KR101378345B1 - Display Device Including Touch Module And Method Of Driving The Same - Google Patents

Abstract

According to the present invention, a plurality of transmission wires to which a drive signal is input, a plurality of reception wires intersecting the plurality of transmission wires, and one end of the plurality of reception wires are configured and divided into first to L-th channel groups. A touch panel including first to nth channels; First to Mth sensing blocks for simultaneously integrating M detection signals output from each of the first to Lth channel groups according to a group input signal; M pairs of first and second sample holding amplifiers each of which holds M detection signals output from the first to Mth sensing blocks, and sequentially outputs the M detection signals according to a channel output signal; An analog-digital converter for sequentially converting the M detection signals output from the M pairs of the first and second sample holding amplifiers from analog to digital; And a micro control unit for controlling the first to Mth sensing blocks and the M pair of first and second sample holding amplifiers and receiving M detection signals from the analog-digital converter.

Description

Display Device Including Touch Module And Method Of Driving The Same}

The present invention relates to a display device including a touch module, and in particular, by simultaneously detecting the detection signals of a plurality of receiving channels, the signal distortion component due to offset and noise is minimized, and the dynamic range and signal noise ratio of the detection signal are improved. A display device comprising a and a driving method thereof.

In line with the information age, the display field has also been rapidly developed, and as a flat panel display device (FPD) with the advantages of thinning, light weight, and low power consumption, a liquid crystal display device (LCD) has been developed. ), Plasma display panel device (PDP), electro luminescence display device (ELD), field emission display device (FED), etc. : It is rapidly replacing CRT.

Recently, a touch screen, which is a display device having a touch panel attached to such a display panel, has been in the spotlight.

The touch screen is used as an output means for displaying an image and is used as an input means for inputting a command of a user by touching a specific portion of the displayed image. The touch panel is classified into a decompression system, , An infrared method, and an ultrasonic method.

That is, when the user touches the touch panel while viewing the image displayed on the display panel, the touch panel can detect the position information of the corresponding part and compare the detected position information with the position information of the image to recognize the user's command.

Such a touch screen may be manufactured in such a manner that a separate touch panel is attached to the display panel or the touch panel is formed on the substrate of the display panel and integrated.

The configuration of the touch module including the touch panel and the touch driver will be described with reference to the drawings.

1 is a view showing the configuration of a conventional touch module, Figure 2 is a timing diagram for a signal used in the conventional touch module.

As shown in FIG. 1, the conventional touch module includes a touch panel 10 that detects position information corresponding to a user's touch point, and supplies a driving signal to the touch panel 10, and supplies the drive signal from the touch panel 10. The touch driver 20 receives a detection signal.

The touch panel 10 includes a plurality of transmission wires 12 spaced apart in parallel with each other, and a plurality of reception wires 14 crossing the plurality of transmission wires 12 and spaced in parallel with each other. The wiring 12 and the plurality of receiving wirings 14 are electrically insulated from each other so that an intersection point of the plurality of transmitting wirings 12 and the plurality of receiving wirings 14 constitutes a capacitor Cm.

One end of the plurality of receiving wires 14 constitutes a plurality of channels CH1 to CHN for outputting a plurality of detection signals.

The touch driver 20 includes a plurality of sensing blocks SB1 to SBN 30 connected to a plurality of channels CH1 to CHN, which are ends of the plurality of receiving wires 14, respectively, and operating according to a channel input signal. A mux 40 for selecting one of the plurality of sensing blocks 30 according to the channel selection signal, and an analog-to-digital converter for converting an analog signal received from the mux 40 into a digital signal. digital converter (ADC) 50, a clock generator and digital control logic (CG & DCL) 60 for generating a clock and a plurality of control signals used in the touch driver 20, and a plurality of sensings. And a micro-control unit (MCU) 70 for controlling the block 30, the mux 40, and the control logic unit 60.

Referring to the operation of the touch module, first, a pulse type driving signal VP is sequentially input to the plurality of transmission wires 12 of the touch panel 10.

For example, the touch driver 20 applies the driving signal Vp to one of the plurality of transmission lines 12 for a predetermined time period, and applies a fixed DC voltage Vd to the remaining plurality of transmission lines 12. Is authorized.

When a touch occurs while driving signals Vp are applied to the plurality of transmission wires 12, the capacitance of the capacitor Cm formed at the intersection of the plurality of transmission wires 12 and the plurality of receiving wires 14. The change, and the touch driver 20 detects the change in capacitance to determine the touch point.

