KR102553515B1 - Touch system, touch circuit, and touch sensing method - Google Patents

Abstract

The present invention relates to a touch display device, a touch system, a touch circuit, and a touch sensing method, and more particularly, touch driving is performed using touch driving signals having various frequencies, and in some cases, touch driving of the same frequency Signals relate to a touch display device, a touch system, a touch circuit, and a touch sensing method that are distinguished from each other through a code division method. According to the present invention, more rapid touch sensing and touch sensing robust against noise are possible, and a plurality of touch lines or a plurality of touch electrodes can be simultaneously driven.

Description

Touch display device, touch system, touch circuit and touch sensing method {TOUCH SYSTEM, TOUCH CIRCUIT, AND TOUCH SENSING METHOD}

The present invention relates to a touch display device, a touch system, a touch circuit, and a touch sensing method.

A touch display device may provide a touch-based input function allowing a user to intuitively and conveniently input information or commands in addition to a function of displaying a video or image.

In order to provide a touch-based input function, such a touch display device must be capable of detecting the presence or absence of a user's touch and accurately sensing touch coordinates. To this end, the touch display device includes a touch panel and a touch circuit for sensing the touch panel.

The touch circuit can sense a touch by supplying a touch driving signal to the touch panel and checking a change in electrical characteristics (eg, capacitance, etc.) of the touch panel in order to sense the touch panel.

Conventionally, since a touch circuit must sequentially supply touch driving signals to a plurality of touch lines (a plurality of touch electrodes) disposed on a touch panel and sequentially sense a plurality of touch lines (a plurality of touch electrodes), all touch lines There has been a problem that it takes too much time to drive and sense.

In addition, conventionally, when a touch driving signal having a predetermined fixed frequency is sequentially applied to a plurality of touch lines (a plurality of touch electrodes) disposed on a touch panel, other patterns or electrodes around the touch line (surrounding touch lines) Including), there has been a problem that noise is generated and touch sensitivity is lowered.

Against this background, an object of embodiments of the present invention is to provide a touch display device, a touch system, a touch circuit, and a touch sensing method capable of sensing a touch more rapidly.

Another object of the embodiments of the present invention is to provide a touch display device robust against noise, a touch system, a touch circuit, and a touch sensing method.

Another object of the embodiments of the present invention is to provide a touch display device, a touch system, a touch circuit, and a touch sensing method capable of simultaneously driving a plurality of touch lines or a plurality of touch electrodes disposed on a touch panel.

Another object of the embodiments of the present invention is to provide a touch display device, a touch system, a touch circuit, and a touch sensing method capable of both mutual capacitance-based touch sensing and self-capacitance-based touch sensing.

Another object of the embodiments of the present invention is to provide a touch display device, a touch system, a touch circuit, and a touch sensing method that enable touch sensing suitable for various situations by allowing various sensing modes to be set.

In one aspect, embodiments of the present invention may provide a touch system including a touch panel on which a plurality of driving touch lines are disposed, and a touch circuit for driving the plurality of driving touch lines.

The plurality of driving touch lines include a first driving touch line group including a 1 th driving touch line to a k th driving touch line, and a th driving touch line group including a (k+1) th driving touch line to a (2k) th driving touch line. It may include 2 driving touch line groups. k may be a natural number of 2 or greater.

The touch circuit may supply touch driving signals of a first frequency to the first driving touch line group, and supply touch driving signals of a second frequency different from the first frequency to a second driving touch line group.

Touch driving signals of the first frequency supplied to the 1 th driving touch line to the k th driving touch line included in the first driving touch line group may be distinguished from each other according to a phase or code. Touch driving signals of the second frequency supplied to the (k+1) th driving touch line to the (2k) th driving touch line included in the second driving touch line group may be distinguished from each other according to a phase or code.

The touch driving signals of the first frequency supplied to the first driving touch line group may be sinusoidal signals of the first frequency, and the touch driving signals of the second frequency supplied to the second driving touch line group may be sinusoidal signals of the second frequency. .

A touch driving signal of a first frequency supplied to one of the 1st driving touch line to the k th driving touch line included in the first driving touch line group, and the (k+1) th driving signal included in the second driving touch line group The phases or codes of the touch driving signals of the second frequency supplied to one of the touch lines to the (2k)th driving touch lines may correspond to each other.

The touch driving signals of the first frequency supplied to the 1st driving touch line to the k th driving touch line included in the first driving touch line group have phases corresponding to the k codes distinguished from each other or k codes distinguished from each other. It may have a phase pattern corresponding to the column.

The touch driving signals of the second frequency supplied to the (k+1) th driving touch line to the (2k) th driving touch line included in the second driving touch line group have phases corresponding to the k codes that are distinguished from each other or are different from each other. It may have a phase pattern corresponding to the distinct k types of code strings.

The k codes or k code sequences indicated by the touch driving signals of the first frequency and the k codes or k code sequences indicated by the touch driving signals of the second frequency may correspond to each other. there is.

The touch driving signals of the first frequency supplied to the first driving touch line group may have k first signal waveforms. The touch driving signals of the second frequency supplied to the second driving touch line group may have k second signal waveforms. Phase patterns of the k first signal waveforms may correspond to phase patterns of the k second signal waveforms.

A plurality of sensing touch lines crossing the plurality of driving touch lines may be further disposed on the touch panel.

The touch circuit may include a first touch circuit electrically connected to a plurality of driving touch lines and a second touch circuit electrically connected to a plurality of sensing touch lines.

The second touch circuit includes a plurality of preamplifiers corresponding to a plurality of sensing touch lines, a plurality of analog-to-digital converters corresponding to and electrically connected to the plurality of preamplifiers, and a plurality of frequency analyzers electrically connected to the plurality of analog-to-digital converters. can include

Each of the plurality of preamplifiers may include a first input terminal receiving an input signal, a second input terminal electrically connected to a corresponding sensing touch line, and an output terminal electrically connected to a corresponding analog-to-digital converter.

Based on the frequency analysis result data output from each of the plurality of frequency analyzers and the phase information or code information that distinguishes touch driving signals having a first frequency from each other or touch driving signals having a second frequency from each other, a touch is detected. A sensing touch controller may be further included.

The input signal may be a DC voltage. The DC voltage may be a voltage lower than the operating voltage of the touch circuit.

The input signal may be a sine wave signal. The input signal may be a sine wave signal having a third frequency different from frequencies of touch driving signals supplied to the plurality of driving touch lines.

The first touch circuit may include a plurality of driving amplifiers outputting touch driving signals to a plurality of driving touch lines.

A time required to determine whether there is a touch or touch coordinates in all areas of the touch panel may be in inverse proportion to a frequency difference between the first frequency and the second frequency.

On the other hand, embodiments of the present invention include a first touch circuit electrically connected to a plurality of driving touch lines disposed on a touch panel, a plurality of sensing touch lines disposed on a touch panel and intersecting the plurality of driving touch lines, A touch circuit including an electrically connected second touch circuit may be provided.

The plurality of driving touch lines include a first driving touch line group including a 1 th driving touch line to a k th driving touch line, and a th driving touch line group including a (k+1) th driving touch line to a (2k) th driving touch line. It may include 2 driving touch line groups. k may be a natural number of 2 or greater.

The first touch circuit may supply touch driving signals of a first frequency to the first driving touch line group, and supply touch driving signals of a second frequency different from the first frequency to a second driving touch line group.

Touch driving signals of the first frequency supplied to each of the 1st driving touch line to the k th driving touch line included in the first driving touch line group may be distinguished from each other according to a phase or code. Touch driving signals of the second frequency supplied to each of the (k+1) th driving touch line to the (2k) th driving touch line included in the second driving touch line group may be distinguished from each other according to a phase or code.

The second touch circuit includes a plurality of preamplifiers corresponding to a plurality of sensing touch lines, a plurality of analog-to-digital converters corresponding to and electrically connected to the plurality of preamplifiers, and a plurality of frequency analyzers electrically connected to the plurality of analog-to-digital converters. can include

Each of the plurality of preamplifiers may include a first input terminal receiving an input signal, a second input terminal electrically connected to a corresponding sensing touch line, and an output terminal electrically connected to a corresponding analog-to-digital converter.

Based on the frequency analysis result data output from each of the plurality of frequency analyzers and the phase information or code information that distinguishes touch driving signals having a first frequency from each other or touch driving signals having a second frequency from each other, a touch is detected. A sensing touch controller may be further included.

The first touch circuit may include a plurality of driving amplifiers that output touch driving signals to a plurality of driving touch lines.

The first touch circuit includes a plurality of preamplifiers corresponding to a plurality of driving amplifiers, a plurality of analog-to-digital converters corresponding to and electrically connected to the plurality of preamplifiers, and a plurality of frequency frequencies corresponding to and electrically connected to the plurality of analog-to-digital converters. It may further include an analyzer.

Each of the plurality of preamplifiers in the first touch circuit includes a first input terminal receiving an input signal, a second input terminal electrically connected to the driving output terminal of the corresponding driving amplifier, and an output terminal electrically connected to the corresponding analog-to-digital converter. can include

Based on the frequency analysis result data output from each of the plurality of frequency analyzers and the phase information or code information that distinguishes touch driving signals having a first frequency from each other or touch driving signals having a second frequency from each other, a touch is detected. A sensing touch controller may be further included.

In another aspect, embodiments of the present invention may provide a touch display device including a touch panel on which a plurality of touch electrodes are disposed and a touch circuit for supplying a touch driving signal to all or part of the plurality of touch electrodes. .

The plurality of touch electrodes may include a first touch electrode group including k touch electrodes and a second touch electrode group including k different touch electrodes. k may be a natural number of 2 or greater.

The touch circuit may supply touch driving signals of a first frequency to the first touch electrode group, and supply touch driving signals of a second frequency different from the first frequency to the second touch electrode group.

The touch driving signals of the first frequency supplied to the k touch electrodes in the first touch electrode group may be distinguished from each other by phase or code.

The touch driving signals of the second frequency supplied to k touch electrodes in the second touch electrode group may be distinguished from each other by phase or code.

In another aspect, embodiments of the present invention provide a step of supplying a touch driving signal to all or part of a plurality of driving touch lines disposed on a touch panel, and all or part of a plurality of sensing touch lines disposed on a touch panel. It is possible to provide a touch sensing method including the step of sensing a touch through the.

The plurality of driving touch lines may include a first driving touch line group including k driving touch lines and a second driving touch line group including another k driving touch lines. k may be a natural number of 2 or greater.

Touch driving signals supplied to the first driving touch line group and touch driving signals supplied to the second driving touch line group may be distinguished from each other by frequency.

Touch driving signals supplied to the first driving touch line group may be distinguished from each other by phase or code. Touch driving signals supplied to the second driving touch line group may be distinguished from each other by phase or code.

The touch sensing method may further include supplying other touch driving signals to all or part of the plurality of sensing touch lines before the sensing step.

Touch driving signals supplied to the first driving touch line group have a first frequency, touch driving signals supplied to the second driving touch line group have a second frequency different from the first frequency, and Alternatively, other touch driving signals that are partially supplied may have a third frequency different from the first and second frequencies.

According to the embodiments of the present invention described above, there is an effect of providing a touch display device, a touch system, a touch circuit, and a touch sensing method capable of sensing a touch more rapidly.

According to the embodiments of the present invention, there is an effect of providing a touch display device robust against noise, a touch system, a touch circuit, and a touch sensing method.

According to embodiments of the present invention, there is an effect of providing a touch display device, a touch system, a touch circuit, and a touch sensing method capable of simultaneously driving a plurality of touch lines or a plurality of touch electrodes disposed on a touch panel.

According to embodiments of the present invention, there is an effect of providing a touch display device, a touch system, a touch circuit, and a touch sensing method capable of both touch sensing based on mutual capacitance and touch sensing based on self capacitance.

According to the embodiments of the present invention, there is an effect of providing a touch display device, a touch system, a touch circuit, and a touch sensing method that enable touch sensing suitable for various situations by allowing various sensing modes to be set.

1 is a system configuration diagram of a touch display device according to embodiments of the present invention.
2 is a schematic configuration diagram of a touch system according to embodiments of the present invention.
3 is a diagram illustrating a first touch circuit and a second touch circuit within a touch circuit of a touch system according to embodiments of the present invention.
4 is an exemplary diagram of a first sensing and driving unit included in a first touch circuit within a touch circuit of a touch system according to embodiments of the present invention.
5 is an exemplary diagram of a second sensing and driving unit included in a second touch circuit within a touch circuit of a touch system according to embodiments of the present invention.
6 is a diagram illustrating multi-frequency driving using code division in a touch system according to embodiments of the present invention.
7 is a diagram exemplarily illustrating multi-frequency driving using code division in a touch system according to embodiments of the present invention.
8 is an exemplary diagram of a touch driving signal for multi-frequency driving using code division in a touch system according to embodiments of the present invention.
9 and 10 are other exemplary diagrams of touch driving signals for multi-frequency driving using code division in a touch system according to embodiments of the present invention.
11 to 15 are diagrams for explaining a touch sensing method using multi-frequency driving using code division in a touch system according to embodiments of the present invention.
16 is a diagram illustrating multi-frequency driving in a touch system according to embodiments of the present invention.
17 is a diagram illustrating a method of simultaneously sensing self-capacitance and mutual capacitance through multi-frequency driving in a touch system according to embodiments of the present invention.
18 is a diagram showing a circuit for inputting an input signal to a first input terminal of a preamplifier in a touch system according to embodiments of the present invention.
19 is another exemplary view of a first sensing and driving unit included in a first touch circuit within a touch circuit of a touch system according to embodiments of the present invention.
20 is another exemplary diagram of a second sensing and driving unit included in a second touch circuit within a touch circuit of a touch system according to embodiments of the present invention.
21 is a diagram illustrating first sensing drive units electrically connected to driving touch lines and second sensing drive units electrically connected to sensing touch lines in a touch system according to embodiments of the present invention.
22 to 25 are for explaining various operation cases and various sensing modes using the first sensing drive unit of FIG. 19 and the second sensing drive unit of FIG. 20 in a touch system according to embodiments of the present invention. they are drawings
26 is a flowchart of a touch sensing method of a touch system according to embodiments of the present invention.
27 is an exemplary view of a touch panel according to embodiments of the present invention.
28 is another exemplary view of a touch panel according to embodiments of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Some embodiments of the present invention are described in detail below with reference to exemplary drawings. In adding reference numerals to components of each drawing, the same components may have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description may be omitted.

