groups corresponding to the touch electrode large groups GA and GB (A, B) may be formed separately from each other in the display driver IC (120).

For example, in the touch panel built-in display device shown in FIGS. 3 and 4, since there are two touch electrode large groups GA and GB, the number of the switch groups A and B is also two.

When the first touch electrode large group GA is formed on the left side of the touch panel 130 as shown in FIG. 3, the first switch group GA corresponding to the first touch electrode large group (GA) A may be formed on the left side inside the display driver IC 120 as shown in FIG.

When the second touch electrode group GB is formed on the right side of the touch panel 130 as shown in FIG. 3, the second switch unit GB corresponding to the second touch electrode large group GA, The group B may be formed on the right side of the display driver IC 120, as shown in FIG.

Sixth, the analog unit 129 converts the analog sense signal transmitted from the touch panel 130 through the switching unit 125 into the digital sense signal during the touch sensing period, 150).

In addition, the analog unit 129 generates the touch pulse during the touch sensing period and transmits the generated touch pulse to the touch electrodes 131 through the switching unit 125.

That is, the analog unit 129 transmits the touch pulse to the touch electrodes 131 during the touch sensing period, and receives the analog sensing signal corresponding to the touch pulse. The analog unit 129 converts the analog sense signal into the digital sense signal and then outputs the converted digital sense signal to the four touch channel lines 141 formed on the flexible printed circuit board 150 To the touch IC 140 via the touch panel.

Particularly, the analog unit 129 divides the time during the touch sensing period and supplies the touch pulse to the touch panel 110 through the switching unit 125, And converts the transmitted analog sense signals into the digital sense signals.

The touch IC 140 will now be described.

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 supplied to each touch electrode is measured using the digital sense signal And detects whether or not each touch electrode is touched.

That is, the touch IC 140 receives the digital sensing signal and analyzes the digital sensing signal using an analysis program using a self-capping method to detect whether or not the touch panel is touched.

4, the touch IC 140 is connected to the touch electrodes 131 through the display driver IC 120, and in particular, the touch ICs 140 are formed on the display driver IC 120. [ And is connected to the touch electrodes 131 through an analog part 129.

The touch IC 140 may be connected to the display driver IC 120 through the flexible printed circuit (FPC) 150, as shown in FIG.

The digital sensing signal may be transmitted from the display driver IC 120 to the touch IC 140 through at least two touch channel lines 141 formed on the flexible printed circuit board 150 have.

4, the touch IC 140 includes a memory 143 storing the analysis program and the digital sensing signal received from the display driver IC 120 using the analysis program And a touch sensing unit 142 for sensing whether the touch panel 130 is touched.

The analysis program may use the same analysis program as the analysis program used to detect whether the panel is touched or not in a touch IC applied to a general touch panel integrated display device.

The memory 143 may be a flash memory. Generally, since the manufacturing process of the flash memory is different from the manufacturing process of the display driver IC 120, the memory 143 is difficult to be formed in the display driver IC 120.

As described above, the touch channel lines 141 include four touch channel lines 141 for transmitting the digital sense signal and one touch channel line 141 for transmitting the touch synchronous signal. .

In particular, the touch IC 140 receives the digital sensing signals in units of the group, analyzes the digital sensing signals using an analysis program using a self-capping method, and detects whether the touch panel is touched Can be performed.

A driving method of the touch panel integrated display device according to the present invention having the above-described configuration will now be described.

The method of driving a touch panel integrated type display device according to the present invention is characterized in that when the video display period comes, a display driver IC (hereinafter, referred to as " display driver IC ") mounted on the panel 110 in which g groups formed by at least two touch electrodes 120) supplies a common voltage to the touch electrodes (131) formed on the panel (110), and when the touch sensing period comes, the display driver IC (120) The display driver IC 120 converts the analog sense signal into a digital sense signal on a group basis when the analog sense signal is received in the group unit, (140), and the touch IC (140) is configured to transmit the digital sense signal to the touch IC (140) Using the Software Using expression analyzes the digital sense signal, and a step of detecting whether or not a touch of the touch panel 130.