To this end, the plurality of sensing blocks 30 sequentially receive and integrate a plurality of detection signals from the plurality of receiving wires 14, and are connected to the analog-to-digital converter 50 through the mux 40 and integrated. Pass the signal.

In addition, the analog-to-digital converter 50 converts the analog detection signal into a digital signal and transmits it to the micro control unit 70, and the micro control unit 70 analyzes the digital detection signal to detect a touch point.

As shown in FIG. 2, which shows a plurality of control signals for the operation of the touch driver 20, the first sensing block SB1 is applied during the first sensing block section TSB1 according to the first channel input signal CHI1. The detection signal of the first channel CH1 is received and integrated, and the second sensing block SB2 detects the second channel CH2 during the second sensing block section TSB2 according to the second channel input signal CHI2. Receive and integrate the signal.

Similarly, the plurality of sensing blocks 30 receive and integrate detection signals sequentially according to a plurality of channel input signals, and finally, the Nth sensing block SBN senses the Nth sensing according to the Nth channel input signal CHIN. The detection signal of the N-th channel CHN is received and integrated during the block section TSBN.

In addition, the analog-to-digital converter 50 does not operate during the zeroth conversion period TADC0 until a predetermined time passes, and then detects the detection signal of the first sensing block SB1 during the first conversion period TADC1. After the conversion, the detection signal of the second sensing block SB2 is converted during the second conversion period TADC2, and then the detection signals of the plurality of sensing blocks 30 are sequentially converted.

In the conventional touch module operating as described above, the number and speed of the channels (report rate or touch frame rate) must be increased to increase the number of sensing blocks accordingly.

However, as the number of channels increases, the offset due to process nonuniformity (e.g., non-uniformity of wiring thickness, line width, insulation layer thickness, etc.) between a plurality of receiving wirings forming a plurality of channels is increased. As a result, nonuniformity occurs between detection signals processed in the plurality of sensing blocks.

In addition, since the plurality of sensing blocks sequentially process the detection signals of the plurality of channels, nonuniformity occurs between the detection signals processed in the plurality of sensing blocks due to time-varying noise caused by the operation of the display panel.

The nonuniformity of the detection signal in the plurality of sensing blocks generates various secondary distortions. The larger the secondary distortion, the lower the dynamic range of the detection signal due to the signal correction of subsequent digital processing and the signal noise ratio ( The signal to noise ratio (SNR) is degraded, and in severe cases, there is a problem in that a touch and noise cannot be distinguished.

SUMMARY OF THE INVENTION The present invention has been proposed to solve this problem, and the detection of offset and noise components by dividing a plurality of channels into a plurality of groups and simultaneously processing the detection signals of a plurality of channels belonging to one group with a plurality of sensing blocks. It is an object of the present invention to provide a display device including a touch module, in which a secondary distortion component of a signal is removed and an effective range of a detection signal and a signal noise ratio are improved.

In order to solve the above problems, the present invention comprises a plurality of transmission wirings to which a drive signal is input, a plurality of receiving wirings crossing the plurality of transmission wirings, and one end of the plurality of receiving wirings. A touch panel including first to Nth channels divided into L-th channel groups; First to Mth sensing blocks for simultaneously integrating M detection signals output from each of the first to Lth channel groups according to a group input signal; M pairs of first and second sample holding amplifiers each of which holds M detection signals output from the first to Mth sensing blocks, and sequentially outputs the M detection signals according to a channel output signal; An analog-digital converter for sequentially converting the M detection signals output from the M pairs of the first and second sample holding amplifiers from analog to digital; And a micro control unit for controlling the first to Mth sensing blocks and the M pair of first and second sample holding amplifiers and receiving M detection signals from the analog-digital converter.

The touch module may further include: M first muxes configured to select one of the first to Lth channel groups according to a group selection signal and simultaneously transmit M detection signals to the first to Mth sensing blocks; A second mux for sequentially selecting the M pairs of the first and second sample holding amplifiers according to a channel selection signal and sequentially transmitting the M detected signals to the analog-digital converter; The apparatus may further include a control logic unit configured to generate and provide the group input signal, the channel output signal, the group selection signal, and the channel selection signal.

In addition, each of the first to Mth sensing blocks includes first and second input terminals, and the detection signal and the reference voltage of one of the first to Nth channels are respectively provided to the first and second input terminals. The detection signals of two of the first to Nth channels may be input.