Also, terms such as first, second, A, B, (a), and (b) may be used in describing the components of the present invention. These terms are only used to distinguish the component from other components, and the nature, sequence, order, or number of the corresponding component is not limited by the term. When an element is described as being “connected,” “coupled to,” or “connected” to another element, that element is or may be directly connected to that other element, but intervenes between each element. It will be understood that may be "interposed", or each component may be "connected", "coupled" or "connected" through other components.

1 is a system configuration diagram of a touch display device according to embodiments of the present invention.

Referring to FIG. 1 , a touch display device according to embodiments of the present invention may provide a display function of displaying an image. In addition, the touch display device according to embodiments of the present invention may provide a touch sensing function for sensing a user's touch and a touch input function for performing input processing according to a user's touch using a touch sensing result. .

Below, components for providing a display function and components for providing a touch sensing function will be described.

Referring to FIG. 1 , a touch display device according to embodiments of the present invention may include a plurality of data lines and a plurality of gate lines in order to provide a display function, and a plurality of data lines and a plurality of gate lines. A display panel (DISP) in which a plurality of subpixels defined by is arranged, a data driving circuit (DDC) driving a plurality of data lines, a gate driving circuit (GDC) driving a plurality of gate lines, and a data driving circuit A display controller (DCTR) controlling the low DDC and the gate driving circuit (GDC) may be included.

The display controller DCTR controls the data driving circuit DDC and the gate driving circuit GDC by supplying various control signals to the data driving circuit DDC and the gate driving circuit GDC.

The display controller (DCTR) starts scanning according to the timing implemented in each frame, converts the input image data input from the outside to suit the data signal format used in the data driving circuit (DDC), and outputs the converted image data. and control data driving at an appropriate time according to the scan.

The gate driving circuit GDC sequentially supplies scan signals of an on voltage or an off voltage to the plurality of gate lines GL under the control of the display controller DCTR.

When a specific gate line is opened by the gate driving circuit (GDC), the data driving circuit (DDC) converts the image data received from the display controller (DCTR) into an analog data voltage and supplies it to a plurality of data lines (DL). do.

The display controller (DCTR) may be a timing controller used in normal display technology or a control device that performs other control functions including the timing controller, and may be a control device different from the timing controller. may be

The display controller DCTR may be implemented as a separate component from the data driving circuit DDC, or may be implemented as an integrated circuit together with the data driving circuit DDC.

The data driving circuit DDC drives the plurality of data lines DL by supplying data voltages to the plurality of data lines DL. Here, the data driving circuit (DDC) is also referred to as a 'source driver'.

The data driving circuit (DDC) may include at least one source driver integrated circuit (SDIC). Each source driver integrated circuit (SDIC) may include a shift register, a latch circuit, a digital to analog converter (DAC), an output buffer, and the like. In some cases, each source driver integrated circuit (SDIC) may further include an analog to digital converter (ADC).

Each source driver integrated circuit (SDIC) is connected to the bonding pad of the display panel (DISP) by a tape automated bonding (TAB) method or a chip on glass (COG) method. , may be directly disposed on the display panel DISP, or may be integrated and disposed on the display panel DISP in some cases. In addition, each source driver integrated circuit (SDIC) may be implemented in a Chip On Film (COF) method mounted on a film connected to a display panel (DISP).

The gate driving circuit GDC sequentially drives the plurality of gate lines GL by sequentially supplying scan signals to the plurality of gate lines GL. Here, the gate driving circuit (GDC) is also referred to as a 'scan driver'.

The gate driving circuit (GDC) may include at least one gate driver integrated circuit (GDIC). Each gate driver integrated circuit (GDIC) may include a shift register, a level shifter, and the like.

Each gate driver integrated circuit (GDIC) is connected to the bonding pad of the display panel (DISP) by a tape automated bonding (TAB) method or a chip on glass (COG) method, or a GIP (Gate In Panel) type , and may be directly disposed on the display panel DISP, or may be integrated and disposed on the display panel DISP in some cases. In addition, each gate driver integrated circuit (GDIC) may be implemented in a chip on film (COF) method mounted on a film connected to the display panel (DISP).

As shown in FIG. 1, the data driving circuit DDC may be located only on one side (eg, upper or lower side) of the display panel DISP, and in some cases, the display panel ( DISP) may be located on both sides (eg, upper and lower sides).

As shown in FIG. 1, the gate driving circuit GDC may be located on only one side (eg, the left or right side) of the display panel DISP, and in some cases, depending on the driving method, panel design method, etc., the display panel It may be located on both sides (eg, left and right) of (DISP).

The touch display device according to the present embodiments may be various types of display devices such as a liquid crystal display device and an organic light emitting display device. The display panel DISP according to the present exemplary embodiments may also be various types of display panels such as a liquid crystal display panel and an organic light emitting display panel.

Each subpixel disposed on the display panel DISP may include one or more circuit elements, and the type and number of circuit elements may be variously determined according to a panel type, provided function, and design method.

Referring to FIG. 1 , a touch display device according to embodiments of the present invention includes a touch panel (TSP) and a touch circuit (TC) for driving and sensing the touch panel (TSP) to provide a touch sensing function. , a touch controller TCTR that senses a touch by using a result of the touch circuit TC sensing the touch panel TSP, and the like.

A touch by a user's pointer may contact or approach the touch panel TSP. Touch sensors may be disposed on the touch panel TSP. Here, the user's pointer may be a finger or a pen. The pen may be a passive pen without a signal transmission/reception function or an active pen with a signal transmission/reception function. The touch circuit TC may supply a touch driving signal to the touch panel TSP and sense the touch panel TSP. The touch controller TCTR may sense a touch by using a result of the touch circuit TC sensing the touch panel TSP. Here, sensing a touch may mean determining whether there is a touch and/or touch coordinates.

The touch panel TSP may be an external type disposed outside the display panel DISP or an internal type disposed inside the display panel DISP.

When the touch panel TSP is an external type, the touch panel TSP and the display panel DISP may be manufactured separately and then bonded to each other using an adhesive or the like. An external touch panel (TSP) is also called an add-on type.

When the touch panel TSP is a built-in type, the touch panel TSP may be manufactured together during a process of manufacturing the display panel DISP. That is, touch sensors constituting the touch panel TSP may be disposed inside the display panel DISP. The embedded touch panel (TSP) may be an in-cell type, an on-cell type, or a hybrid type.

The touch controller TCTR may be implemented as, for example, a micro control unit (MCU), a processor, or the like.

The display controller DCTR and the touch controller TCTR may be implemented separately or integrated.

2 is a schematic configuration diagram of a touch system according to embodiments of the present invention.

Referring to FIG. 2 , a touch system according to embodiments of the present invention includes a touch panel (TSP), a touch circuit (TC) that drives and senses the touch panel (TSP), and the touch circuit (TC) is a touch panel. A touch controller (TCTR) that senses a touch using a result of sensing (TSP) may be included.

A plurality of touch lines may be disposed on the touch panel TSP. A plurality of touch lines correspond to touch sensors.

The plurality of touch lines may include a plurality of first touch lines disposed in a first direction and a plurality of second touch lines disposed in a second direction different from the first direction.

Here, the first touch line and the second touch line are only distinguished in terms of arrangement, and may not be distinguished in function or role.

The plurality of first touch lines and the plurality of second touch lines may be disposed in different directions and cross each other. For example, as shown in FIG. 2 , each of a plurality of first touch lines may be disposed in a row direction, and each of a plurality of second touch lines may be disposed in a column direction. Alternatively, each of the plurality of first touch lines may be disposed in a column direction, and each of the plurality of second touch lines may be disposed in a row direction.

The touch circuit TC may include a first touch circuit TC1 electrically connected to a plurality of first touch lines, a second touch circuit TC2 electrically connected to a plurality of second touch lines, and the like.

Each of the first touch line and the second touch line may be one touch electrode in the form of a line or a bar. Alternatively, each of the first touch line and the second touch line may include several touch electrodes electrically connected to each other.

The first touch line and the second touch line may be located on different layers or may be located on the same layer.

One or more touch electrodes constituting each of the first touch line and the second touch line may be plate-shaped electrodes without open areas or mesh-shaped electrodes with open areas. Here, each of the open areas existing in one touch electrode may correspond to one or more subpixels or their light emitting areas.

Below, for convenience of explanation, the first touch line may be described as a driving touch line DTL, and the second touch line may be described as a sensing touch line STL. Here, the driving touch line DTL and the sensing touch line STL are only distinguished in terms of arrangement, and may not be distinguished in terms of functions or roles.

3 is a diagram illustrating a first touch circuit TC1 and a second touch circuit TC2 within the touch circuit TC of the touch system according to example embodiments.

Referring to FIG. 3 , the plurality of driving touch lines DTL and the plurality of sensing touch lines STL disposed on the touch panel TSP may cross each other.

Referring to FIG. 3 , the touch circuit TC includes a plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...) disposed on the touch panel TSP. Electrically connected first touch circuit TC1 and a plurality of sensing touch lines (STL(1), STL(2), STL(3), STL(4), ...) disposed on the touch panel TSP It may include a second touch circuit TC2 connected to .

A touch system according to embodiments of the present invention may sense a touch based on mutual capacitance, may sense a touch based on self-capacitance, or may sense a touch based on both mutual capacitance and self-capacitance. there is.

If the touch system according to embodiments of the present invention senses a touch based on mutual capacitance, one of the first touch circuit TC1 and the second touch circuit TC2 is a driving circuit, and the other one is a sensing circuit. may be a circuit.

Accordingly, the touch system according to the embodiments of the present invention can provide various operation cases and various sensing modes. Below, five cases are described.

Case 1 is a case of operating in the mutual capacitance sensing mode, the first touch circuit TC1 operates as a driving circuit for mutual capacitance sensing, and the second touch circuit TC2 operates as a sensing circuit for mutual capacitance sensing. It is a case of

In this case, the first touch circuit TC1 may drive all or part of the plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...). The second touch circuit TC2 may sense all or part of the plurality of sensing touch lines (STL(1), STL(2), STL(3), STL(4), ...).

That is, the first touch circuit TC1 simultaneously or sequentially applies touch driving signals to all or part of the plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...). can supply The second touch circuit TC2 simultaneously or sequentially detects touch sensing signals from all or some of the plurality of sensing touch lines (STL(1), STL(2), STL(3), STL(4), ...) can do.

Here, the touch sensing signal may be a signal reflecting mutual capacitance between the corresponding sensing touch line STL and the corresponding driving touch line DTL.

Case 2 is a case of operating in the mutual capacitance sensing mode, in which the first touch circuit TC1 operates as a sensing circuit for mutual capacitance sensing and the second touch circuit TC2 operates as a driving circuit for mutual capacitance sensing. is the case

The second touch circuit TC2 may drive all or part of the plurality of sensing touch lines (STL(1), STL(2), STL(3), STL(4), ...). The first touch circuit TC1 may sense all or part of the plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...).

That is, the second touch circuit TC2 simultaneously or sequentially applies the touch driving signal to all or part of the plurality of sensing touch lines (STL(1), STL(2), STL(3), STL(4), ...). can supply The first touch circuit TC1 simultaneously or sequentially detects touch sensing signals from all or part of a plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...) can do.

Here, the touch sensing signal may be a signal reflecting mutual capacitance between the corresponding driving touch line DTL and the corresponding sensing touch line STL.

Case 3 is a case of operating in a mixed sensing mode (mutual capacitance sensing mode, self-capacitance sensing mode), the first touch circuit TC1 operates as a driving circuit for mutual capacitance sensing, and the second touch circuit TC2 operates as a driving circuit for mutual capacitance sensing. This is a case of operating as a sensing circuit for mutual capacitance sensing, and a case where the second touch circuit TC2 also operates as a driving circuit and sensing circuit for self-capacitance sensing.

In this case, the first touch circuit TC1 may drive all or part of the plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...). The second touch circuit TC2 may drive and sense all or part of the plurality of sensing touch lines (STL(1), STL(2), STL(3), STL(4), ...).

That is, the first touch circuit TC1 uses all or part of the plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...) to sense the touch driving signal (mutual capacitance). touch driving signal) can be supplied simultaneously or sequentially. The second touch circuit TC2 is all or part of a plurality of sensing touch lines (STL(1), STL(2), STL(3), STL(4), ...), and the touch driving signal (for sensing self-capacitance) touch driving signal) can be supplied simultaneously or sequentially.

The second touch circuit TC2 simultaneously or sequentially detects touch sensing signals from all or some of the plurality of sensing touch lines (STL(1), STL(2), STL(3), STL(4), ...) can do.

Here, the touch sensing signal may be a signal that reflects both mutual capacitance between the corresponding sensing touch line STL and the corresponding driving touch line DTL and self capacitance of the corresponding sensing touch line STL. .

Case 4 is a case of operating in a mixed sensing mode (mutual capacitance sensing mode, self-capacitance sensing mode), the second touch circuit TC2 operates as a driving circuit for mutual capacitance sensing, and the first touch circuit TC1 operates as a driving circuit for mutual capacitance sensing. This is a case of operating as a sensing circuit for mutual capacitance sensing, and a case where the first touch circuit TC1 also operates as a driving circuit and a sensing circuit for self-capacitance sensing.

In this case, the second touch circuit TC2 may drive all or part of the plurality of sensing touch lines STL(1), STL(2), STL(3), STL(4), .... The first touch circuit TC1 may drive and sense all or part of the plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...).

That is, the second touch circuit TC2 senses the touch driving signal (mutual capacitance) with all or part of the plurality of sensing touch lines (STL(1), STL(2), STL(3), STL(4), ...) touch driving signal) can be supplied simultaneously or sequentially. The first touch circuit TC1 is all or part of a plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...), and includes a touch driving signal (for sensing self-capacitance). touch driving signal) can be supplied simultaneously or sequentially.

The first touch circuit TC1 simultaneously or sequentially detects touch sensing signals from all or part of a plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...) can do.

Here, the touch sensing signal may be a signal that reflects both mutual capacitance between the corresponding driving touch line DTL and the corresponding sensing touch line STL and self capacitance of the corresponding driving touch line DTL. .

Case 5 is a case of operating in the self-sensing mode, the first touch circuit TC1 operates as a driving circuit and a sensing circuit for self-capacitance sensing, and the second touch circuit TC2 also operates as a driving circuit and a sensing circuit for self-capacitance sensing. This is the case of operating as a sensing circuit.