Here, in the step of transmitting the digital sensing signal to the touch IC by the group unit, the display driver IC 120 may be mounted on the flexible printed circuit board 150 connected to the display driver IC 120, The touch sensing unit 140 may transmit the digital sensing signal to the touch IC 140 mounted on the flexible printed circuit board through the touch channel lines 141 formed in the touch sensing unit 140. [

In addition, in the step of supplying the touch pulse in units of the group, a touch signal included in one of the touch electrode subgroups of the touch electrode subgroups MUX1, MUX2, and MUX3, which is composed of at least two or more touch electrodes, After the touch pulse is supplied to the electrodes, the touch pulse may be supplied to the touch electrodes included in another touch electrode subgroup. In this case, the groups may be the touch electrode subgroups.

In the method of driving a touch panel integrated type display device according to the first embodiment of the present invention, the step of converting the analog sense signal into the digital sense signal on a group basis includes: Converting the first analog sense signals to the digital sense signals and transmitting to the touch IC 140 while the second analog sense signals are received from the second group, And repeatedly performing the steps of receiving the sensing signals and the second analog sensing signals up to the g-th group.

The display driver IC 120 applied to the touch panel integrated display device according to the first exemplary embodiment of the present invention includes a plurality of g groups A display driver IC mounted on a panel on which a common voltage is supplied, supplying a common voltage to the touch electrodes formed on the panel; When the touch sensing period arrives, the display driver IC supplies a touch pulse in units of the group; Converting the analog sense signal into a digital sense signal by the display driver IC when the analog sense signal is received in the group unit; Transmitting the digital sensed signal to the touch IC by the display driver IC in units of the group; And the touch IC analyzes the digital sensing signal using an analysis program using a self-capping method in units of the group to detect whether or not the touch panel is touched.

Wherein the display driver IC (120) is configured to receive first analog sense signals from a first group of the groups and then receive the first analog sense signals from the second group And transmits the digital sensing signals to the touch IC. The receiving process and the transmitting process can be repeatedly performed until the g-th group.

For example, the touch electrodes 131 may include g touches corresponding to the number of the touch electrodes connected to the group touch electrode switches 126 formed in the display drive IC 120, And M electrode groups MUX1, MUX2, and MUX3. As described above, the g touch electrode subgroups may be the groups. In the following example, g is set to 3.

In this case, each of the group touch electrode switches 126 may be turned on during the touch sensing period, as shown in (a) of FIG. 5, by the first touch of the touch electrode subgroups MUX1, MUX2, The process of supplying the touch pulse to the touch electrodes included in the second sub electrode group MUX1 and then supplying the touch pulse to the touch electrodes included in the second touch electrode sub group MUX2, Can be repeatedly performed up to a small group (MUX3 when g is 3).

Also, the analog unit 129 may include receiving first analog sense signals from the first group of the groups, as shown in Figure 5 (b), receiving second analog sense signals from the second group, Converting the first analog sense signals to first digital sense signals Data1 and transmitting the first digital sense signals Data1 to the touch IC while the first analog sense signals Data1 are received, And repeatedly performing the steps of receiving the second analog sense signals up to the g-th group.

For example, after receiving the first analog sense signals from the first group, the analog unit 129 may receive the first analog sense signals from the first digital analog < RTI ID = 0.0 > Signals Data1. The analog unit 129 transmits the first digital sensing signals Data1 to the touch IC 140 while the second analog sensing signals are received.

The analog unit 129 receives the second analog sense signals from the second group and then transmits the second analog sense signals to the second digital analog signals Data2 ). The analog unit 129 transmits the second digital sensing signals Data2 to the touch IC 140 while the third analog sensing signals are received.

The analog unit 129 receives the third analog sense signals from the third group and then converts the third analog sense signals into the third digital analog signals Data 3 during the video display period. The analog unit 129 transmits the third digital sensing signals Data3 to the touch IC 140 during the video display period.