On the other hand, the present invention comprises a plurality of transmission wirings to which a drive signal is input, a plurality of receiving wirings intersecting the plurality of transmitting wirings, and one end of the plurality of receiving wirings, and are divided into first to L-th channel groups. A touch panel including first to Nth channels; First to Mth sensing blocks for simultaneously integrating M detection signals output from each of the first to Lth channel groups according to a group input signal; M pairs of first and second sample holding amplifiers each of which holds M detection signals output from the first to Mth sensing blocks, and sequentially outputs the M detection signals according to a channel output signal; An analog-digital converter for sequentially converting the M detection signals output from the M pairs of the first and second sample holding amplifiers from analog to digital; A micro control unit for controlling the first to Mth sensing blocks and the M pairs of first and second sample holding amplifiers and receiving M detection signals from the analog-digital converter; A display panel disposed under the touch panel to display an image; Provided is a display device including a touch module including a display driver for supplying an image signal and a control signal to the display panel.

On the other hand, according to the present invention, the first to M-th sensing block integrates M detection signals output from each of the first to L-th channel groups of the first to Nth channels of the touch panel simultaneously according to the group input signal. Making a step; Maintaining M detected signals output from the first to Mth sensing blocks, and sequentially outputting the M pairs of first and second sample holding amplifiers according to channel output signals; A method of driving a touch module, comprising the steps of converting the M detection signals output from the M pairs of the first and second sample holding amplifiers sequentially from an analog-to-digital converter to a micro control unit. to provide.

In the method of driving the touch module, M first mux selects one of the first to Lth channel groups according to a group selection signal to simultaneously transmit the M detection signals to the first to Mth sensing blocks. Delivering; The second mux may further include sequentially selecting the M pairs of the first and second sample holding amplifiers according to a channel selection signal and sequentially transmitting the M detection signals to the analog-digital converter.

In addition, each of the first to Mth sensing blocks includes first and second input terminals, and the detection signal and the reference voltage of one of the first to Nth channels are respectively provided to the first and second input terminals. The detection signals of two of the first to Nth channels may be input.

On the other hand, the present invention comprises the steps of supplying a video signal and a control signal to the display driver; Displaying, by the display panel, an image using the image signal and the control signal; Simultaneously integrating M detection signals output from each of the first to Lth channel groups of the first to Nth channels of the touch panel on the display panel according to the group input signal. Wow; Maintaining M detected signals output from the first to Mth sensing blocks, and sequentially outputting the M pairs of first and second sample holding amplifiers according to channel output signals; A display module including a touch module including converting the M detection signals output from the M pairs of the first and second sample holding amplifiers sequentially from an analog-to-digital converter to a micro control unit; It provides a method of driving a device.

In addition, the driving method of the display device including the touch module may include: detecting position information of a touch point by analyzing the detection signal; The method may further include recognizing a command by comparing the location information of the touch point with the location information of the image.

According to the present invention, by simultaneously processing the detection signals of a plurality of channels with a plurality of sensing blocks, the secondary distortion components of the detection signal such as offset and noise components are removed, and the effective range and signal noise ratio of the detection signal are improved. have.

In addition, the present invention has an effect of further improving the effective range and signal noise ratio of the detection signal by differentially inputting and simultaneously detecting the detection signals of the plurality of channels to the plurality of sensing blocks.

1 is a view showing the configuration of a conventional touch module.
2 is a timing diagram for signals used in a conventional touch module.
3 is a diagram illustrating a configuration of a display device including a touch module according to a first embodiment of the present invention.
4 is a diagram illustrating a configuration of a touch module according to a first embodiment of the present invention.
5 is a timing diagram for signals used in the touch module according to the first embodiment of the present invention.
6 is a circuit diagram showing the configuration of a sensing block, a first sample holding amplifier, and a second sample holding amplifier of the touch module according to the first embodiment of the present invention;
7 is a diagram illustrating a configuration of a touch module according to a second embodiment of the present invention.

Hereinafter, a display device including a touch module and a driving method thereof will be described with reference to the accompanying drawings.

3 is a diagram illustrating a configuration of a display device including a touch module according to a first embodiment of the present invention.

As shown in FIG. 3, the display device 100 including the touch module according to the first embodiment of the present invention includes a touch panel 110 for detecting position information corresponding to a touch point of a user, and a touch panel. A touch driver 120 that supplies a driving signal to the 110 and receives a detection signal from the touch panel 110, a display panel 210 disposed under the touch panel 110 to display an image, and a display panel ( And a display driver 220 for supplying an image signal and a control signal to the 210.