The first touch circuit TC1 supplies a touch driving signal to all or part of a plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...) and provides a plurality of driving touch lines. Touch sensing signals may be simultaneously or sequentially detected from all or part of the lines (DTL(1), DTL(2), DTL(3), DTL(4), ...).

Here, the touch sensing signal may be a signal reflecting self capacitance of the corresponding driving touch line DTL.

Similarly, the second touch circuit TC2 supplies touch driving signals to all or part of the plurality of sensing touch lines (STL(1), STL(2), STL(3), STL(4), ...) and Touch sensing signals may be simultaneously or sequentially detected from all or part of the sensing touch lines (STL(1), STL(2), STL(3), STL(4), ...) of

Here, the touch sensing signal may be a signal reflecting self capacitance of the corresponding sensing touch line STL.

Referring to FIG. 3 , the first touch circuit TC1 is electrically connected to a plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...). A sensing drive unit (SDU_D) may be included. The second touch circuit TC2 includes a plurality of second sensing drive units SDU_S electrically connected to a plurality of sensing touch lines STL(1), STL(2), STL(3), STL(4), ... can include

Each operation of the first sensing and driving unit SDU_D and the second sensing and driving unit SDU_S may vary depending on which of the five cases the touch system according to embodiments of the present invention operates in.

In addition, the internal configuration of each of the first sensing and driving unit SDU_D and the second sensing and driving unit SDU_S varies depending on which of the five cases the touch system according to the embodiments of the present invention can operate in. can

Hereinafter, a touch system, a touch circuit (TC), and a touch sensing method for Cases 1 and 3 among the above-described five cases will be described in more detail. Cases 2 and 4 are the same as Cases 1 and 3 except that the roles of the first touch circuit TC1 and the second touch circuit TC2 are opposite to each other.

4 is an exemplary diagram of a first sensing and driving unit SDU_D included in a first touch circuit TC1 within a touch circuit TC of a touch system according to embodiments of the present invention.

Referring to FIG. 4 , the first touch circuit TC1 may include a plurality of driving amplifiers DR-AMP that output touch driving signals to the plurality of driving touch lines DTL. That is, each of the plurality of first sensing and driving units SDU_D in the first touch circuit TC1 may include a driving amplifier DR-AMP.

The driving amplifier DR-AMP may include an input terminal mi through which the touch driving signal TDS is input and an output terminal mo through which the amplified touch driving signal TDS is output.

The driving amplifier DR-AMP may output the touch driving signal TDS of large amplitude, and through this, more effective driving of the driving touch line DTL may be possible.

5 is an exemplary diagram of a second sensing and driving unit SDU_S included in a second touch circuit TC2 within the touch circuit TC of a touch system according to embodiments of the present invention.

The second touch circuit TC2 includes a plurality of preamplifiers PRE-AMPs corresponding to a plurality of sensing touch lines STL and a plurality of analog and digital analog and digital signals corresponding to and electrically connected to the plurality of preamplifiers PRE-AMPs. It may include a converter (ADC) and a plurality of frequency analyzers (FRA) electrically connected to the plurality of analog-to-digital converters (ADC).

That is, each of the plurality of second sensing and driving units SDU_S in the second touch circuit TC2 may include a pre-amplifier PRE-AMP, an analog-to-digital converter ADC, and a frequency analyzer FRA.

Each of the plurality of preamplifiers (PRE-AMP) has a first input terminal (Ni1) receiving the input signal (INS), a second input terminal (Ni2) electrically connected to the corresponding sensing touch line (STL), and a corresponding It may include an output terminal (No) electrically connected to an analog-to-digital converter (ADC).

The frequency analyzer FRA included in each second sensing drive unit SDU_S performs frequency analysis using a Fourier transform such as, for example, Fast Fourier Transform (FFT). In addition, Sonogram, which is a two-dimensional image calculated and constructed by Fourier spectrum transform, Wigner Transform, Continuous Wavelet Transform (CWT), Discrete Wavelet Transform (DWT) Transform), etc.

Below, for convenience of description, it is assumed that the frequency analyzer (FRA) uses FFT.

Meanwhile, the touch system according to embodiments of the present invention may use touch driving signals TDS having various frequencies instead of using a touch driving signal TDS having one fixed frequency. That is, the touch system according to the embodiments of the present invention can provide multi-frequency driving.

The touch system according to the embodiments of the present invention provides multi-frequency driving (MFD), so it can perform touch driving and touch sensing faster, and can be less affected by unnecessary noise during touch sensing. there is. In addition, there is an advantage in that a plurality of driving touch lines DTL can be simultaneously driven.

For multi-frequency driving (MFD), several frequencies must be densely used, which increases the complexity of frequency analysis by the frequency analyzer (FRA).

In order to reduce the disadvantages of the multi-frequency driving (MFD) while taking advantage of the advantages of the multi-frequency driving (MFD), the touch system according to the embodiments of the present invention is a multi-frequency driving (MFD) using code division can be performed.

Multi-frequency driving (MFD) using code division is a driving method in which touch driving signals (TDS) of different frequencies are used, but the touch driving signals (TDS) of the same frequency have different codes or code sequences. That is, multi-frequency driving (MFD) using code division is a driving method in which both frequency division and code division of the touch driving signal TDS are used. Here, a code represents a phase, and a code string represents a phase pattern.

The first touch circuit TC1 binds (groups) k driving touch lines DTL (for example, k = 2, 4, 8, 12, ...) and drives them with the touch driving signal TDS of the same frequency. However, the k driving touch lines DTL bundled together may be driven with touch driving signals TDS having different phases.

Here, different phases or phase patterns of the touch driving signals TDS of the same frequency may be expressed as different codes or code sequences. These different codes or code columns may constitute an encoding matrix.

Accordingly, the second touch circuit TC2 of the touch system according to the embodiments of the present invention provides k (eg, k = 2, 4, 8, 12) with respect to the touch sensing signal received from the sensing touch lines STL , …) times of FFT are performed.

The second touch circuit TC2 or the touch controller TCTR may perform matrix multiplication operation processing on k FFT results and a decoding matrix. The touch controller TCTR may determine whether there is a touch and/or touch coordinates based on a result of performing a matrix multiplication operation process.

In the case of using the above-described multi-frequency driving (MFD) using code division, it is possible to reduce the number of types (number) of frequencies, so that the frequency analyzer (FRA) does not have to perform a high-complexity FFT.

In the following, multi-frequency driving (MFD) using code division will be described in more detail.

6 is a diagram illustrating multi-frequency driving (MFD) using code division in a touch system according to embodiments of the present invention.

Referring to FIG. 6 , the plurality of driving touch lines DTL disposed on the touch panel TSP includes a first driving touch line DTL( 1 ) to a k th driving touch line DTL(k). Second driving touch lines including a first driving touch line group GR1 and (k+1)th driving touch lines DTL(k+1) to (2k)th driving touch lines DTL(2k) A group GR2 may be included. Here, k is a natural number greater than or equal to 2.

In FIG. 6 , only two driving touch line groups GR1 and GR2 are illustrated, but this is only for convenience of explanation, and a larger number of driving touch line groups may exist.

The first touch circuit TC1 in the touch circuit TC is a first driving touch line group GR1 and generates touch driving signals (TDS(1), TDS(2), ..., TDS of the first frequency F1). (k)) may be supplied, and the touch driving signals TDS(k+1) and TDS(k+1) of a second frequency F2 different from the first frequency F1 are supplied to the second driving touch line group GR2. 2), …, TDS (2k)) can be supplied.

Here, the first driving touch line group GR1 is k driving touch lines to which touch driving signals TDS(1), TDS(2), ..., TDS(k) of the same first frequency F1 are applied. means (DTL(1) to DTL(k)). The second driving touch line group GR2 has k number of driving units to which touch driving signals (TDS(k+1), TDS(k+2), ..., TDS(2k)) of the same second frequency F2 are applied. This means the touch lines (DTL(k+1) to DTL(2k)).

Touch driving signals of the first frequency F1 supplied to the first driving touch line DTL(1) to the k th driving touch line DTL(k) included in the first driving touch line group GR1 ( TDS(1), TDS(2), ..., TDS(k)) can be distinguished from each other according to phase or code.

More specifically, the phase or phase pattern (pattern of phases) of the touch driving signal TDS(1) of the first frequency F1 supplied to the first driving touch line DTL(1) and the second driving touch The phase or phase pattern (pattern of phases) of the touch driving signal TDS(2) of the first frequency F1 supplied to the line DTL(2) and the k-th driving touch line DTL(k) The phase or phase pattern (pattern of phases) of the supplied touch driving signal TDS(k) of the first frequency F1 may all be different.

Here, the phase or phase pattern may be expressed as a code or code sequence.

The code of the touch driving signal (TDS(1)) of the first frequency (F1) supplied to the first driving touch line (DTL(1)) and the first driving signal (TDS(1)) supplied to the second driving touch line (DTL(2)). A code of the touch driving signal TDS(2) of the frequency F1 and a code of the touch driving signal TDS(k) of the first frequency F1 supplied to the kth driving touch line DTL(k) can all be different.

The code string CS1 of the touch driving signal TDS(1) of the first frequency F1 supplied to the first driving touch line DTL(1) and the second driving touch line DTL(2) The code CS2 of the touch driving signal TDS(2) of the first frequency F1 supplied and the touch driving signal of the first frequency F1 supplied to the kth driving touch line DTL(k) ( Code CSk of TDS(k) may all be different.

The second driving touch lines DTL(k+1) to (2k) th driving touch lines DTL(2k) included in the second driving touch line group GR2 are supplied. The touch driving signals TDS(k+1), TDS(k+2), ..., TDS(2k) of the frequency F2 may be distinguished from each other according to phases or codes.

More specifically, the phase or phase pattern (pattern of phases) of the touch driving signal TDS(k+1) of the second frequency F2 supplied to the k+1th driving touch line DTL(k+1). and a phase or phase pattern (pattern of phases) of the touch driving signal TDS(k+2) of the second frequency F2 supplied to the k+2th driving touch line DTL(k+2); The phase or phase pattern (pattern of phases) of the touch driving signal TDS(2k) of the second frequency F2 supplied to the 2kth driving touch line DTL(2k) may all be different.

Here, the phase or phase pattern may be expressed as a code or code sequence.

The code of the touch driving signal TDS(k+1) of the second frequency F2 supplied to the k+1th driving touch line DTL(k+1), and the k+2th driving touch line DTL( The code of the touch driving signal TDS(k+2) of the second frequency F2 supplied to the k+2) and the second frequency F2 supplied to the 2kth driving touch line DTL(2k) Codes of the touch driving signal (TDS 2k) of may all be different.

The code string CS1 of the touch driving signal TDS(k+1) of the second frequency F2 supplied to the k+1th driving touch line DTL(k+1) and the k+2th driving touch Code CS2 of the touch driving signal TDS(k+2) of the second frequency F2 supplied to the line DTL(k+2) and supplied to the 2kth driving touch line DTL(2k) The codes CSk of the touch driving signal TDS(2k) of the second frequency F2 may all be different.

In the case of performing the multi-frequency driving using the aforementioned code division, in each of the plurality of second sensing drive units SDU_S in the second touch circuit TC2, the preamplifier PRE-AMP is connected to the corresponding sensing touch line STL. ) is sensed, the analog-to-digital converter (ADC) converts the sensed value into digital, and the frequency analyzer (FRA) performs FFT on the digitally converted value to output FFT result data (frequency analysis result data). do.

The touch controller TCTR has frequency analysis result data (FFT result data) output from each of the plurality of frequency analyzers FRA included in the plurality of second sensing drive units SDU_S and a first frequency F1. The touch driving signals (TDS(1), TDS(2), ..., TDS(k) are distinguished from each other or the touch driving signals (TDS(k+1), TDS(k) having the second frequency F2 +2), ... , TDS (2k)) can be sensed based on phase information or code information that distinguishes them from each other.

Below, multi-frequency driving using code division will be described in more detail with reference to FIGS. 7 to 10 . However, below, the case where k is 4 will be described as an example.

K may mean the number of driving touch lines DTL to which the touch driving signals TDS of the same frequency are applied. Alternatively, k may mean different phases or the number of types of different phase patterns for distinguishing the touch driving signals TDS of the same frequency. Alternatively, k may mean different codes or the number of types of code strings for distinguishing the touch driving signals TDS of the same frequency.

7 is a diagram showing multi-frequency driving using code division in a touch system according to embodiments of the present invention by way of example, and FIG. 8 is a diagram showing multi-frequency driving using code division in a touch system according to embodiments of the present invention. 9 and 10 are other exemplary diagrams of a touch driving signal for multi-frequency driving using code division in a touch system according to embodiments of the present invention. .

Referring to FIG. 7 , the plurality of driving touch lines DTL disposed on the touch panel TSP includes a first driving touch line DTL(1) to a fourth driving touch line DTL(4). A first driving touch line group GR1 and a second driving touch line group GR2 including the fifth driving touch line DTL(k+1) to the eighth driving touch line DTL(8) are included. can do.

The first touch circuit TC1 in the touch circuit TC is the first driving touch line group GR1, and the touch driving signals (TDS(1), TDS(2), TDS(3) of the first frequency F1 ), TDS(4)), and touch driving signals (TDS(5), TDS(6) of a second frequency (F2) different from the first frequency (F1) as the second driving touch line group (GR2). ), TDS(7), TDS(8)) can be supplied.

Referring to FIG. 9 , touch driving signals (TDS(1), TDS(2), TDS(3), and TDS(4) of the first frequency F1 supplied to the first driving touch line group GR1) is a sinusoidal wave signal of the first frequency F1. Referring to FIG. 10 , touch driving signals (TDS(5), TDS(6), TDS(7), TDS(8)) of the second frequency F2 supplied to the second driving touch line group GR2 may be a sine wave signal of the second frequency F2.

Here, a case in which the first frequency F1 is 100 KHz and the second frequency F2 is 50 KHz is exemplified.

The touch driving signals TDS(1), TDS(2), TDS(3), and TDS(4) of the first frequency F1 supplied to the first driving touch line group GR1 are phased or coded according to can be distinguished from each other.