In the method of driving a touch panel integrated type display device according to the second embodiment of the present invention, the step of converting the analog sense signal into the digital sense signal in units of groups may include: converting k (k) The first step of supplying the touch pulse to the first group of the first touch electrode subgroup MUX1 of the touch electrode subgroups MUX1, MUX2 and MUX3 of the first touch electrode subgroup MUX2, A second step of converting the analog sense signals received from the first group of the first touch electrode subgroup into the digital sense signals while supplying the touch pulse to the first group and transmitting the analog sense signals to the touch IC 140 A third step of repeatedly performing the first step and the second step up to the kth touch electrode subgroup, a fourth step of supplying the touch pulse to the second group of the first touch electrode subgroup, As a second group of electrode subgroups A fifth step of converting the analog sense signals received from the second group of the first touch electrode subgroup into the digital sense signals and supplying the analog sense signals to the touch IC while supplying the first touch pulse, A sixth step of repeatedly performing the fifth step to the kth touch electrode subgroup and a seventh step of repeatedly performing the first step to the sixth step to the gth group of the kth touch electrode small group do.

For example, as shown in FIGS. 6A and 6B, the display driver IC 120 includes k (= 3) number of touch electrodes including g (= 3) The touch pulse is supplied to the first group of the first touch electrode subgroup MUX1 of the small groups MUX1, MUX2, and MUX3 (first step). That is, in the following example, each of the first to third touch electrode subgroups includes three groups, and the touch pulse is simultaneously supplied to each of the groups formed in the touch electrode subgroups.

The display driver IC 120 then applies the touch pulse to the first group of the second touch electrode subgroup MUX2 while supplying the touch pulse to the first group of the first touch electrode subgroup MUX2, The sensing signals are converted into the 1-1 digital sensing signals Data 1-1 and the 1-1 digital sensing signals Data 1-1 are transferred to the touch IC 140 in a second step.

Next, the display driver IC 120 repeatedly performs the first step and the second step up to the kth touch electrode subgroup (step 3). Accordingly, the three digital sense signals Data1-1, Data2-1, and Data3-1 shown in FIG. 6B are transmitted to the touch IC 140. [

Next, the display driver IC 120 supplies the touch pulse to the second group of the first touch electrode subgroup MUX1 (step 4).

Next, the display driver IC 120 applies the analog sense signals received from the second group of the first touch electrode subgroups to the first group of the first touch electrode subgroups while supplying the touch pulse to the second group of the second touch electrode subgroups -2 digital sensing signals Data1-2 and transmits the first and second digital sensing signals Data1-2 to the touch IC (step 5).

Next, the display driver IC 120 repeatedly performs the fourth step and the fifth step to the kth touch electrode subgroup (step 6). Accordingly, three pieces of digital sensing signals Data1-2, Data2-2, and Data3-2 among the digital sensing signals shown in FIG. 6B are transmitted to the touch IC 140. FIG.

Next, the display driver IC 120 repeatedly performs the first to sixth steps up to the g-th group of the k-th touch electrode subgroup (step 7). Thus, the remaining three digital sense signals (Data 1-3, Data 2-3, Data 3-3) of the digital sense signals shown in FIG. 6 (b) are transmitted to the touch IC.

Hereinafter, a method of driving a touch panel integrated type display device according to the present invention will be described briefly with reference to a second embodiment, after having been described in more detail with reference to the first embodiment. In this case, in the first embodiment, the first to third touch electrode subgroups MUX1, MUX2, MUX3 correspond to the groups, and in the second embodiment, the first to third touch electrode subgroups MUX1, MUX2, and MUX3, respectively.

In the first step, when the operation time of the touch panel integrated type display apparatus according to the present invention is an image display period, the touch synchronous signal generating unit 122, under the control of the controller 121, And transmits the generated signal to the first switch 127 of each group touch electrode switch 126 constituting the switching unit 125. [ The channel switching signal generator 123 generates the 0th channel switching signal 00 and outputs the 0th channel switching signal 00 to the second switcher 126 of each group touch electrode switch 126 forming the switching unit 125. [ 128).

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 switch 128, Are switched according to the zeroth channel switching signal and are connected to all the MUX channels (touch electrode lines) 132.

The common voltage Vcom generated from the common voltage generating unit 124 is applied to the touch electrode switch 126 through the switching unit 125. As a result, And is supplied to all the touch electrodes 131 constituting the panel 130.

In step 4, when the image display period is over and the touch sensing period arrives, the touch synchronous signal generating unit 122 generates the first touch synchronous signal '1' according to the control of the controller 121 To the first switching unit 127 of each group touch electrode switch 126 constituting the switching unit 125. [ The channel switching signal generator 123 generates the first channel switching signal 01 and outputs the first channel switching signal 01 to the second switching unit 126 of each group touch electrode switch 126, 128).