Although not illustrated, a plurality of gate wires and a plurality of data wires may be formed in the display panel 210, and thin film transistors may be formed in each of the plurality of pixels defined by the intersection of the plurality of gate wires and the plurality of data wires. have.

The display driver 220 may generate a gate signal and apply the same to a plurality of gate lines, and generate a data signal and apply the same to a plurality of data lines.

When the user touches the touch panel 110 in response to a specific portion of the image displayed on the display panel 210, the touch driver 120 detects the position information corresponding to the touch point and transmits the position information to the system, so that the system touches the touch panel 110. The user's command is recognized by comparing the location information of the point with the location information of the image.

The configuration and operation of the touch module will be described with reference to the drawings.

4 is a diagram illustrating a configuration of a touch module according to a first embodiment of the present invention, and FIG. 5 is a timing diagram of signals used in the touch module according to the first embodiment of the present invention.

As shown in FIG. 4, the touch module according to the first embodiment of the present invention supplies a touch signal to the touch panel 110 and the touch panel 110 to detect position information corresponding to a user's touch point. And a touch driver 120 receiving a detection signal from the touch panel 110.

The touch panel 110 includes a plurality of transmission wires 112 spaced apart from each other in parallel with each other, and a plurality of reception wires 114 crossing the plurality of transmission wires 112 and spaced in parallel with each other. The wiring 112 and the plurality of receiving wirings 114 are electrically insulated from each other so that the intersection points of the plurality of transmitting wirings 112 and the plurality of receiving wirings 114 constitute a capacitor Cm.

One end of the plurality of receiving wires 114 configures the first to Nth channels CH1 to CHN for outputting a plurality of detection signals.

The touch driver 120 is connected to each of the first to Nth channels CH1 to CHN, which are ends of the plurality of receiving wires 114, and is one of the first to Nth channels CH1 to CHN according to the group selection signal. M first mux MUX1 to MUXM 130, M sensing blocks SB1 to SBM 140 operating according to a group input signal, and M sensing blocks SB1 to SBM 140. M first sample and hold amplifiers (SHA1) 150 and M second sample holding amplifiers (SHA2) 155 which hold and output the detection signals output from A second mux (160) selecting one of the M first sample holding amplifiers (SHA1) 150 and the analog signal received from the second mux 160 are converted into digital signals according to the channel selection signal. The analog-to-digital converter (ADC) 170 and a clock and a plurality of control signals used in the touch driver 120 are generated. Is a clock logic and digital control logic (CG & DCL) 180, M first mux 130, M sensing block 140, M first sample holding amplifier 150, M And a second sample holding amplifier 155, a second mux 160, and a control logic unit 180 to control the microcontrol unit (MCU) (190).

Referring to the operation of the touch module, first, a pulse type driving signal VP is sequentially input to the plurality of transmission lines 112 of the touch panel 110.

For example, the touch driver 120 applies the driving signal Vp to one of the plurality of transmission lines 112 for a predetermined time period, and applies a fixed DC voltage Vd to the other plurality of transmission lines 112. After that, the driving signal Vp is sequentially applied to the plurality of transmission wires 112.

In this case, the remaining transmission lines 112 to which the driving signal Vp is not applied may be floated.

When a touch occurs in a state where the driving signals Vp are applied to the plurality of transmission lines 112, the capacitance of the capacitor Cm formed at the intersection of the plurality of transmission lines 112 and the plurality of receiving lines 114. The capacitance changes, and the touch driver 120 detects such a change in capacitance to determine a touch point.

Here, the first to Nth channels CH1 to CHN are divided into first to Lth channel groups CG1 to CGL each including M channels (N = MXL) (N ≧ M), and M channels belonging to each of the 1 to L-th channel groups CG1 to CGL (CH1 to CHM, CH (M + 1) to CH (2M), and CH (N-M + 1) to CHN) are each M It is connected to the first mux (MUX1 to MUXM) 130.

The M first mux 130 selects one of the first to Lth channel groups CG1 to CGL according to the group selection signal transmitted from the microcontrol unit (MCU) 190. M detection signals output from the M channels of the group are simultaneously input to the first to Mth sensing blocks SB1 to SBM 140 according to the group input signal transmitted from the microcontrol unit 190 and integrated. do.

In addition, the M detection signals integrated in the first to Mth sensing blocks SB1 to SBM 140 are transferred to the first and second sample holding amplifiers SHA1 and SHA2 150 and 155 of M pairs, respectively. The value is maintained and output according to the channel output signal transmitted from the microcontrol unit (MCU) 190.