A touch driving signal TDS(1) supplied to the first driving touch line DTL(1) and a touch driving signal TDS(2) supplied to the second driving touch line DTL(2); The touch driving signal TDS(3) supplied to the third driving touch line DTL(3) and the touch driving signal TDS(4) supplied to the fourth driving touch line DTL(4) are The phase or phase pattern (change pattern of phases) can all be different.

A touch driving signal TDS(1) supplied to the first driving touch line DTL(1) and a touch driving signal TDS(2) supplied to the second driving touch line DTL(2); The touch driving signal TDS(3) supplied to the third driving touch line DTL(3) and the touch driving signal TDS(4) supplied to the fourth driving touch line DTL(4) are Codes represented by phases or code sequences represented by phase patterns (change patterns of phases) may all be different.

The touch driving signals (TDS(5), TDS(6), TDS(7), and TDS(8)) of the second frequency F2 supplied to the second driving touch line group GR2 are phased or coded. can be distinguished from each other.

A touch driving signal (TDS(5)) supplied to the fifth driving touch line (DTL(5)) and a touch driving signal (TDS(6)) supplied to the sixth driving touch line (DTL(6)); The touch driving signal TDS(7) supplied to the 7th driving touch line DTL(7) and the touch driving signal TDS(8) supplied to the 8th driving touch line DTL(8) are The phase or phase pattern (change pattern of phases) can all be different.

A touch driving signal (TDS(5)) supplied to the fifth driving touch line (DTL(5)) and a touch driving signal (TDS(6)) supplied to the sixth driving touch line (DTL(6)); The touch driving signal TDS(7) supplied to the 7th driving touch line DTL(7) and the touch driving signal TDS(8) supplied to the 8th driving touch line DTL(8) are Codes represented by phases or code sequences represented by phase patterns (change patterns of phases) may all be different.

Referring to FIGS. 7 and 8 , one code string is composed of 4-digit codes, and each digit code may be 1 or -1.

Referring to FIG. 8, when the code is 1, the phase is in phase (0 degrees). If the code is -1, the phase is out of phase (180 degrees).

Referring to FIG. 8, signal parts having a code of 1 have the same phase, and signal parts having a code of -1 have the same phase. A signal portion with a code of 1 and a signal portion with a code of -1 are out of phase.

As shown in FIG. 7, the touch driving signal TDS having the same frequency may be distinguished into four code columns (one code column consists of 4-digit codes), but as shown in FIG. 8, touches having the same frequency The driving signal TDS can also be distinguished by a 1-digit code.

When there are two types of codes (1, -1) and only one-digit codes are used, the touch driving signal TDS having the same frequency can be distinguished into two types according to the two codes (1, -1). Here, the two codes (1, -1) may correspond to different phases.

When there are 3 types of codes (-1, 0, 1) and only 1-digit codes are used, the touch drive signal (TDS) having the same frequency is classified into 3 types according to 3 types of codes (-1, 0, 1). It can be. Here, the three codes (-1, 0, 1) may correspond to different phases. Alternatively, among the three codes (-1, 0, 1), 1 and -1 may be in normal phase and out of phase, and 0 may be a case in which the amplitude is 0 (zero).

Even if there are two or more signal states (phase, amplitude, etc.) that can be expressed by a 1-digit code, if the code is 1 digit, the number of cases in which the touch driving signal TDS of the same frequency can be expressed differently is inevitably limited.

Therefore, as in the examples of FIGS. 7, 9, and 10, if a code string consisting of two or more digit codes is used, even if the frequency is the same, the touch driving signal TDS having various signal waveforms that can be distinguished from each other can make

Referring to the example of FIG. 9 , the touch driving signals (TDS(1), TDS(2), TDS(3), TDS(4) of the first frequency F1 supplied to the first driving touch line group GR1 )) as a code string. Also, there may be a total of four types of code strings ((1 1 1 1), (1 -1 1 -1), (1 1 -1 -1), (1 -1 -1 1)).

A code string (including four codes) of the touch driving signal TDS(1) supplied to the first driving touch line DTL(1) is (1 1 1 1). The code sequence of the touch driving signal TDS(2) supplied to the second driving touch line DTL(2) is (1 -1 1 -1). The code sequence of the touch driving signal TDS(3) supplied to the third driving touch line DTL(3) is (1 1 -1 -1). The code sequence of the touch driving signal TDS(4) supplied to the fourth driving touch line DTL(4) is (1 -1 -1 1).

Referring to the example of FIG. 10 , the touch driving signals (TDS(5), TDS(6), TDS(7), TDS(8) of the second frequency F2 supplied to the second driving touch line group GR2 )) as a code string. And, as in FIG. 9, there are a total of four types of code columns ((1 1 1 1), (1 -1 1 -1), (1 1 -1 -1), (1 -1 -1 1) ) can be.

A code string (including four codes) of the touch driving signal (TDS(5)) supplied to the fifth driving touch line (DTL(5)) is (1 1 1 1). The code sequence of the touch driving signal (TDS(6)) supplied to the sixth driving touch line (DTL(6)) is (1 -1 1 -1). The code sequence of the touch driving signal (TDS(7)) supplied to the seventh driving touch line (DTL(7)) is (1 1 -1 -1). The code sequence of the touch driving signal (TDS(8)) supplied to the eighth driving touch line (DTL(8)) is (1 -1 -1 1).

9 and 10 , a first driving touch line supplied to one of the first driving touch line DTL(1) to the fourth driving touch line DTL(4) included in the first driving touch line group GR1. The touch driving signal of 1 frequency F1 and the (5)th driving touch lines DTL(5) to (8)th driving touch lines DTL(8) included in the second driving touch line group GR2 The touch driving signal of the second frequency F2 supplied to one of the phases or codes may correspond to each other.

The code sequence of the touch driving signal TDS(1) supplied to the 1st driving touch line DTL(1) and the touch driving signal TDS(5) supplied to the 5th driving touch line DTL(5) The code columns are the same. Further, the code string of the touch driving signal (TDS(2)) supplied to the second driving touch line (DTL(2)) and the touch driving signal (TDS(6)) supplied to the sixth driving touch line (DTL(6)) ) are identical. Further, the code column of the touch driving signal (TDS(3)) supplied to the third driving touch line (DTL(3)) and the touch driving signal (TDS(7)) supplied to the seventh driving touch line (DTL(7)) ) are identical. Further, a code column of the touch driving signal (TDS(4)) supplied to the fourth driving touch line (DTL(4)) and a touch driving signal (TDS(8)) supplied to the eighth driving touch line (DTL(8)) ) are identical.

Referring to FIG. 9 , when k=4, the first driving touch line DTL(1) to the fourth (k=4) driving touch line DTL(k) included in the first driving touch line group GR1 )), the touch driving signals (TDS(1), TDS(2), TDS(3), and TDS(4)) of the first frequency F1 are 4 (k=4) codes that are distinguished from each other. phase corresponding to or 4 (k=4) distinct code sequences ((1 1 1 1), (1 -1 1 -1), (1 1 -1 -1), (1 -1 -1 It has a phase pattern corresponding to 1)). Here, 4 (k=4) code sequences ((1 1 1 1), (1 -1 1 -1), (1 1 -1 -1), (1 -1 -1 1)) are 4 digits It can be composed of the code of

Referring to FIG. 10 , the 5th (k+1=5) th driving touch line (DTL(5)) to the 8th (2k=2*4=8) th driving touch included in the second driving touch line group GR2 The touch driving signals TDS(5), TDS(6), TDS(7), and TDS(8) of the second frequency F2 supplied to the line DTL(8) are 4 (k= Phases corresponding to 4) codes or 4 (k=4) code sequences ((1 1 1 1), (1 -1 1 -1), (1 1 -1 -1), ( 1 -1 -1 has a phase pattern corresponding to 1)). Here, 4 (k=4) code sequences ((1 1 1 1), (1 -1 1 -1), (1 1 -1 -1), (1 -1 -1 1)) are 4 digits It can be composed of the code of

Referring to FIGS. 9 and 10, k codes or Touch of k code strings ((1 1 1 1), (1 -1 1 -1), (1 1 -1 -1), (1 -1 -1 1)) and the second frequency (F2) k codes or k code sequences ((1 1 1 1), (1 -1 1 -1), (1 1 -1 -1), and (1 -1 -1 1)) may correspond to each other.

For example, the TDS(1) of the first frequency F1 and the TDS(5) of the second frequency F2 may have the same code string (1 1 1 1). The TDS(2) of the first frequency (F1) and the TDS (6) of the second frequency (F2) may have the same code sequence (1 -1 1 -1). The TDS(3) of the first frequency (F1) and the TDS (7) of the second frequency (F2) may have the same code sequence (1 1 -1 -1). The TDS 4 of the first frequency F1 and the TDS 8 of the second frequency F2 may have the same code sequence (1 -1 -1 1).

9, the touch driving signals (TDS(1), TDS(2), TDS(TDS(1), TDS(2), TDS( 3), TDS (4)) may have 4 (k=4) first signal waveforms. Four (k=4) first signal waveforms correspond to four code strings.

Referring to FIG. 10 , touch driving signals (TDS(5), TDS(6), TDS(7), TDS(8)) of the second frequency F2 supplied to the second driving touch line group GR2 may have 4 (k=4) second signal waveforms. Four (k=4) first signal waveforms correspond to four code strings.

9 and 10, k first signal waveforms for the touch driving signals (TDS(1), TDS(2), TDS(3), TDS(4)) of a first frequency F1 and k second signal waveforms for the touch driving signals (TDS(5), TDS(6), TDS(7), TDS(8)) of the second frequency F2 may correspond to each other.

That is, the phase patterns of the k first signal waveforms for the touch driving signals (TDS(1), TDS(2), TDS(3), and TDS(4)) of the first frequency F1, and Phase patterns of k second signal waveforms for the touch driving signals (TDS(5), TDS(6), TDS(7), and TDS(8)) of 2 frequencies (F2) may correspond to each other.

For example, the TDS 1 of the first frequency F1 and the TDS 5 of the second frequency F2 may have the same phase pattern (normal phase-normal phase-normal phase-normal phase). The TDS 2 of the first frequency F1 and the TDS 6 of the second frequency F2 may have the same phase pattern (normal phase-antiphase-normal phase-antiphase). The TDS 3 of the first frequency F1 and the TDS 7 of the second frequency F2 may have the same phase pattern (normal phase - normal phase - reverse phase - reverse phase). The TDS 4 of the first frequency F1 and the TDS 8 of the second frequency F2 may have the same phase pattern (normal phase-antiphase-antiphase-normal phase).

Referring to FIG. 7 , when the touch driving signal TDS is applied to the plurality of driving touch lines DTL, mutual capacitances between the plurality of driving touch lines DTL and the plurality of sensing touch lines STL occur. ) can be created.

These mutual capacitances may be sensed by the plurality of second sensing drive units SDU_S in the second touch circuit TC2 connected to the plurality of sensing touch lines STL.

Referring to FIG. 7 , the input signal INS input to the first input terminal Ni1 of the preamplifier PRE-AMP included in each of the plurality of second sensing drive units SDU_S in the second touch circuit TC2 may be a DC voltage as a reference voltage.

Accordingly, the touch system operates as Case 1 and can sense a touch based on the mutual capacitance.

Meanwhile, when the input signal INS input to the first input terminal Ni1 of the preamplifier PRE-AMP included in each of the plurality of second sensing drive units SDU_S is a DC voltage, this DC voltage is It may be a voltage lower than the operating voltage of the circuit TC. For example, the DC voltage may be 1/2 of the operating voltage of the touch circuit TC.

Hereinafter, a method of sensing a touch through multi-frequency driving using code division described above will be described as an example with reference to FIGS. 11 to 15 .

11 to 15 are diagrams for explaining a touch sensing method using multi-frequency driving using code division in a touch system according to embodiments of the present invention.

Referring to FIG. 11 , a case where touches occur at two points is taken as an example. More specifically, a touch occurs at a point where the fourth driving touch line DTL(4) and the first sensing touch line STL(1) in the first driving touch line group GR1 intersect, and the second driving touch line A case in which a touch also occurs at a point where the sixth driving touch line DTL(6) and the first sensing touch line STL(1) in the touch line group GR2 intersect will be taken as an example.

Referring to FIG. 11 , according to multi-frequency driving using code division, the four driving touch lines DTL(1) to DTL(4) included in the first driving touch line group GR1 have a first frequency ( The touch driving signals (TDS(1) to TDS(4)) of F1) are applied, and the four driving touch lines (DTL(5) to DTL(6)) included in the second driving touch line group GR2 The touch driving signals TDS(5) to TDS(8) of the second frequency F2 are applied to .

In addition, according to multi-frequency driving using code division, among the four driving touch lines DTL(1) to DTL(4) included in the first driving touch line group GR1, the first driving touch line DTL (1)), the touch driving signal TDS(1) of the first frequency F1 in which the phase pattern is expressed by the (1 1 1 1) code string is applied, and the second driving touch line DTL(2) (1 -1 1 -1) The touch driving signal (TDS(2)) of the first frequency (F1) in which the phase pattern is expressed as a code string is applied, and the third driving touch line (DTL(3)) is (1 1 -1 -1) A touch driving signal (TDS(3)) of a first frequency (F1) in which a phase pattern is expressed as a code string is applied, and (1 -1 -1) is applied to the fourth driving touch line (DTL(4)). 1) A touch driving signal (TDS(4)) of a first frequency (F1) in which a phase pattern is represented by a code string is applied.

Among the four driving touch lines (DTL(5) to DTL(8)) included in the second driving touch line group GR2, the fifth driving touch line (DTL(5)) has (1 1 1 1) The touch driving signal (TDS(5)) of the second frequency (F2) in which the phase pattern is represented by the code string is applied, and the phase (1 -1 1 -1) code string is applied to the 6th driving touch line (DTL(6)). The touch driving signal (TDS(6)) of the second frequency (F2) in which the pattern is expressed is applied, and the phase pattern is expressed in (1 1 -1 -1) code columns in the 7th driving touch line (DTL(7)). A touch driving signal (TDS(7)) of the second frequency (F2) is applied, and a phase pattern is expressed as a (1 -1 -1 1) code sequence to the eighth driving touch line (DTL(8)). A touch driving signal (TDS 8) of frequency F2 is applied.

By four code columns ((1 1 1 1), (1 -1 1 -1), (1 1 -1 -1), (1 -1 -1 1)) ) can be defined.