In a fifth step, the first switches 127 are switched according to the first touch synchronous signal ('1') to be connected to the analog unit 129, and the second switches 128 And is switched according to the one-channel switching signal to be connected to the first mux channels.

The first touch pulse generated from the analog unit 129 is inputted to the switch unit 125 through the switching unit 125 as the sixth touch electrode switch 126 is connected as described above, And is supplied to the touch electrodes connected to the first mux channels among all the touch electrodes 131 constituting the touch panel 110. The touch electrodes connected to the first mux channels form the first touch electrode subgroup MUX1.

The analog unit 129 oscillates the first touch pulse through 80 analog channel lines 129a. In this case, since each of the analog channel lines 129a is connected to the pre-set touch electrode, the touch IC 140 connected to the analog unit 129 connects each analog channel line 129a The touch sensing unit can determine whether the touch electrode is touched by analyzing the digital sensing signal transmitted through the touch sensing unit using the analysis program.

5A, the display driver IC 120 supplies a touch pulse to the first touch electrode sub-group MUX1 to apply a touch pulse to the first touch electrode sub-group MUX1, 1 Receive analog sense signals (MUX1 Sensing). The display driver IC 120 converts the received first analog sense signals into first digital sense signals Data1 and outputs the first digital sense signals Data1 at a timing as shown in FIG. Signals (Data1) to the touch IC (140).

The touch IC 140 may determine whether the touch electrode is touched by using a change amount of the capacitance of the touch electrode 131 or the like. That is, the touch IC 140 can determine whether the touch electrodes 131 corresponding to the first touch electrode subgroup MUX1 are touched by using the first digital sense signals Data1.

In the seventh step, the first touch pulse is supplied to the touch electrodes 131 connected to the first mux channels CH1 during 1/3 of the entire touch sensing period, The channel switching signal generating unit 123 generates the second channel switching signal '10' according to the control of the switching unit 121 and supplies the group switching signal to the group touch electrode switching unit 126 To the second switch 128 of the second switch. 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 touch synchronizing signal generating unit 122 of the group touch electrode switching unit 126, To the switching unit 127.

In the eighth step, the first switches 127 are switched according to the first touch synchronizing signal '1' continuously supplied to be connected to the analog unit 129, and the second switches 128 Are switched according to the second channel switching signal '10' and are connected to the second MUX channels CH2.

The second touch pulse generated from the analog unit 129 is input to the touch unit 125 through the switching unit 125 as a result of the connection of the group touch electrode switch 126, And is supplied to the touch electrodes connected to the second mux channels CH2 among all the touch electrodes 131 constituting the panel 130. [

That is, the second touch pulse is supplied to the touch electrodes 131 connected to the second mux channel CH2 during a period corresponding to the second one-third of the touch sensing period. For this, the controller 121 may transmit a control signal requesting the analog unit 129 to output the first touch pulse.

The analog unit 129 oscillates the second touch pulse through 80 analog channel lines 129a. In this case, since each of the analog channel lines 129a is connected to the pre-set touch electrode, the touch IC 140 connected to the analog unit 129 connects each analog channel line 129a The touch sensing unit can determine whether the touch electrode is touched by analyzing the digital sensing signal transmitted through the touch sensing unit using the analysis program. In this case, the touch IC 140 can determine whether the touch electrode is touched by using a change amount of the capacitance of the touch electrode 131 or the like.

5A, the display driver IC 120 supplies a touch pulse to the second touch electrode sub-group MUX2 to apply a touch pulse to the second touch electrode sub-group MUX1, 2 Receive analog sense signals (MUX2 Sensing). The display driver IC 120 converts the received second analog sense signals into second digital sense signals Data2 and outputs the second digital sense signals Data2 at a timing as shown in FIG. Signals (Data2) to the touch IC (140).

The touch IC 140 may determine whether the touch electrode is touched by using a change amount of the capacitance of the touch electrode 131 or the like. That is, the touch IC 140 can determine whether or not the touch electrodes 131 corresponding to the second touch electrode subgroup MUX2 are touched by using the second digital sense signals Data2.