The second mux 160 selects one of M pairs of the first and second sample holding amplifiers SHA1 and SHA2 150 and 155 according to the channel selection signal, and selects the selected first and second sample holding amplifiers SHA1. The detection signal output from the SHA2 (150, 155) is transmitted to the analog-to-digital converter (170).

Accordingly, M detection signals output from the M pairs of the first and second sample holding amplifiers SHA1 and SHA2 150 and 155 are sequentially transmitted to the analog-to-digital converter 170 through the second mux 160. do.

Here, the channel selection signal for controlling the second mux 160 may be a signal having the same timing as the channel output signal for controlling the first and second sample holding amplifiers SHA1 and SHA2 150 and 155.

In addition, the analog-to-digital converter 170 converts the analog detection signal into a digital signal and transmits it to the micro control unit 190, and the micro control unit 190 analyzes the digital detection signal to detect a touch point.

The control logic unit CG & DCL 180 generates and provides a clock, a group selection signal, a group input signal, a channel output signal, a channel selection signal, and the like under the control of the micro control unit 190.

The operation of the touch driver 120 will be described in detail with reference to an example.

For example, when the touch panel 110 includes the first to the 100th channels CH1 to CH100 (N = 100), the first to the 10th channels CH1 to CH10 are assigned to the first channel group CG1. The 11 th to 20 th channels CH11 to CH20 may be divided into the second channel group CG2, and the 91 th to 100 th channels CH91 to CH100 may be divided into the 10 th channel group CG10 (M = 10, L = 10), wherein the first to tenth channels CH1 to CH10 of the first channel group CG1 are connected to ten first muxes MUX1 to MUX10, respectively, and the first to the second channel group CG2 of the second channel group CG2. The 11 th to 20 th channels CH11 to CH20 are connected to 10 first mux MUX1 to MUX10, respectively, and the 91 th to 100 th channels CH191 to CH100 of the 10 th channel group CG10 are each 10. It is connected to the first mux MUX1 to MUX10.

That is, one channel of the first to tenth channel groups CG1 to CG10 is connected to each of the ten first muxes MUX1 to MUX10.

When the first channel group CG1 is selected by the ten first mux MUX1 to MUX10 according to the group selection signal, the first to tenth channels CH1 to 10 of the first channel group CG1 according to the group input signal. Ten detection signals of CH10 are simultaneously delivered to and integrated with the first to tenth sensing blocks SB1 to SB10, and the integrated ten detection signals are respectively provided for ten first and second sample holding amplifiers SB1 and SB2. ) And its value is maintained.

The ten detection signals of the first channel group CG1 whose values are maintained in the ten first and second sample holding amplifiers SB1 and SB2 are sequentially transferred to the second mux according to the channel output signal. After transmission, it is converted to digital by an analog-to-digital converter (ADC) and transferred to a micro control unit (MCU).

Thereafter, when the second channel group CG2 is selected by the ten first mux MUX1 to MUX10 according to the group selection signal, the eleventh to twentieth channels of the second channel group CG2 according to the group input signal ( Ten detection signals of CH11 to CH20 are simultaneously delivered to and integrated into the first to tenth sensing blocks SB1 to SB10, respectively, and the integrated ten detection signals are respectively provided to ten first and second sample holding amplifiers SB1. , SB2) and its value is maintained.

The ten detection signals of the second channel group CG2 whose values are maintained in the ten first and second sample holding amplifiers SB1 and SB2 are sequentially transferred to the second mux according to the channel output signal. After transmission, it is converted to digital by an analog-to-digital converter (ADC) and transferred to a micro control unit (MCU).

By applying the same process to the third to tenth channel groups CG3 to CG10, the detection signals of the first to 100th channels CH1 to CH100 are integrated, digitally converted, and transferred to the microcontroller MCU. .

In conclusion, when the touch panel 110 includes the first to 100th channels CH1 to CH100, the detection signal of the adjacent first to 10th channels CH1 to CH10 of the first channel group CG1 is touched. Simultaneously integrated by the first to tenth sensing blocks SB1 to SB10 of the drive unit 120, and sequentially digitally in the state where the values are maintained in the corresponding first and second sample holding amplifiers SB1 and SB2. It is converted and transferred to the micro control unit (MCU).