<Encoding matrix>

After the multi-frequency driving using the above-described code division is performed, each second sensing drive unit SDU_S in the second touch circuit TC2 is connected to the corresponding sensing touch line STL through the preamplifier PRE-AMP. Detects a signal (touch sensing signal) corresponding to the mutual capacitance of , converts the detected signal into a digital value through an analog-to-digital converter (ADC), and converts the digital value to a frequency using a method such as FFT through a frequency analyzer (FRA). Analysis is performed, and frequency analysis result data is output. Here, the frequency analysis may be performed, for example, using an FFT method. Accordingly, the frequency analysis result data may be FFT result data. Hereinafter, for convenience of explanation, frequency analysis result data is also referred to as FFT result data.

As described above, assuming that k=4, the FFT result data can be made in the form of a 1*4 matrix such as [A B C D].

The touch controller TCTR or the second touch circuit TC2 performs a matrix multiplication operation process between the FFT result data and the decoding matrix to obtain a resultant value OUT.

Here, the decoding matrix corresponds to an inverse matrix of a predetermined encoding matrix. According to the example of the encoding matrix mentioned above, the decoding matrix is as follows.

<Decoding matrix>

The touch controller TCTR may determine whether there is a touch and/or touch coordinates by using the resultant value OUT of the matrix multiplication operation process.

13 shows a matrix multiplication operation process for FFT result data and a decoding matrix obtained according to multi-frequency driving using code division when touch does not occur, and FIG. 14 shows code when touch occurs at two points. It shows the matrix multiplication operation process for the decoding matrix and the FFT result data obtained according to multi-frequency driving using division.

Referring to FIG. 13, when there is no touch, the FFT result data [-320 0 0 0] is the touch driving signals (TDS(5), TDS(6), TDS(7) of the second frequency (F2=50KHz) ) and TDS(8) to the second driving touch line group GR2.

In the FFT result data [-320 0 0 0], -320, which is the first column value, is a touch of the second frequency (F2) having a phase corresponding to the codes (1 1 1 1) in the first column of the encoding matrix. Driving signals (TDS(5) of normal phase, TDS(6) of normal phase, TDS(7) of normal phase, and TDS(8) of normal phase) are driven as the 5th drive within the second driving touch line group GR2. The sensing touch line is supplied to the touch line (DTL(5)), the 6th driving touch line (DTL(6)), the 7th driving touch line (DTL(7)) and the 8th driving touch line (DTL(8)). This is the FFT result obtained from the touch sensing signal received through (STL(1)). This FFT result corresponds to the solid line at the 50 KHz point in the graph (a) of FIG. 15 .

In the FFT result data [-320 0 0 0], the second column value 0 is the second frequency F2 having a phase corresponding to codes (1 -1 1 -1) in the second column of the encoding matrix. The touch driving signals (TDS(5) of normal phase, TDS(6) of reverse phase, TDS(7) of normal phase, and TDS(8) of reverse phase) are applied to the 5th in the second driving touch line group GR2. Sensing touch by supplying to the driving touch line (DTL(5)), the 6th driving touch line (DTL(6)), the 7th driving touch line (DTL(7)) and the 8th driving touch line (DTL(8)) This is the FFT result obtained from the touch sensing signal received through the line (STL(1)). This FFT result corresponds to the solid line at the 50 KHz point in the graph (b) of FIG. 15 .

In the FFT result data [-320 0 0 0], the third column value, 0, is the value of the second frequency F2 having a phase corresponding to the codes (1 1 -1 -1) in the third column of the encoding matrix. The touch driving signals (TDS(5) of normal phase, TDS(6) of normal phase, TDS(7) of reverse phase, and TDS(8) of reverse phase) are applied to the 5th in the second driving touch line group GR2. Sensing touch by supplying to the driving touch line (DTL(5)), the 6th driving touch line (DTL(6)), the 7th driving touch line (DTL(7)) and the 8th driving touch line (DTL(8)) This is the FFT result obtained from the touch sensing signal received through the line (STL(1)). This FFT result corresponds to the solid line at the 50 KHz point in the graph (c) of FIG. 15 .

In the FFT result data [-320 0 0 0], the 4th column value 0 is the value of the second frequency F2 having a phase corresponding to the codes (1 -1 -1 1) in the 4th column of the encoding matrix. The touch driving signals (TDS(5) of normal phase, TDS(6) of reverse phase, TDS(7) of reverse phase, TDS(8) of normal phase) are applied to the 5th in the second driving touch line group GR2. Sensing touch by supplying to the driving touch line (DTL(5)), the 6th driving touch line (DTL(6)), the 7th driving touch line (DTL(7)) and the 8th driving touch line (DTL(8)) This is the FFT result obtained from the touch sensing signal received through the line (STL(1)). This FFT result corresponds to the solid line at the 50 KHz point in the graph (d) of FIG. 15 .

Referring to FIG. 13, when there is no touch, the FFT result data [350 0 0 0] is the touch driving signals (TDS(1), TDS(2), TDS(3) of the first frequency (F1 = 100KHz) , TDS(4) to the first driving touch line group GR1.

In the FFT result data [350 0 0 0], the first column value of 350 is the touch driving signal of the first frequency F1 having a phase corresponding to the codes (1 1 1 1) in the first column of the encoding matrix. (TDS(1) of normal phase, TDS(2) of normal phase, TDS(3) of normal phase, TDS(4) of normal phase) are the first driving touch lines in the first driving touch line group GR1. (DTL(1)), 2nd driving touch line (DTL(2)), 3rd driving touch line (DTL(3)) and 4th driving touch line (DTL(4)) This is the FFT result obtained from the touch sensing signal received through (1)). This FFT result corresponds to the solid line at the 100 KHz point in the graph (a) of FIG. 15 .

In the FFT result data [350 0 0 0], the second column value 0 is the touch of the first frequency F1 having a phase corresponding to the codes (1 -1 1 -1) in the second column of the encoding matrix. Driving signals (TDS(1) of normal phase, TDS(2) of reverse phase, TDS(3) of normal phase, and TDS(4) of reverse phase) are driven first in the first driving touch line group GR1. The sensing touch line is supplied to the touch line (DTL(1)), the 2nd driving touch line (DTL(2)), the 3rd driving touch line (DTL(3)) and the 4th driving touch line (DTL(4)). This is the FFT result obtained from the touch sensing signal received through (STL(1)). This FFT result corresponds to the solid line at the 100 KHz point in the graph (b) of FIG. 15 .

In the FFT result data [350 0 0 0], the third column value, 0, is a touch of the first frequency F1 having a phase corresponding to codes (1 1 -1 -1) in the third column of the encoding matrix. Drive signals (regular phase TDS(1), normal phase TDS(2), reverse phase TDS(3), reverse phase TDS(4)) are used to drive the first drive within the first driving touch line group GR1. The sensing touch line is supplied to the touch line (DTL(1)), the 2nd driving touch line (DTL(2)), the 3rd driving touch line (DTL(3)) and the 4th driving touch line (DTL(4)). This is the FFT result obtained from the touch sensing signal received through (STL(1)). This FFT result corresponds to the solid line at the 100 KHz point in the graph (c) of FIG. 15 .

In the FFT result data [350 0 0 0], the 4th column value, 0, is the touch of the first frequency F1 having a phase corresponding to the codes (1 -1 -1 1) in the 4th column of the encoding matrix. Drive signals (regular phase TDS(1), reverse phase TDS(2), reverse phase TDS(3), normal phase TDS(4)) are driven as a first step in the first driving touch line group GR1. The sensing touch line is supplied to the touch line (DTL(1)), the 2nd driving touch line (DTL(2)), the 3rd driving touch line (DTL(3)) and the 4th driving touch line (DTL(4)). This is the FFT result obtained from the touch sensing signal received through (STL(1)). This FFT result corresponds to the solid line at the 100 KHz point in the graph (d) of FIG. 15 .

Referring to FIG. 13 , the touch controller TCTR or the second touch circuit TC2 includes the fifth driving touch line DTL(5) to the eighth driving touch line included in the second driving touch line group GR2. For (DTL(8)), a matrix multiplication operation is performed on the FTT result data [-320 0 0 0] obtained through multi-frequency driving using code division and the decoding matrix, and the resulting value (OUT) is [-80 - 80 -80 -80]. The resulting value OUT in the form of a 1*4 matrix obtained in this way is referred to as a resultant value corresponding to a baseline in the case of no touch.

Looking at the result value (OUT) corresponding to this baseline, the first to fourth column values may be similar. The result value (OUT) corresponding to the baseline may be stored in advance.

Referring to FIG. 13 , the touch controller TCTR or the second touch circuit TC2 includes the first driving touch line DTL(1) to the fourth driving touch line included in the first driving touch line group GR1. For (DTL(4)), matrix multiplication operation is performed on the FTT result data [350 0 0 0] obtained through multi-frequency driving using code division and the decoding matrix, and the resulting value (OUT) is [88 88 88 88 ] is obtained. The resulting value OUT in the form of a 1*4 matrix obtained in this way is referred to as a resultant value corresponding to a baseline in the case of no touch.

Looking at the result value (OUT) corresponding to this baseline, the first to fourth column values may be similar. The result value (OUT) corresponding to the baseline may be stored in advance.

Referring to FIG. 14, when a touch occurs, the FFT result data [-256 -63 64 -63] is the second frequency (F2 = 50KHz) touch driving signals (TDS(5), TDS(6), TDS (7) is FFT result data obtained by applying TDS(8) to the second driving touch line group GR2.

In the FFT result data [-256 -63 64 -63], -256, the first column value, is the second frequency (F2) having a phase corresponding to the codes (1 1 1 1) in the first column of the encoding matrix. The touch driving signals (TDS(5) of normal phase, TDS(6) of normal phase, TDS(7) of normal phase, and TDS(8) of normal phase) of 5 in the second driving touch line group GR2 Sensing by supplying to the th driving touch line (DTL(5)), 6th driving touch line (DTL(6)), 7th driving touch line (DTL(7)) and 8th driving touch line (DTL(8)) This is the FFT result obtained from the touch sensing signal received through the touch line (STL(1)). This FFT result corresponds to the dotted line at the 50 KHz point in the graph (a) of FIG. 15 .

In the FFT result data [-256 -63 64 -63], the second column value -63 is the second frequency ( The touch driving signals (TDS(5) of normal phase, TDS(6) of reverse phase, TDS(7) of normal phase, TDS(8) of reverse phase) of F2) are applied to the second driving touch line group GR2. Supply to my 5th driving touch line (DTL(5)), 6th driving touch line (DTL(6)), 7th driving touch line (DTL(7)) and 8th driving touch line (DTL(8)) This is the FFT result obtained from the touch sensing signal received through the sensing touch line (STL(1)). This FFT result corresponds to the dotted line at the 50 KHz point in the graph (b) of FIG. 15 .

In the FFT result data [-256 -63 64 -63], the third column value of 64 is the second frequency (F2) having a phase corresponding to the codes (1 1 -1 -1) in the third column of the encoding matrix. ) in the second driving touch line group GR2. supplied to the 5th driving touch line (DTL(5)), 6th driving touch line (DTL(6)), 7th driving touch line (DTL(7)) and 8th driving touch line (DTL(8)) This is the FFT result obtained from the touch sensing signal received through the sensing touch line (STL(1)). This FFT result corresponds to the dotted line at the 50 KHz point in the graph (c) of FIG. 15 .

In the FFT result data [-256 -63 64 -63], -63, which is the 4th column value, is the second frequency ( The touch driving signals (TDS(5) of normal phase, TDS(6) of reverse phase, TDS(7) of reverse phase, TDS(8) of normal phase) of F2) are applied to the second driving touch line group GR2. Supply to my 5th driving touch line (DTL(5)), 6th driving touch line (DTL(6)), 7th driving touch line (DTL(7)) and 8th driving touch line (DTL(8)) This is the FFT result obtained from the touch sensing signal received through the sensing touch line (STL(1)). This FFT result corresponds to the dotted line at the 50 KHz point in the graph (d) of FIG. 15 .

Referring to FIG. 14, when a touch occurs, the FFT result data [280 70 70 -70] is the touch driving signals (TDS(1), TDS(2), TDS(3) of the first frequency (F1=100KHz) ) and TDS(4) to the first driving touch line group GR1.

In the FFT result data [280 70 70 -70], 280, which is the first column value, is a touch drive of the first frequency F1 having a phase corresponding to the codes (1 1 1 1) in the first column of the encoding matrix. The signals (TDS(1) of normal phase, TDS(2) of normal phase, TDS(3) of normal phase, and TDS(4) of normal phase) are applied to the first driving touch in the first driving touch line group GR1. The sensing touch line ( This is the FFT result obtained from the touch sensing signal received through the STL(1). This FFT result corresponds to the dotted line at the 100 KHz point in the graph (a) of FIG. 15 .

In the FFT result data [280 70 70 -70], the second column value of 70 is the value of the first frequency F1 having a phase corresponding to the codes (1 -1 1 -1) in the second column of the encoding matrix. The touch driving signals (TDS(1) of normal phase, TDS(2) of reverse phase, TDS(3) of normal phase, and TDS(4) of reverse phase) are applied to the first drive in the first driving touch line group GR1. Sensing touch by supplying to the driving touch line (DTL(1)), the 2nd driving touch line (DTL(2)), the 3rd driving touch line (DTL(3)) and the 4th driving touch line (DTL(4)) This is the FFT result obtained from the touch sensing signal received through the line (STL(1)). This FFT result corresponds to the dotted line at the 100 KHz point in the graph (b) of FIG. 15 .

In the FFT result data [280 70 70 -70], the third column value of 70 is the value of the first frequency F1 having a phase corresponding to the codes (1 1 -1 -1) in the third column of the encoding matrix. The touch driving signals (normal phase TDS(1), normal phase TDS(2), reverse phase TDS(3), reverse phase TDS(4)) are transmitted to the first driving touch line group GR1. Sensing touch by supplying to the driving touch line (DTL(1)), the 2nd driving touch line (DTL(2)), the 3rd driving touch line (DTL(3)) and the 4th driving touch line (DTL(4)) This is the FFT result obtained from the touch sensing signal received through the line (STL(1)). This FFT result corresponds to the dotted line at the 100 KHz point in the graph (c) of FIG. 15 .