In the tenth step, the second touch pulse is supplied to the touch electrodes connected to the second mux channels (CH2) during another 1/3 of the entire touch sensing time, The channel switching signal generator 123 generates the third channel switching signal 11 'and outputs the third channel switching signal' 11 'to the switching unit 125 of the group touch electrode switching unit 126, 2 < / RTI > The touch synchronizing signal generator 122 still generates the first touch synchronizing signal '1' and supplies the first touch synchronizing signal '1' to the first switcher 126 of each group touch electrode switch 126, which constitutes the switching unit 125, (127).

In step 11, the first switches 127 are switched according to the first touch synchronizing signal '1' continuously supplied to the analog switch 129, and the second switch 128 Are switched according to the third channel switching signal '11' and are connected to the third mux channels CH3.

The third touch pulse generated from the analog unit 129 is input to the switching unit 125 through the switching unit 125 as the twin group touch electrode switch 126 is connected as described above. And are supplied to the touch electrodes connected to the third mux channels CH3 among all the touch electrodes 131 constituting the touch panel 130. [

 That is, the third touch pulse is supplied to the touch electrodes 131 connected to the third mux channel CH3 during a third one-third of the touch sensing period. For this, the controller 121 may transmit a control signal requesting the analog unit 129 to output the first touch pulse.

The analog unit 129 oscillates the second touch pulse through 80 analog channel lines 129a. In this case, since each of the analog channel lines 129a is connected to the pre-set touch electrode, the touch IC 140 connected to the analog unit 129 connects each analog channel line 129a The touch sensing unit can determine whether the touch electrode is touched by analyzing the digital sensing signal transmitted through the touch sensing unit using the analysis program. In this case, the touch IC 140 can determine whether or not the touch electrode is touched by using the change amount of the capacitance of the touch electrode 131.

5 (a), the display driver IC 120 supplies a touch pulse to the third touch electrode sub-group MUX3 to apply a touch pulse to the third touch electrode sub-group MUX3, 3 Receive analog sense signals (MUX3 Sensing). The display driver IC 120 converts the received third analog sense signals into third digital sense signals Data3 and outputs the third digital sense signals Data3 at a timing as shown in FIG. And transmits the signals Data3 to the touch IC 140. [

The touch IC 140 may determine whether the touch electrode is touched by using a change amount of the capacitance of the touch electrode 131 or the like. That is, the touch IC 140 can determine whether the touch electrodes 131 corresponding to the third touch electrode subgroup MUX3 are touched by using the third digital sense signals Data1.

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

Meanwhile, in the second embodiment of the present invention, the period corresponding to 1/3 of the touch sensing period may be further divided into three periods. For example, as shown in FIG. 6, the display driver IC 120 is formed in the first touch electrode sub-group MUX1 during a period corresponding to the first 1/9 of the touch sensing period And receives the 1-1 analog sense signals from the first group (Mux1 Sensing).

During a second one-ninth period, the display driver IC 120 senses during the second -1 analog sense signals from the first group formed in the second touch electrode sub-group MUX2 (Mux2 Sensing ), Converts the 1-1 analog sense signals into the 1-1 digital sense signals Data1-1, and then outputs the 1-1 second digital sense signals Data1-1 in FIG. And transmits it to the touch IC 140 at the timing shown in (b).

During the third 1/9 period, the display driver IC 120 senses (MUX2 Sensing) while receiving the 3-1 analog sense signal from the first group formed in the third touch electrode subgroup MUX3, , And transmits the second 2-1 digital sense signals (Data 2-1) to the touch IC 140.

From the period corresponding to the fourth 1/9, during the period corresponding to the sixth 1/9, the 1-2 digital sensing signals Data 1-2, the 2-2 digital sensing signals Data 1-2, The 3-2 digital sense signals Data3-2 are generated and transmitted to the touch IC 140. [

From the period corresponding to the seventh 1/9, during the period corresponding to the ninth 1/9, the first to third digital sense signals Data 1-3, the second to third digital sense signals Data 2-3, And the third 3-3 digital sensing signals Data 3-3 are generated and transmitted to the touch IC 140.

The touch IC 140 analyzes the digital sensing signals when the digital sensing signals are received, and determines whether the touch panel 130 is touched.

The touch panel integrated display device according to the present invention as described above can be summarized as follows.