Subsequently, detection signals of the adjacent eleventh to twentieth channels CH11 to CH20 of the second channel group CG2 are also integrated simultaneously by the first to tenth sensing blocks SB1 to SB10, and corresponding first and fifth signals are simultaneously integrated. In the two-sample holding amplifiers SB1 and SB2, their values are sequentially converted to digital and transferred to the micro control unit MCU, and the remaining channels of the third to tenth channel groups CG3 to CG10 are detected. The signal is transmitted to the micro control unit (MCU) through the same process.

As shown in FIG. 5, which illustrates a plurality of control signals for the operation of the touch driver 120, the M sensing blocks SB1 to SBM have a first group section TG1 according to the first group input signal GI1. Receive and integrate detection signals of the M channels CH1 to CHM belonging to the first channel group CG1 at the same time, and then, during the second group period TG2 according to the second group input signal GI2. The detection signals of the M channels CH (M + 1) to CH (2M) belonging to the channel group CG2 are simultaneously received and integrated.

The M sensing blocks SB1 to SBM process the detection signals for the remaining channel groups in the same manner, and finally, according to the L-th group input signal GIL, the L-channel group ( The detection signals of the M channels CH (N-M + 1) to CHN belonging to CGL are simultaneously received and integrated.

The first and second sample holding amplifiers SHA1 and SHA2 150 and 155 of the M pairs are terminated at the end points of the first to Lth group sections TG1 to TGL according to the channel output signal SHA. In synchronization, M channels belonging to each of the first to L th channel groups CG1 to CGL are sequentially output.

In addition, the analog-to-digital converter 170 does not operate during the zeroth conversion period TADC0 until a predetermined time elapses, and then belongs to the first channel group CG1 during the first conversion period TADC1. The detection signals of the two channels CH1 through CHM are sequentially converted, and the M channels CH (M + 1) through CH (2M) belonging to the second channel group CG2 during the second conversion period TADC2. The detection signal is sequentially converted.

The analog-to-digital converter 170 processes the detection signal for the remaining channel groups in the same manner, and finally, M channels (CH (N−) belonging to the L-th channel group CGL during the L-th conversion period TADCL. The detection signals of M + 1) to CHN) are sequentially converted.

As described above, in the touch module according to the first embodiment of the present invention, the first to Nth channels CH1 to CHN are divided into first to Lth channel groups CG1 to CGL, each of which includes M channels. The first and second sensing signals SB1 to SBM integrate the detection signals of the M channels of the selected channel group among the first to Lth channel groups CG1 to CGL simultaneously. While the values are maintained in the sample holding amplifiers SB1 and SB2, they are sequentially converted to digital and transferred to the micro control unit (MCU), and the remaining channel groups are sequentially processed in the same manner.

Here, M channels belonging to each channel group have similar offsets and noises because they correspond to adjacent reception lines 114. Since the detection signals of the reception lines 114 are integrated at the same time, the size of the detection signal itself is affected. Signal distortion can be prevented by easily eliminating offset and noise components without giving.

Meanwhile, an example of a circuit configuration of the sensing blocks SB1 to SBM 140, the first sample holding amplifier SHA1 150, and the second sample holding amplifier SHA2 155 will be described with reference to the drawings. .

FIG. 6 is a circuit diagram illustrating a configuration of a sensing block, a first sample holding amplifier, and a second sample holding amplifier of the touch module according to the first embodiment of the present invention.

As shown in FIG. 6, the sensing block 140 includes 12 switching elements that are opened and closed according to the first and second switching signals .phi.1 and .phi.2 and the reset switching signal .phi.rst, and four capacitors Cs, Cf) and one operational amplifier (OP AMP).

Each of the first and second sample holding amplifiers 150 and 155 includes eight switching elements that are opened and closed according to the first and second switching signals Φ1 and Φ2 and the channel output signal .phi.shasha, and two capacitors. (Csh) and one operational amplifier (OP AMP).

Here, each of the first and second sample holding amplifiers 150 and 155 maintains or outputs the detection signal, which is controlled by the channel output signal .phi.sha.

In addition, the sensing block 140 includes first and second input terminals 142 and 144, and the first sample holding amplifier 150 includes first and second output terminals 152 and 154. In one embodiment, the detection signal output from the first mux 130 is input to the first input terminal 142, and the reference voltage Vref provided by the touch driver 120 is input to the second input terminal 144. In addition, the detection signal output from the first output terminal 152 of the first sample holding amplifier 150 is transmitted to the second mux 160.

As such, a method of inputting a detection signal to the first input terminal 142 of the sensing block 140 and inputting the reference voltage Vref to the second input terminal 144 of the sensing block 140 is a single input. It is called a method.