In the FFT result data [280 70 70 -70], the 4th column value -70 is the first frequency F1 having a phase corresponding to the codes (1 -1 -1 1) in the 4th column of the encoding matrix. of the touch driving signals (TDS(1) of normal phase, TDS(2) of reverse phase, TDS(3) of reverse phase, and TDS(4) of normal phase) to 1 in the first driving touch line group GR1. Sensing by supplying to the 1st driving touch line (DTL(1)), 2nd driving touch line (DTL(2)), 3rd driving touch line (DTL(3)) and 4th driving touch line (DTL(4)) This is the FFT result obtained from the touch sensing signal received through the touch line (STL(1)). This FFT result corresponds to the dotted line at the 100 KHz point in the graph (d) of FIG. 15 .

Referring to FIG. 14 , the touch controller TCTR or the second touch circuit TC2 includes the fifth driving touch line DTL(5) to the eighth driving touch line included in the second driving touch line group GR2. [-256 -63 64 -63] and the decoding matrix obtained through multi-frequency driving using code division for (DTL(8)) are matrix multiplied, and the resulting value (OUT) is [- 80 -16 -80 -80].

The touch controller (TCTR) compares the resulting value (OUT) [-80 -16 -80 -80] in the form of a 1*4 matrix obtained in this way with the resultant value (OUT) [-80 -80 -80 -80] of FIG. It can be seen that the second column value (-16) in the result value (OUT) [-80 -16 -80 -80] of FIG. 14 is greatly changed compared to the column value (-80) in the base line.

Therefore, the touch controller TCTR is driven by the 2nd sixth driving touch line among the fifth driving touch line DTL(5) to the eighth driving touch line DTL(8) included in the second driving touch line group GR2. It can be confirmed that a touch has occurred at a point where the touch line DTL(6) and the corresponding sensing touch line STL(1) intersect.

Referring to FIG. 14 , the touch controller TCTR or the second touch circuit TC2 includes the first driving touch line DTL(1) to the fourth driving touch line included in the first driving touch line group GR1. For (DTL(4)), a matrix multiplication operation process is performed on the FTT result data [280 70 70 -70] obtained through multi-frequency driving using code division and the decoding matrix, and as the result value (OUT) is [88 88 88 17] is obtained.

The touch controller (TCTR) compares the resulting value (OUT) [88 88 88 17] in the form of a 1*4 matrix obtained in this way with the resultant value (OUT) [88 88 88 88] of FIG. 13, the resultant value ( OUT) [88 88 88 17], it can be seen that the fourth column value (17) is greatly changed compared to the column value (88) in the baseline.

Therefore, the touch controller TCTR is driven by a fourth driving touch line among the first driving touch lines DTL( 1 ) to the fourth driving touch lines DTL( 4 ) included in the first driving touch line group GR1 . It can be confirmed that a touch has occurred at a point where the touch line DTL(4) and the corresponding sensing touch line STL(1) intersect.

Meanwhile, the time required for touch sensing may be inversely proportional to a frequency difference between used frequencies.

In this regard, in the case of multi-frequency driving using the code division described above with reference to FIGS. 6 to 15, the difference between the used frequencies (100 KHz and 50 KHz) is 50 KHz. Therefore, in the case of using multi-frequency driving using code division, the time required to find out whether there is a touch or touch coordinates in the entire area of the touch panel TSP is the frequency difference between the first frequency F1 and the second frequency F2. can be inversely proportional to

If the above-described touch sensing method through multi-frequency driving using code division is used, Case 1 can be provided among the above-described five cases, and the first touch circuit TC1 and the second touch circuit TC2 If the roles are reversed and the roles of the driving touch lines DTL and the sensing touch lines STL are reversed, Case 2 can be provided in the same manner.

Below, among the five cases, cases 3 and 4 operating in a mixed sensing mode that simultaneously provides a mutual capacitance sensing mode and a self-capacitance sensing mode will be described. Cases 3 and 4 are identical in that they operate in mixed sensing mode, and only the roles of the first touch circuit TC1 and the second touch circuit TC2 are reversed.

Therefore, below, Case 3 is representatively described for convenience of description. Case 3 is a case of operating in a mixed sensing mode (mutual capacitance sensing mode, self-capacitance sensing mode), the first touch circuit TC1 operates as a driving circuit for mutual capacitance sensing, and the second touch circuit TC2 is operated as a sensing circuit for mutual capacitance sensing, and the second touch circuit TC2 also operates as a driving circuit and a sensing circuit for self-capacitance sensing.

However, in the description of Case 3, it is exemplified that only multi-frequency driving is applied without applying code division driving.

16 is a diagram illustrating multi-frequency driving in a touch system according to embodiments of the present invention, and FIG. 17 is a diagram showing self-capacitance and mutual capacitance through multi-frequency driving in a touch system according to embodiments of the present invention. It is a diagram showing a method of simultaneously sensing.

Referring to FIG. 16 , the first touch circuit TC1 includes a plurality of driving touch lines DTL(1) to DTL(8) and transmits touch driving signals (TDS(1) to TDS(8) having different frequencies. )) can be supplied. In the example of FIG. 16 , eight frequency types (100, 110, 120, 130, 140, 150, 160, and 170 KHz) and a frequency difference of 10 KHz are exemplified.

Referring to FIG. 16 , in order to provide a mixed sensing mode for simultaneously sensing self-capacitance and mutual capacitance, a preamplifier (PRE) included in each of the plurality of second sensing drive units (SDU_S) in the second touch circuit (TC2). The input signal (INS) input to the first input terminal (Ni1) of the -AMP) may not be a DC voltage but an AC signal formed of a sine wave signal.

The input signal INS made of a sine wave signal may have a third frequency F3.

Here, the third frequency F3 is the frequencies 100 of the touch driving signals TDS(1) to TDS(8) supplied to the plurality of driving touch lines DTL(1) to DTL(8). , 110, 120, 130, 140, 150, 160, 170 KHz) and other frequencies.

Below, as an example, the input signal INS input to the first input terminal Ni1 of the preamplifier PRE-AMP included in each of the plurality of second sensing drive units SDU_S in the second touch circuit TC2. ) is 90 KHz.

The input signal INS in the form of a sine wave signal input to the first input terminal Ni1 of the preamplifier PRE-AMP included in each of the plurality of second sensing drive units SDU_S in the second touch circuit TC2 is , may be a touch driving signal that causes self capacitance to be generated in the corresponding sensing touch lines STL(1) and STL(2).

In other words, in FIG. 16 , the touch driving signals TDS(1) to TDS(8) supplied to the plurality of driving touch lines DTL(1) to DTL(8) by the first touch circuit TC1 ) is a touch driving signal necessary for sensing the mutual capacitance. In contrast, an input signal in the form of a sine wave signal ( INS) is a touch driving signal necessary for sensing the self capacitance.

Referring to FIG. 16, the point where the fourth driving touch line (DTL(4)) driven by the 130 KHz touch driving signal (TDS(4)) and the first sensing touch line (STL(1)) intersect, Touch at two points including the intersection of the 6th driving touch line (DTL(6)) driven by the 150 KHz touch driving signal (TDS(4)) and the 1st sensing touch line (STL(1)) For example, the case where

As described above, multi-frequency driving is performed on the plurality of driving touch lines (DTL(1) to DTL(8)), and the plurality of sensing touch lines (STL(1) and STL(2)) After an input signal (INS, a touch driving signal necessary for sensing the self-capacitance) in the form of a sine wave signal is supplied, the FFT result obtained by the second touch circuit TC2 may be shown as shown in FIG. 17 .

Referring to FIG. 17, the touch controller TCTR finds that, from the FFT result, at the point of 90 KHz corresponding to the third frequency F3, the amount of change (2pF, 1pF) in capacitance (self-capacitance) is greater than when there is no touch. Able to know.

Accordingly, the touch controller TCTR cannot know the exact coordinates of the touch, but can know that a touch has occurred on the first sensing touch line STL( 1 ).

Also, referring to FIG. 17, the touch controller (TCTR) calculates the amount of change in capacitance (mutual capacitance) (0.5 pF, 0.5 pF, 0.25 pF) is found to have occurred significantly.

Therefore, in the touch controller TCTR, the fourth driving touch line DTL(4) driven by the 130 KHz touch driving signal TDS(4) and the first sensing touch line STL(1) intersect. point, and two points including the intersection of the 6th driving touch line (DTL(6)) driven by the 150 KHz touch driving signal (TDS(4)) and the 1st sensing touch line (STL(1)). It can be seen that a touch occurred at the point.

18 is a diagram showing a circuit for inputting an input signal INS to the first input terminal Ni1 of the preamplifier PRE-AMP in the touch system according to the embodiments of the present invention.

As shown in FIG. 16, in order to operate in the mixed sensing mode as in Case 3, the input signal INS in the form of a sine wave signal (AC signal form) is applied to the first input terminal Ni1 of the preamplifier PRE-AMP. should be entered

Alternatively, in order to operate in the self-capacitance sensing mode as in Case 5, the input signal INS in the form of a sine wave signal (AC signal form) must be input to the first input terminal Ni1 of the preamplifier PRE-AMP.

However, in order to operate in the mutual capacitance sensing mode as in Case 1, the input signal INS in the form of a DC voltage must be input to the first input terminal Ni1 of the preamplifier PRE-AMP.

Therefore, depending on the type of sensing mode, the input signal INS in the form of a DC voltage and the input signal INS in the form of an AC signal (sinusoidal signal form) is selectively applied to the first input terminal Ni1 of the preamplifier PRE-AMP. In order to input as , the switch SW may be configured inside or outside the second touch circuit TC2.

The switch SW switches one of the DC power supply DSUP outputting a DC voltage and the AC power supply ASUP outputting an AC signal to the preamplifier PRE-AMP according to the sensing mode control signal SMCS. It is electrically connected to the first input terminal (Ni1).

If the multi-frequency driving described above is used, many touch lines can be simultaneously driven, thereby reducing the touch driving time and increasing the touch sensing speed.

Comparing the multi-frequency driving using code division described above with reference to FIGS. 6 to 15 and the multi-frequency driving described above with reference to FIGS. 16 and 17, the case of performing multi-frequency driving using code division , the number of frequencies used can be reduced, and as a result, there is no need to densely use various frequencies, thereby reducing the complexity of frequency analysis (FFT).

Meanwhile, the time required for touch sensing may be inversely proportional to a frequency difference between used frequencies.

In this regard, in the case of multi-frequency driving using the code division described above with reference to FIGS. 6 to 15, the difference between the used frequencies (100 KHz and 50 KHz) is 50 KHz, and In the case of the aforementioned multi-frequency driving, a difference between user frequencies 100, 110, 120, 130, 140, 150, 160, and 170 KHz is 10 KHz. Accordingly, in the case of the multi-frequency driving using the code division described above with reference to FIGS. 6 to 15, since the frequency difference is larger, the time required for touch sensing can be further reduced. That is, if the multi-frequency driving using the aforementioned code division is used, touch sensing can be performed more quickly.

Meanwhile, as described above, in the touch system according to embodiments of the present invention, each of the first sensing drive unit SDU_D and the second touch circuit in the first touch circuit TC1 is provided in order to provide all five cases. Each second sensing and driving unit SDU_S in TC2 may have the same circuit configuration. That is, each of the first sensing drive unit SDU_D and the second sensing drive unit SDU_S may include both a driving amplifier DR-AMP and a pre-amplifier PRE-AMP.

FIG. 19 is another exemplary view of the first sensing and driving unit SDU_D included in the first touch circuit TC1 in the touch circuit TC of the touch system according to embodiments of the present invention. 20 is another exemplary view of the second sensing and driving unit SDU_S included in the second touch circuit TC2 in the touch circuit TC of the touch system according to embodiments of the present invention. 21 illustrates first sensing drive units SDU_D electrically connected to driving touch lines and second sensing drive units SDU_S electrically connected to sensing touch lines in a touch system according to embodiments of the present invention. is the drawing shown.

Referring to FIG. 21 , the first touch circuit TC1 may include first sensing and driving units SDU_D electrically connected to the driving touch lines DTL1 , DTL2 , DTL3 , and DTL4 . The second touch circuit TC2 may include second sensing drive units SDU_S electrically connected to the sensing touch lines STL1 , STL2 , STL3 , and STL4 .

Referring to FIG. 19 , the first touch circuit TC1 includes, in addition to the plurality of driving amplifiers DR-AMPs, a plurality of preamplifiers PRE-AMPs corresponding to the plurality of driving amplifiers DR-AMPs, and a plurality of preamplifiers PRE-AMPs. It may further include a plurality of analog-to-digital converters (ADCs) electrically connected to the pre-amplifier (PRE-AMP) of the corresponding and a plurality of frequency analyzers (FRAs) electrically connected to the plurality of analog-to-digital converters (ADCs). there is.

That is, each first sensing and driving unit SDU_D in the first touch circuit TC1 has a drive input terminal mi that receives the input signal IND-2 and a drive that amplifies and outputs the input signal IND-2. It includes a drive amplifier (DR-AMP) having an output stage (mo), and may further include a preamplifier (PRE-AMP), a plurality of analog-to-digital converters (ADC), and a frequency analyzer (FRA). Here, the input signal IND-2 input to the driving input terminal mi may be a touch driving signal for mutual capacitance sensing.

The pre-amplifier PRE-AMP has a first input terminal ni1 receiving the input signal IND-1 and a second input terminal electrically connected to the corresponding drive output terminal mo of the driving amplifier DR-AMP. (ni2) and an output terminal (no) electrically connected to a corresponding analog-to-digital converter (ADC).

Here, the input signal IND-1 input to the first input terminal ni1 of the preamplifier PRE-AMP may be a DC voltage or an AC signal (sine wave signal). The DC voltage may be a reference voltage for mutual capacitance sensing, and the AC signal (sinusoidal wave signal) may be a touch driving signal for self-capacitance sensing.

Referring to FIG. 19 , the operation of the preamplifier PRE-AMP included in the first sensing drive unit SDU_D can be activated by the first sensing activation signal END-1. The operation of the driving amplifier DR-AMP included in the first sensing and driving unit SDU_D may be activated by the first driving activation signal END-2.

Referring to FIG. 20, the second touch circuit TC2 includes a plurality of preamplifiers PRE-AMP and a plurality of analog-to-digital converters ADC electrically connected to the plurality of preamplifiers PRE-AMP. , including a plurality of frequency analyzers (FRA) electrically connected to a plurality of analog-to-digital converters (ADC), and further including a plurality of drive amplifiers (DR-AMP) corresponding to a plurality of pre-amplifiers (PRE-AMP) can do.