The conventional touch panel integrated display device is a bulky flexible printed circuit due to a touch IC having a large number of touch channel lines (80 to 88 lines) and a relatively large chip size (6 x 6 mm ² ) Circuit board, which limits the module design and serves as a limiting factor in the conclusion of the system set. [0008] Also, excessive touch channel lines and relatively large chip sizes The touch ghost noise is liable to be caused. In addition, since the number of pins of the touch IC and the display driver IC is increased, the defect rate is increased during the module process .

In the touch panel integrated type display device according to the present invention, an analog part for performing an analog operation among the conventional touch ICs is connected to the display driver IC 120). Accordingly, the touch IC 140 applied to the touch panel integrated type display device according to the present invention includes a touch sensing unit 140 for sensing whether the touch IC 140 is touching using a digital sensing signal and an analysis program generated from the analog unit, (142), and the memory (143) storing the analysis program.

According to the present invention, since the touch IC 140 is mounted on the flexible printed circuit board 150, the plurality of touch channel lines 141 may not be exposed to the flexible printed circuit board 150. In addition, the chip size of the touch IC 140 may be reduced to about 1/4 (3 x 3 mm ² ).

In this case, only about 5 to 6 touch channel lines 141 for interface between the display drive IC 120 and the touch IC 140 may be exposed on the flexible printed circuit board 140 .

Accordingly, the touch ghost noise due to the external impact is eliminated, and the degree of freedom of module design can be increased. In addition, the defective rate at the time of chip mounting can also be reduced.

The display driver IC 120 may be configured to transmit serial data, such as an SPI interface, with the touch IC 140, and may operate as a slave.

The touch IC 140 can operate mainly as a master. The touch IC 140 may receive a synchronization signal from the display driver IC 120 to determine a transmission timing of the digital sensing signal.

The display driver IC 120 may include a storage unit for storing analog sense signals for each of the mux channels CH1, CH2, and CH3. The storage unit may be formed in the analog unit 129 of the driver IC 120 or may be formed independently of the analog unit 129.

The display driver IC 120 may generate the synchronization signal to transmit the digital sensing signal, which has been converted in the analog unit 129, to the touch IC 140. [

Conventionally, when the touch sensing operation is completed in the display driver IC, the received analog sensing signals are transmitted to the touch IC, and the touch analysis process (algorithm processing) is performed in the touch IC. In this case, while the analog sense signals are being transmitted to the touch IC, the algorithm processing can not proceed smoothly and the waiting state is maintained until the transmission is completed. This acts as a loss time, delaying the algorithm processing time and ultimately worsening latency, an important touch characteristic. As a result, the user determines that the touch response speed is slow. In addition, the above issues may also interfere with the implementation of the 120Hz report rate.

In order to solve the above-described problems, the present invention provides a method of controlling a touch panel of a display device, such that before all the sensing operations on the touch panel (130) in the analog unit (129) And converts the detected analog sense signals into digital sense signals and transmits the digital sense signals to the touch IC 140. [ That is, the present invention can implement a more efficient driving method by paralleling the hardware sensing and the digital sensing signal (data) transmission.

In other words, the present invention is characterized in that when the first analog sense signals for the first group are received (Mux1 sensing), the first digital sense signals are transmitted to the touch IC 140 and the second When the analog sense signals are received (Mux2 sensing), the second digital sense signals are transmitted to the touch IC 140, and when the third analog sense signals for the third group are received (Mux3 sensing) To the touch IC (140). According to the present invention, since the detection signals can be efficiently transmitted, the algorithm processing time delay is minimized, so that fast latency and high report rate can be achieved.

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: flexible printed circuit board 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 switcher 129: analog part
140: Touch IC 141: Touch channel line
142: Touch sensing unit 143: Memory

Claims (10)