Meanwhile, in the touch module according to the first embodiment, the detection signal is input to the sensing block 140 in a single input method. In another embodiment, the detection signal is input to the sensing block in a differential input method to offset and The noise component may be more effectively removed, which will be described with reference to the drawings.

7 is a diagram illustrating a configuration of a touch module according to a second embodiment of the present invention, and descriptions of the same parts as those of the first embodiment are omitted.

As shown in FIG. 7, the touch module according to the second embodiment of the present invention supplies a touch signal to a touch panel 310 for detecting position information corresponding to a touch point of a user, and a touch signal to the touch panel 310. And a touch driver 320 that receives a detection signal from the touch panel 310.

The touch driver 120 is connected to each of the first to Nth channels CH1 to CHN, which are ends of the plurality of receiving wires 314, and is one of the first to Nth channels CH1 to CHN according to the group selection signal. M first mux (not shown) for selecting the M, M sensing blocks (SB1 to SBM) 340 operating according to the group input signal, and M sensing blocks (SB1 to SBM) 340 is output from M first sample holding amplifiers (SHA1) 350 and M second sample holding amplifiers (SHA2) 355 for holding the detection signal and outputting the same according to the channel output signal, and M first samples according to the channel selection signal. A second mux (360) for selecting one of the sample holding amplifier (SHA1) 350 and an analog-to-digital converter (ADC) for converting an analog signal received from the second mux 360 into a digital signal ( 370, a control logic unit (CG & DCL) 380 for generating a clock and a plurality of control signals used in the touch driver 320, M first mux, and M number Micro control unit (MCU) for controlling the sensing block 340, M first sample holding amplifier 350, M second sample holding amplifier 355, the second mux 360 and the control logic unit 380 390.

Here, the detection signal is input to each of the first to Mth sensing blocks SB1 to SBM by a differential input method, for example, the first and second input terminals of each of the first to Mth sensing blocks SB1 to SBM. Two detection signals of the first to Nth channels CH1 to CHN are input to 342 and 344, respectively.

The detection signals output from the first and second output terminals 352 and 354 of each of the M first sample holding amplifiers SHA1 are sequentially processed by the analog-digital converter 370 through the second mux 360. Is converted to digital and transmitted to the micro control unit 390.

Accordingly, the first to Nth channels CH1 to CHN are divided into first to Kth channel groups CG1 to CGK each including 2M channels (N = 2M XK) (N ≧ 2M), 2M channels (CH1 to CH (2M), CH (2M + 1) to CH (4M), and CH (N-2M + 1) to CHN) belonging to each of the first to Kth channel groups CG1 to CGK It is connected two by M first mux.

The M first mux selects one of the K channel groups CG1 to CGK according to the group selection signal transmitted from the microcontrol unit (MCU) 390. Accordingly, from the 2M channels of the selected channel group, The output 2M detection signals are inputted and integrated into the M sensing blocks SB1 to SBM 340 simultaneously according to the group input signal transmitted from the microcontrol unit (MCU) 390.

In addition, the 2M detection signals integrated in the M sensing blocks SB1 to SBM 140 are transmitted to M pairs of the first and second sample holding amplifiers SHA1 and SHA2 250 and 255, respectively. The value is maintained and output according to the channel output signal transmitted from the microcontrol unit (MCU) 390.

The second mux 360 selects one of M pairs of the first and second sample holding amplifiers SHA1 and SHA2 350 and 355 according to the channel selection signal, and selects the selected first and second sample holding amplifiers SHA1. In addition, one of two detection signals output from the SHA2) 350 and 355 is further selected and transmitted to the analog-to-digital converter 170.

Accordingly, the 2M detection signals output from the M pairs of the first and second sample holding amplifiers SHA1 and SHA2 350 and 355 are sequentially transmitted to the analog-to-digital converter 370 through the second mux 360. do.