That is, each second sensing and driving unit SDU_S in the second touch circuit TC2 corresponds to the driving signal, in addition to the preamplifier PRE-AMP, the plurality of analog-to-digital converters ADC and the frequency analyzer FRA. A driving amplifier DR-AMP having a driving input terminal Mi receiving the input signal INS-2 and a driving output terminal Mo amplifying and outputting the input signal INS-2 may be further included. Here, the input signal INS-2 input to the driving input terminal Mi may be a touch driving signal for mutual capacitance sensing.

The preamplifier (PRE-AMP) has a first input terminal (Ni1) receiving the input signal (INS-1) and a second input terminal electrically connected to the driving output terminal (Mo) of the corresponding driving amplifier (DR-AMP). (Ni2) and an output terminal (No) electrically connected to the corresponding analog-to-digital converter (ADC).

Here, the input signal INS-1 input to the first input terminal Ni1 of the preamplifier PRE-AMP may be a DC voltage or an AC signal (sine wave signal). The DC voltage may be a reference voltage for mutual capacitance sensing, and the AC signal (sinusoidal wave signal) may be a touch driving signal for self-capacitance sensing.

Referring to FIG. 20 , the operation of the preamplifier PRE-AMP included in the second sensing drive unit SDU_S may be activated by the second sensing activation signal ENS-1. The operation of the driving amplifier DR-AMP included in the second sensing and driving unit SDU_S may be activated by the second driving activation signal ENS-2.

22 illustrates various operation cases and various sensing modes using the first sensing drive unit SDU_D of FIG. 19 and the second sensing drive unit SDU_S of FIG. 20 in a touch system according to embodiments of the present invention. This is a diagram showing a table classified into five cases, and FIGS. 23 to 25 are views schematically showing driving and sensing operations for the five cases.

22 and 23 , Case 1 is a case of operating in the mutual capacitance sensing mode, the first touch circuit TC1 operates as a driving circuit for mutual capacitance sensing, and the second touch circuit TC2 operates as a driving circuit for mutual capacitance sensing. This is a case of operating as a sensing circuit for mutual capacitance sensing.

In this case, the first touch circuit TC1 may supply touch driving signals code-divided and frequency-divided to all or part of the plurality of driving touch lines DTL. The second touch circuit TC2 may sense all or part of the plurality of sensing touch lines STL. Here, the sensing is sensing the mutual capacitance between the corresponding sensing touch line STL and the corresponding driving touch line DTL.

22 and 23, Case 2 is a case of operating in the mutual capacitance sensing mode, the first touch circuit TC1 operates as a sensing circuit for mutual capacitance sensing, and the second touch circuit TC2 operates in the mutual capacitance sensing mode. This is the case of operating as a driving circuit for capacitance sensing.

In this case, the second touch circuit TC2 may supply touch driving signals code-divided and frequency-divided to all or part of the plurality of sensing touch lines STL. The first touch circuit TC1 may sense all or part of the plurality of driving touch lines DTL. Here, the sensing is sensing the mutual capacitance between the corresponding sensing touch line STL and the corresponding driving touch line DTL.

22 and 24, Case 3 is a case of operating in a mixed sensing mode (mutual capacitance sensing mode, self-capacitance sensing mode), and the first touch circuit TC1 operates as a driving circuit for mutual capacitance sensing. , This is a case where the second touch circuit TC2 operates as a sensing circuit for mutual capacitance sensing, and a case where the second touch circuit TC2 also operates as a driving circuit and a sensing circuit for self-capacitance sensing.

In this case, the first touch circuit TC1 may supply touch driving signals code-divided and frequency-divided to all or part of the plurality of driving touch lines DTL.

The second touch circuit TC2 may drive and sense all or part of the plurality of sensing touch lines STL.

More specifically, the second touch circuit TC2 may simultaneously or sequentially supply touch driving signals (touch driving signals for sensing self-capacitance) to all or part of the plurality of sensing touch lines STL. Also, the second touch circuit TC2 may simultaneously or sequentially detect touch sensing signals from all or part of the plurality of sensing touch lines STL. Here, the touch sensing signal may be a signal that reflects both mutual capacitance between the corresponding sensing touch line STL and the corresponding driving touch line DTL and self capacitance of the corresponding sensing touch line STL. .

22 and 24, Case 4 is a case of operating in a mixed sensing mode (mutual capacitance sensing mode, self-capacitance sensing mode), and the second touch circuit TC2 operates as a driving circuit for mutual capacitance sensing. , This is a case where the first touch circuit TC1 operates as a sensing circuit for sensing mutual capacitance, and a case where the first touch circuit TC1 also operates as a driving circuit and a sensing circuit for sensing self-capacitance.

In this case, the second touch circuit TC2 may supply touch driving signals code-divided and frequency-divided to all or part of the plurality of sensing touch lines STL.

The first touch circuit TC1 may drive and sense all or part of the plurality of driving touch lines (DTL(1), DTL(2), DTL(3), DTL(4), ...).

More specifically, the first touch circuit TC1 may simultaneously or sequentially supply touch driving signals (touch driving signals for sensing self-capacitance) to all or part of the plurality of driving touch lines DTL. The first touch circuit TC1 may simultaneously or sequentially detect touch sensing signals from all or part of the plurality of driving touch lines DTL.

Here, the touch sensing signal may be a signal that reflects both mutual capacitance between the corresponding driving touch line DTL and the corresponding sensing touch line STL and self capacitance of the corresponding driving touch line DTL. .

22 and 25 , Case 5 is a case of operating in the self-sensing mode, the first touch circuit TC1 operates as a driving circuit and a sensing circuit for self-capacitance sensing, and the second touch circuit TC2 This is also the case of operating as a driving circuit and a sensing circuit for self-capacitance sensing.

In this case, the first touch circuit TC1 supplies touch driving signals to all or part of the plurality of driving touch lines DTL and simultaneously or sequentially transmits touch sensing signals from all or parts of the plurality of driving touch lines DTL. can be detected. Here, the touch sensing signal may be a signal reflecting self capacitance of the corresponding driving touch line DTL.

Similarly, the second touch circuit TC2 supplies touch driving signals to all or part of the plurality of sensing touch lines STL, and simultaneously or sequentially supplies touch sensing signals from all or part of the plurality of sensing touch lines STL. Here, the touch sensing signal may be a signal reflecting self capacitance of the corresponding sensing touch line STL.

Referring to FIG. 22 , Cases 1 and 2 may consume less power than Cases 3 and 4.

Meanwhile, the mutual capacitance sensing mode may have relatively better touch sensing accuracy than the self capacitance sensing mode. The self-capacitance sensing mode may consume relatively less power than the mutual capacitance sensing mode.

Considering these characteristics, Case 5 can be used for activating the touch system in idle mode or standby mode. And Case 5 can be utilized in a pen mode that senses one pen (in particular, an active pen). In addition, Case 5 can be used in a situation where the touch panel (TSP) is wet.

The above-described touch sensing method will be briefly described again. However, the explanation will be centered on Case 1.

26 is a flowchart of a touch sensing method of a touch system according to embodiments of the present invention.

Referring to FIGS. 26 and 7 together, a touch sensing method of a touch system according to embodiments of the present invention transmits a touch driving signal to all or part of a plurality of driving touch lines DTL disposed on a touch panel TSP. It may include supplying (S2610) and sensing a touch through all or part of the plurality of sensing touch lines (STL) disposed on the touch panel (TSP) (S2620).

The plurality of driving touch lines DTL includes a first driving touch line group GR1 including k driving touch lines DTL(1) to DTL(k) and another k driving touch lines DTL(k). A second driving touch line group GR2 including +1) to DTL(2k) may be included. k is a natural number greater than or equal to 2;

The touch driving signals supplied to the first driving touch line group GR1 and the touch driving signals supplied to the second driving touch line group GR2 are distinguished from each other by frequency,

Touch driving signals supplied to the first driving touch line group GR1 are distinguished from each other by phase or code, and touch driving signals supplied to the second driving touch line group GR2 are distinguished from each other by phase or code. It can be.

Before step S2620, in order to perform self-capacitance sensing as well as mutual capacitance sensing, other touch driving signals may be supplied to all or part of the plurality of sensing touch lines STL. (This is the operation for Case 3)

Touch driving signals supplied to the first driving touch line group GR1 may have a first frequency, and touch driving signals supplied to the second driving touch line group GR2 may have a second frequency different from the first frequency. .

Other touch driving signals supplied to all or part of the plurality of sensing touch lines STL may have a third frequency different from the first and second frequencies.

27 is an exemplary view of a touch panel (TSP) according to embodiments of the present invention, and FIG. 28 is another exemplary view of a touch panel (TSP) according to embodiments of the present invention.

A plurality of driving touch lines DTL and a plurality of sensing touch lines STL may be disposed on the touch panel TSP while crossing each other.

Referring to FIG. 27 , each of the plurality of driving touch lines DTL and the plurality of sensing touch lines STL may be a single touch electrode in the form of a line or a bar.

A pad area to which the touch circuit TC is electrically connected exists in an outer area of the touch panel TSP. A plurality of driving touch pads DTP and a plurality of sensing touch pads STP may be disposed in the pad area.

Each of the plurality of driving touch lines DTL may correspond to and electrically connect to the driving touch pad DTP through one or more driving routing wires DRL.

Each of the plurality of sensing touch lines STL may correspond to and electrically connect to the sensing touch pad STP through one or more sensing routing lines SRL.

Referring to FIG. 28 , each of the plurality of driving touch lines DTL and the plurality of sensing touch lines STL may include a plurality of electrically connected touch electrodes.

For example, one driving touch line DTL may include several driving touch electrodes DTE and driving connection patterns DCL electrically connecting them.

Here, the driving connection patterns DCL may be a pattern integrated with the driving touch electrodes DTE or may be a separate pattern different from the driving touch electrodes DTE.

The driving touch electrodes DTE and the driving connection patterns DCL may be positioned on different layers or on the same layer.

One sensing touch line STL may include a plurality of sensing touch electrodes STE and sensing connection patterns SCL electrically connecting them.

Here, the sensing connection patterns SCL may be a pattern integrated with the sensing touch electrodes STE or a separate pattern different from the sensing touch electrodes STE.

The sensing touch electrodes STE and the sensing connection patterns SCL may be positioned on different layers or on the same layer.

A pad area to which the touch circuit TC is electrically connected exists in an outer area of the touch panel TSP. A plurality of driving touch pads DTP and a plurality of sensing touch pads STP may be disposed in the pad area.

Each of the plurality of driving touch lines DTL may correspond to and electrically connect to the driving touch pad DTP through one or more driving routing wires DRL.

Each of the plurality of sensing touch lines STL may correspond to and electrically connect to the sensing touch pad STP through one or more sensing routing lines SRL.

Referring to FIG. 28 , one or more touch electrodes DTE and STE constituting each of the plurality of driving touch lines DTL and the plurality of sensing touch lines STL may be plate-shaped electrodes without open areas or open areas. It may be a mesh-shaped electrode with regions. Here, each of the open areas existing in one touch electrode DTE or STE may correspond to one or more subpixels or their light emitting areas.

Referring to FIGS. 27 and 28 , the plurality of driving touch lines DTL and the plurality of sensing touch lines STL may be positioned on different layers or on the same layer.

In addition to the examples of FIGS. 27 and 28, equivalently, as long as it can be implemented as shown in FIG. 2, it can be configured in any form.

The touch system according to the above-described embodiments of the present invention will be briefly described again. However, considering the touch panel TSP of FIGS. 27 and 28, the touch line is described as a touch electrode.

A touch system according to embodiments of the present invention may include a touch panel (TSP) on which a plurality of touch electrodes are disposed, and a touch circuit (TC) that supplies a touch driving signal to all or part of the plurality of touch electrodes. .

The plurality of touch electrodes may include a first touch electrode group (corresponding to GR1) including k touch electrodes and a second touch electrode group (corresponding to GR2) including k other touch electrodes. k is a natural number greater than or equal to 2;

The touch circuit TC may supply touch driving signals of a first frequency to the first touch electrode group, and may supply touch driving signals of a second frequency different from the first frequency to the second touch electrode group.

The touch driving signals of the first frequency supplied to the k touch electrodes in the first touch electrode group may be distinguished from each other by phase or code. The touch driving signals of the second frequency supplied to k touch electrodes in the second touch electrode group may be distinguished from each other by phase or code.

According to the embodiments of the present invention described above, there is an effect of providing a touch display device, a touch system, a touch circuit, and a touch sensing method capable of sensing a touch more quickly.

According to the embodiments of the present invention, there is an effect of providing a touch display device robust against noise, a touch system, a touch circuit, and a touch sensing method.

According to embodiments of the present invention, there is an effect of providing a touch display device, a touch system, a touch circuit, and a touch sensing method capable of simultaneously driving a plurality of touch lines or a plurality of touch electrodes disposed on a touch panel.

According to embodiments of the present invention, there is an effect of providing a touch display device, a touch system, a touch circuit, and a touch sensing method capable of both touch sensing based on mutual capacitance and touch sensing based on self capacitance.

According to the embodiments of the present invention, there is an effect of providing a touch display device, a touch system, a touch circuit, and a touch sensing method that enable touch sensing suitable for various situations by allowing various sensing modes to be set.