A panel formed with a pixel defined by the intersection of the data line and the gate line;
A touch panel having g groups formed by at least two or more touch electrodes formed integrally with the panel;
A display driver for supplying touch pulses in units of groups and dividing time during a touch sensing period to receive analog sensing signals from the touch panel in units of groups and converting the analog sensing signals into digital sensing signals; IC; And
And a touch IC for receiving the digital sensing signals and analyzing the digital sensing signals using an analysis program using a self-capping method to detect whether or not the touch panel is touched. The method according to claim 1,
The touch IC is mounted on a flexible printed circuit board,
Wherein the digital sensing signals are transmitted from the display driver IC to the touch IC through 2 to 7 touch channel lines formed on the flexible printed circuit board. The method according to claim 1,
The display driver IC includes:
After receiving the first analog sense signals from the first group, converting the first analog sense signals into the digital sense signals while the second analog sense signals are received from the second group, To the IC, and performs the receiving process and the transmitting process repeatedly to the g-th group. The method according to claim 1,
The touch electrodes are divided into g touch electrode subgroups corresponding to the number of touch electrodes connected to each of the group touch electrode switchers formed in the display drive IC,
Each of the group touch electrode switchers supplies the touch pulse to the touch electrodes included in the first touch electrode subgroup of the touch electrode subgroups during the touch sensing period and then supplies the touch pulse to the second touch electrode subgroup And the touch pulse is repeatedly supplied to the g-th touch electrode group,
Wherein the groups are the touch electrode subgroups. The method according to claim 1,
The display driver IC includes:
A common voltage generator for generating a common voltage to be supplied to the touch electrode;
A plurality of group touch electrode switching units connected to the at least two touch electrode lines among the plurality of touch electrode lines;
And an analog to digital converter for converting the analog sense signals transmitted in the group unit from the touch panel to the digital sense signals through the switching unit, part;
A touch synchronizing signal generator for generating a touch synchronizing signal for connecting the touch electrode lines to the common voltage generator or for connecting the touch electrode lines to the analog voltage generator in group units; And
The touch electrode lines are connected to all the touch electrode lines during the video output time, and during the touch sensing period, the touch electrode lines connected to each of the group touch electrode switches are divided into the group- And a channel switching signal generator for generating a channel switching signal to be connected to the analog unit. When a video display period is reached, a display driver IC mounted on a panel having g groups formed of at least two touch electrodes supplies a common voltage to the touch electrodes formed on the panel;
When the touch sensing period arrives, the display driver IC supplies a touch pulse in units of the group;
Converting the analog sense signal into a digital sense signal by the display driver IC when the analog sense signal is received in the group unit;
Transmitting the digital sensed signal to the touch IC by the display driver IC in units of the group; And
And the touch IC analyzing the digital sensed signal using an analysis program using a self-capping method in units of the group, and detecting whether the touch panel is touched. The method according to claim 6,
Wherein the step of transmitting the digital sense signal to the touch IC by the group comprises:
Wherein the display driver IC is connected to the touch ICs mounted on the flexible printed circuit board through touch channel lines formed on a flexible printed circuit board connected to the display driver IC, Wherein the display unit is connected to the touch panel. The method according to claim 6,
Wherein the step of supplying the touch pulse in units of groups comprises:
The touch pulse is supplied to the touch electrodes included in one of the plurality of touch electrode subgroups of the plurality of touch electrode subgroups having at least two or more touch electrodes, Supplies the touch pulse to the touch panel,
Wherein the groups are the touch electrode subgroups. The method according to claim 6,
Wherein the step of converting the analog sense signal into a digital sense signal,
Receiving, among the groups, first analog sense signals from a first group;
Converting the first analog sense signals into the digital sense signals and transmitting them to the touch IC while the second analog sense signals are received from the second group;
And repeatedly performing the steps of receiving the first analog sense signals and the second analog sense signals up to the gth group. 10. The method of claim 9,
Wherein the step of converting the analog sense signal into a digital sense signal,
A first step of supplying the touch pulse to a first group of a first touch electrode subgroup among k touch electrode subgroups each including g groups;
Converts the analog sense signals received from the first group of the first touch electrode subgroup into the digital sense signals while supplying the touch pulse to the first group of the second touch electrode subgroups and transmits the analog sense signals to the touch IC A second step;
A third step of repeating the first step and the second step repeatedly up to the kth touch electrode subgroup;
A fourth step of supplying the touch pulse to a second group of the first touch electrode subgroup;
Converts the analog sense signals received from the second group of the first touch electrode subgroup into the digital sense signals while supplying the touch pulse to the second group of the second touch electrode subgroup and transmits the analog sense signals to the touch IC Step 5;
A sixth step of repeating the fourth step and the fifth step repeatedly up to the kth touch electrode subgroup; And
And a seventh step of repeating the first to sixth steps to the g-th group of the k-th touch electrode subgroup.

Images