In the touch module according to the second exemplary embodiment, by differentially inputting detection signals of two channels corresponding to adjacent receiving wirings 314 into one sensing block 340, offset and noise components having similar values are more efficiently. Can be removed

In addition, since one sensing block 340 integrates detection signals of two channels, the number of necessary sensing blocks 340 may be reduced to reduce manufacturing costs.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It can be understood that

100: display device 110: touch panel
120: touch driver 130: first mux
140: sensing block 150: first sample maintenance amplifier
155: second sample maintenance amplifier 160: the second mux
170: analog-to-digital converter 180: control logic
190: micro control unit 210: display panel
220: display driver

Claims (9)

A first to Nth unit configured to include a plurality of transmission wires to which a driving signal is input, a plurality of reception wires intersecting the plurality of transmission wires, and one end of the plurality of reception wires, and are divided into first to L channel groups. A touch panel including a channel;
First to Mth sensing blocks for simultaneously integrating M detection signals output from each of the first to Lth channel groups according to a group input signal;
M pairs of first and second sample holding amplifiers each of which holds M detection signals output from the first to Mth sensing blocks, and sequentially outputs the M detection signals according to a channel output signal;
An analog-digital converter for sequentially converting the M detection signals output from the M pairs of the first and second sample holding amplifiers from analog to digital;
A micro control unit for controlling the first to Mth sensing blocks and the M pairs of first and second sample holding amplifiers and receiving M detection signals from the analog-digital converter;
Touch module comprising a.
The method of claim 1,
M first muxes which select one of the first to Lth channel groups according to a group selection signal and simultaneously transmit M detection signals to the first to Mth sensing blocks;
A second mux for sequentially selecting the M pairs of the first and second sample holding amplifiers according to a channel selection signal and sequentially transmitting the M detected signals to the analog-digital converter;
The control logic unit generates and provides the group input signal, the channel output signal, the group selection signal, and the channel selection signal.
Touch module further comprising.
The method of claim 1,
Each of the first to Mth sensing blocks includes first and second input terminals, and the detection signal and the reference voltage of one of the first to Nth channels are respectively input to the first and second input terminals. And a touch module to which the detection signals of two of the first to Nth channels are input.
A first to Nth unit configured to include a plurality of transmission wires to which a driving signal is input, a plurality of reception wires intersecting the plurality of transmission wires, and one end of the plurality of reception wires, and are divided into first to L channel groups. A touch panel including a channel;
First to Mth sensing blocks for simultaneously integrating M detection signals output from each of the first to Lth channel groups according to a group input signal;
M pairs of first and second sample holding amplifiers each of which holds M detection signals output from the first to Mth sensing blocks, and sequentially outputs the M detection signals according to a channel output signal;
An analog-digital converter for sequentially converting the M detection signals output from the M pairs of the first and second sample holding amplifiers from analog to digital;
A micro control unit for controlling the first to Mth sensing blocks and the M pairs of first and second sample holding amplifiers and receiving M detection signals from the analog-digital converter;
A display panel disposed under the touch panel to display an image;
A display driver for supplying an image signal and a control signal to the display panel
Display device comprising a touch module comprising a.
Simultaneously integrating M detection signals output from each of the first to Lth channel groups of the first to Nth channels of the touch panel according to the group input signal;
Maintaining M detected signals output from the first to Mth sensing blocks, and sequentially outputting the M pairs of first and second sample holding amplifiers according to channel output signals;
Analog-to-digital converter sequentially converts the M detected signals output from the M pairs of the first and second sample holding amplifiers from analog to digital and transfers them to a micro control unit;
Method of driving a touch module comprising a.
The method of claim 5, wherein
M first mux selecting one of the first to Lth channel groups according to a group selection signal and simultaneously transmitting M detection signals to the first to Mth sensing blocks;
A second mux sequentially selecting the M pairs of the first and second sample holding amplifiers according to a channel selection signal and sequentially transmitting the M detected signals to the analog-digital converter;
Driving method of the touch module further comprises.
The method of claim 5, wherein
Each of the first to Mth sensing blocks includes first and second input terminals, and the detection signal and the reference voltage of one of the first to Nth channels are respectively input to the first and second input terminals. And driving the detection signals of two of the first to Nth channels, respectively.
Supplying an image signal and a control signal by the display driver;
Displaying, by the display panel, an image using the image signal and the control signal;
Simultaneously integrating M detection signals output from each of the first to Lth channel groups of the first to Nth channels of the touch panel on the display panel according to the group input signal. Wow;
Maintaining M detected signals output from the first to Mth sensing blocks, and sequentially outputting the M pairs of first and second sample holding amplifiers according to channel output signals;
Analog-to-digital converter sequentially converts the M detected signals outputted from the M pairs of the first and second sample holding amplifiers from analog to digital and transfers them to a micro control unit;
Method of driving a display device comprising a touch module comprising a.
The method of claim 8,
Analyzing location information of the touch point by analyzing the detection signal;
Recognizing a command by comparing the location information of the touch point and the location information of the image
Method of driving a display device including a touch module further comprising.

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