The above description and accompanying drawings are merely illustrative of the technical idea of the present invention, and those skilled in the art can combine the configuration within the scope not departing from the essential characteristics of the present invention. , various modifications and variations such as separation, substitution and alteration will be possible. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed according to the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

Claims (30)

a touch panel on which a plurality of driving touch lines are disposed; and
A touch circuit for driving the plurality of driving touch lines;
The plurality of driving touch lines,
A first driving touch line group including a 1 th driving touch line to a k th driving touch line, and a second driving touch line group including a (k+1) th driving touch line to a (2k) th driving touch line And, k is a natural number greater than or equal to 2,
The touch circuit,
supplying touch driving signals of a first frequency to the first driving touch line group;
supplying touch driving signals of a second frequency different from the first frequency to the second driving touch line group;
The touch driving signals of the first frequency supplied to the 1st driving touch line to the k th driving touch line included in the first driving touch line group are distinguished from each other according to a phase or code;
The touch driving signals of the second frequency supplied to the (k+1) th driving touch line to the (2k) th driving touch line included in the second driving touch line group are distinguished from each other according to a phase or code,
The touch driving signals of the first frequency supplied to the 1st driving touch line to the k th driving touch line included in the first driving touch line group have phase patterns corresponding to the k code strings that are distinguished from each other,
The k code sequences include k digit codes,
The k digit code included in one of the k code strings,
Among the touch drive signals of the first frequency, at least one touch drive signal of the first frequency corresponding to the one code string exhibits a normal-phase relationship with the touch drive signal of the first frequency corresponding to at least one other code string. At least one anti-phase code exhibiting an anti-phase relationship with the normal-phase code;
The touch driving signals of the second frequency supplied to the (k+1) th driving touch line to the (2k) th driving touch line included in the second driving touch line group correspond to the k code strings that are distinguished from each other. have a phase pattern,
The k code sequences distinguishing the touch driving signals of the second frequency from each other include the k digit codes;
The k digit code included in one code sequence among the k code sequences for distinguishing the touch driving signals of the second frequency from each other,
Among the touch driving signals of the second frequency, at least one touch driving signal of the second frequency corresponding to the one code string exhibiting a normal-phase relationship with the touch driving signal of the second frequency corresponding to at least one other code string A touch system comprising at least one anti-phase code representing an anti-phase relationship with a normal-phase code.
According to claim 1,
The touch driving signals of the first frequency supplied to the first driving touch line group are sine wave signals of the first frequency;
The touch driving signals of the second frequency supplied to the second driving touch line group are sinusoidal signals of the second frequency.
According to claim 1,
A touch driving signal of the first frequency supplied to one of the first driving touch line to the k-th driving touch line included in the first driving touch line group, and (k+1) included in the second driving touch line group. The touch driving signal of the second frequency supplied to one of the )th driving touch line to the (2k)th driving touch line has a phase or code corresponding to each other.
According to claim 1,
The touch driving signals of the second frequency supplied to the (k+1) th driving touch line to the (2k) th driving touch line included in the second driving touch line group have phases corresponding to k codes that are distinguished from each other. or has a phase pattern corresponding to k distinct code sequences;
The k codes or k code strings displayed by the touch driving signals of the first frequency and the k codes or k code strings displayed by the touch driving signals of the second frequency correspond to each other. touch system.
According to claim 1,
The touch driving signals of the first frequency supplied to the first driving touch line group have k first signal waveforms;
The touch driving signals of the second frequency supplied to the second driving touch line group have k second signal waveforms;
The phase patterns of the k kinds of first signal waveforms and the phase patterns of the k kinds of second signal waveforms correspond to each other.
According to claim 1,
A plurality of sensing touch lines crossing the plurality of driving touch lines are further disposed on the touch panel;
The touch circuit,
a first touch circuit electrically connected to the plurality of driving touch lines and a second touch circuit electrically connected to the plurality of sensing touch lines;
The second touch circuit,
A plurality of preamplifiers corresponding to the plurality of sensing touch lines, a plurality of analog-to-digital converters corresponding to and electrically connected to the plurality of preamplifiers, and a plurality of frequency analyzers electrically connected to the plurality of analog-to-digital converters; ,
Each of the plurality of preamplifiers,
A first input terminal receiving an input signal, a second input terminal electrically connected to a corresponding sensing touch line, and an output terminal electrically connected to a corresponding analog-to-digital converter;
Based on the frequency analysis result data output from each of the plurality of frequency analyzers and phase information or code information for distinguishing the touch driving signals having the first frequency from each other or distinguishing the touch driving signals having the second frequency from each other , A touch system further comprising a touch controller for sensing a touch.
According to claim 6,
The touch system is configured to generate mutual capacitances between the plurality of driving touch lines and the plurality of sensing touch lines by applying the touch driving signal to the plurality of driving touch lines.
According to claim 6,
The input signal is a DC voltage touch system.
According to claim 8,
The DC voltage is a voltage lower than the operating voltage of the touch circuit.
According to claim 6,
The input signal is a sine wave signal.
According to claim 10,
The input signal is a sine wave signal having a third frequency different from frequencies of touch driving signals supplied to the plurality of driving touch lines.
According to claim 10,
When the input signal is a sine wave signal, the input signal is a touch driving signal that causes self-capacitance to be generated in a corresponding sensing touch line.
According to claim 6,
The second touch circuit,
Further comprising a plurality of driving amplifiers corresponding to the plurality of preamplifiers,
Each of the plurality of driving amplifiers includes a driving input terminal to which a driving signal is input and a driving output terminal electrically connected to a corresponding second input terminal of the preamplifier.
According to claim 1,
A plurality of sensing touch lines crossing the plurality of driving touch lines are further disposed on the touch panel;
The touch circuit,
a first touch circuit electrically connected to the plurality of driving touch lines;
A second touch circuit electrically connected to the plurality of sensing touch lines;
The touch system of claim 1 , wherein the first touch circuit includes a plurality of driving amplifiers outputting the touch driving signals to the plurality of driving touch lines.
According to claim 14,
The first touch circuit,
A plurality of preamplifiers corresponding to the plurality of driving amplifiers, a plurality of analog-to-digital converters corresponding to and electrically connected to the plurality of preamplifiers, and a plurality of frequency analyzers corresponding to and electrically connected to the plurality of analog-to-digital converters. include,
Each of the plurality of preamplifiers,
A touch system comprising a first input terminal receiving an input signal, a second input terminal electrically connected to a corresponding drive output terminal of a driving amplifier, and an output terminal electrically connected to a corresponding analog-to-digital converter.
According to claim 1,
The touch system of claim 1 , wherein a time required to determine whether there is a touch or touch coordinates in all areas of the touch panel is in inverse proportion to a frequency difference between the first frequency and the second frequency.
a first touch circuit electrically connected to a plurality of driving touch lines disposed on the touch panel; and
a second touch circuit disposed on the touch panel and electrically connected to a plurality of sensing touch lines crossing the plurality of driving touch lines;
The plurality of driving touch lines,
A first driving touch line group including a 1 th driving touch line to a k th driving touch line, and a second driving touch line group including a (k+1) th driving touch line to a (2k) th driving touch line And, k is a natural number greater than or equal to 2,
The first touch circuit,
supplying touch driving signals of a first frequency to the first driving touch line group;
supplying touch driving signals of a second frequency different from the first frequency to the second driving touch line group;
The touch driving signals of the first frequency supplied to each of the 1st driving touch line to the k th driving touch line included in the first driving touch line group are distinguished from each other according to a phase or code;
The touch driving signals of the second frequency supplied to each of the (k+1) th driving touch line to the (2k) th driving touch line included in the second driving touch line group are distinguished from each other according to a phase or code,
The touch driving signals of the first frequency supplied to the 1st driving touch line to the k th driving touch line included in the first driving touch line group have phase patterns corresponding to the k code strings that are distinguished from each other,
The k code sequences include k digit codes,
The k digit code included in one of the k code strings,
Among the touch drive signals of the first frequency, at least one touch drive signal of the first frequency corresponding to the one code string exhibits a normal-phase relationship with the touch drive signal of the first frequency corresponding to at least one other code string. At least one anti-phase code exhibiting an anti-phase relationship with the normal-phase code;
The touch driving signals of the second frequency supplied to the (k+1) th driving touch line to the (2k) th driving touch line included in the second driving touch line group correspond to the k code strings that are distinguished from each other. have a phase pattern,
The k code sequences distinguishing the touch driving signals of the second frequency from each other include the k digit codes;
The k digit code included in one code sequence among the k code sequences for distinguishing the touch driving signals of the second frequency from each other,
Among the touch driving signals of the second frequency, at least one touch driving signal of the second frequency corresponding to the one code string exhibiting a normal-phase relationship with the touch driving signal of the second frequency corresponding to at least one other code string A touch circuit including at least one anti-phase code representing an anti-phase relationship with a normal-phase code.
According to claim 17,
A touch driving signal of the first frequency supplied to one of the first driving touch line to the k-th driving touch line included in the first driving touch line group, and (k+1) included in the second driving touch line group. The touch driving signal of the second frequency supplied to one of the )th driving touch line to the (2k)th driving touch line corresponds to a phase or code.
According to claim 17,
The k codes or k code strings displayed by the touch driving signals of the first frequency and the k codes or k code strings displayed by the touch driving signals of the second frequency correspond to each other. touch circuit.
According to claim 17,
The touch driving signals of the first frequency supplied to the first driving touch line group have k first signal waveforms;
The touch driving signals of the second frequency supplied to the second driving touch line group have k second signal waveforms;
The phase patterns of the k kinds of first signal waveforms and the phase patterns of the k kinds of second signal waveforms correspond to each other.
According to claim 19,
The second touch circuit,
A plurality of preamplifiers corresponding to the plurality of sensing touch lines, a plurality of analog-to-digital converters corresponding to and electrically connected to the plurality of preamplifiers, and a plurality of frequency analyzers electrically connected to the plurality of analog-to-digital converters; ,
Each of the plurality of preamplifiers,
A first input terminal receiving an input signal, a second input terminal electrically connected to a corresponding sensing touch line, and an output terminal electrically connected to a corresponding analog-to-digital converter;
Based on the frequency analysis result data output from each of the plurality of frequency analyzers and phase information or code information for distinguishing the touch driving signals having the first frequency from each other or distinguishing the touch driving signals having the second frequency from each other , A touch circuit further comprising a touch controller for sensing a touch.
According to claim 21,
The input signal is a DC voltage touch circuit.
According to claim 21,
The input signal is a sine wave signal touch circuit.
According to claim 23,
The input signal is a sine wave signal having a third frequency different from frequencies of touch driving signals supplied to the plurality of driving touch lines.
According to claim 17,
The first touch circuit,
and a plurality of driving amplifiers outputting the touch driving signals to the plurality of driving touch lines.
According to claim 25,
The first touch circuit,
A plurality of preamplifiers corresponding to the plurality of driving amplifiers, a plurality of analog-to-digital converters corresponding to and electrically connected to the plurality of preamplifiers, and a plurality of frequency analyzers corresponding to and electrically connected to the plurality of analog-to-digital converters. include,
Each of the plurality of preamplifiers includes a first input terminal receiving an input signal, a second input terminal electrically connected to a driving output terminal of a corresponding driving amplifier, and an output terminal electrically connected to a corresponding analog-to-digital converter,
Based on the frequency analysis result data output from each of the plurality of frequency analyzers and phase information or code information for distinguishing the touch driving signals having the first frequency from each other or distinguishing the touch driving signals having the second frequency from each other , A touch circuit further comprising a touch controller for sensing a touch.
a touch panel on which a plurality of touch electrodes are disposed; and
A touch circuit for supplying a touch driving signal to all or part of the plurality of touch electrodes;
The plurality of touch electrodes include a first touch electrode group including k touch electrodes and a second touch electrode group including k different touch electrodes, where k is a natural number greater than or equal to 2;
The touch circuit,
supplying touch driving signals of a first frequency to the first touch electrode group;
Supplying touch driving signals of a second frequency different from the first frequency to the second touch electrode group;
The touch driving signals of the first frequency supplied to the k touch electrodes in the first touch electrode group are distinguished from each other by a phase or code,
The touch driving signals of the second frequency supplied to the k touch electrodes in the second touch electrode group are distinguished from each other by a phase or code,
The touch driving signals of the first frequency supplied to the first touch electrode group including the k touch electrodes have phase patterns corresponding to the k code strings that are distinguished from each other,
The k code sequences include k digit codes,
The k digit code included in one of the k code strings,
Among the touch drive signals of the first frequency, at least one touch drive signal of the first frequency corresponding to the one code string exhibits a normal-phase relationship with the touch drive signal of the first frequency corresponding to at least one other code string. At least one anti-phase code exhibiting an anti-phase relationship with the normal-phase code;
The touch driving signals of the second frequency supplied to the second touch electrode group including the k different touch electrodes have phase patterns corresponding to the k code strings that are distinguished from each other,
The k code sequences distinguishing the touch driving signals of the second frequency from each other include the k digit codes;
The k digit code included in one code sequence among the k code sequences for distinguishing the touch driving signals of the second frequency from each other,
Among the touch driving signals of the second frequency, at least one touch driving signal of the second frequency corresponding to the one code string exhibiting a normal-phase relationship with the touch driving signal of the second frequency corresponding to at least one other code string A touch display device comprising at least one anti-phase code representing an anti-phase relationship with a normal-phase code.
In the touch sensing method,
supplying a touch driving signal to all or part of a plurality of driving touch lines disposed on the touch panel; and
Sensing a touch through all or part of a plurality of sensing touch lines disposed on the touch panel;
The plurality of driving touch lines,
a first driving touch line group including k driving touch lines and a second driving touch line group including k driving touch lines, where k is a natural number equal to or greater than 2;
The touch driving signals supplied to the first driving touch line group and the touch driving signals supplied to the second driving touch line group are distinguished from each other by frequency,
The touch driving signals supplied to the first driving touch line group are distinguished from each other by phase or code,
The touch driving signals supplied to the second driving touch line group are distinguished from each other by phase or code,
The touch driving signals supplied to the first driving touch line group have a first frequency and have a phase pattern corresponding to k different code strings,
The k code sequences include k digit codes,
The k digit code included in one of the k code strings,
Among the touch drive signals of the first frequency, at least one touch drive signal of the first frequency corresponding to the one code string exhibits a normal-phase relationship with the touch drive signal of the first frequency corresponding to at least one other code string. At least one anti-phase code exhibiting an anti-phase relationship with the normal-phase code;
The touch driving signals supplied to the second driving touch line group have a second frequency and have a phase pattern corresponding to the k code strings that are distinguished from each other,
The k code sequences distinguishing the touch driving signals of the second frequency from each other include the k digit codes;
The k digit code included in one code sequence among the k code sequences for distinguishing the touch driving signals of the second frequency from each other,
Among the touch driving signals of the second frequency, at least one touch driving signal of the second frequency corresponding to the one code string exhibiting a normal-phase relationship with the touch driving signal of the second frequency corresponding to at least one other code string A touch sensing method comprising at least one anti-phase code representing an anti-phase relationship with a normal-phase code.
According to claim 28,
Prior to the sensing step,
The touch sensing method further comprises supplying another touch driving signal to all or part of the plurality of sensing touch lines.
According to claim 29,
Touch driving signals supplied to the first driving touch line group have a first frequency;
Touch driving signals supplied to the second driving touch line group have a second frequency different from the first frequency;
The touch sensing method of claim 1 , wherein other touch driving signals supplied to all or part of the plurality of sensing touch lines have a third frequency different from the first frequency and the second frequency.

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