KR101879654B1 - A method for reducing power consumption of a touch input sensing device at a stand-by mode and the input sensing device - Google Patents

Abstract

The present invention provides a technique capable of reducing a power usage amount in a touch input standby mode of a touch input detecting device. The touch input detecting device providing the touch input standby mode and a touch input operation mode comprises: a plurality of electrodes; a standby mode detecting circuit module; a second switch part connected to the plurality of electrodes and the standby mode detecting circuit module; and a calculation process and driving control part forming an integrated electrode by connecting the plurality of electrodes to each other in the touch input standby mode, and controlling the second switch part so as to connect the integrated electrode to the standby mode detecting circuit module.

Description

[0001] The present invention relates to a method of reducing power consumption of a touch input sensing device in a standby mode, and a method of reducing the power consumption of the touch input sensing device at a stand-

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic apparatus, and more particularly to a touch input sensing apparatus which is a user input means of a user apparatus. More particularly, the present invention relates to a method for reducing the power consumption of the touch input sensing device in a standby mode in which the user is not using the user equipment, and a touch input sensing device therefor.

The portable user device may be connected to a touch input sensing device as a user input device for the user. Alternatively, the touch input sensing device may be installed in the user equipment. The touch input sensing device may provide a planar input area that is wider than an area of the fingertip. The touch input sensing device is capable of detecting whether or not user input has been performed and / or determining the coordinates at which the user input is made in the input area.

Various methods can be adopted as the operating principle of the touch input sensing device. The touch input sensing device may be implemented by a well-known capacitive sensing method. For the capacitive sensing method, the touch input sensing device may include a plurality of transparent or opaque sensing electrodes. In order to detect coordinates of a point at which a touch input occurs in the input region, a plurality of capacitances whose values can be changed by the sensing electrodes must be continuously measured. A plurality of sensing circuit modules may be connected to the plurality of sensing electrodes for measuring the plurality of capacitances. At this time, in order to continuously measure the plurality of capacitances, the plurality of sensing circuit modules must continuously operate, and as a result, the power consumption may increase in proportion to the number of sensing circuit modules.

Meanwhile, in the present specification, a mode that operates by determining that there is no user input may be referred to as a touch input standby mode of the user device or the touch input sensing device. And a mode that operates to determine the coordinates at which user input occurs in the sensing area, assuming that the user input is present or occurs in the near future, may be referred to as the touch input operation mode of the user device or the touch input sensing device .

In many cases, in a state in which the user equipment is turned on, the time in which the touch input standby mode exists may be longer than the time in which the touch input operation mode is operated. If the manner in which the touch input sensing device operates in the touch input standby mode is the same as that in the touch input operation mode, the power consumption rate in the touch input standby mode is determined by the power consumption rate in the touch input operation mode, Will be the same or similar. In this case, it is necessary to reduce the power consumption generated in the touch input standby mode in which the calculation of the coordinates of the user input is not required.

The present invention provides a technique for reducing power consumption in a touch input standby mode of a touch input sensing device.

The user device can switch to the touch input operation mode when it is determined that the user input is started in the touch input standby mode. At this time, in order to detect whether or not the user input is started, it is not necessary to specifically determine the coordinates at which the user input occurs in the input region, and it is sufficient to determine only whether or not the input occurred in any of the input regions.

In the method according to one aspect of the present invention, when the user equipment is in the touch input standby mode, all of the plurality of sensing electrodes are connected to each other as one integrated sensing electrode, or at least one of the plurality of sensing electrodes And at least a part of the sensing electrodes connected to each other is used as one integrated sensing electrode. One idle mode sensing circuit module 30_T may be connected to the one integrated sensing electrode and the one idle mode sensing circuit module 30_T may control the size of a capacitance that can be changed by the single integrated sensing electrode .

According to an aspect of the present invention, a touch input sensing apparatus that provides a touch input standby mode and a touch input operation mode can be provided. The touch input sensing device includes a plurality of electrodes, a standby mode sensing circuit module, a second switch connected to the plurality of electrodes and the standby mode sensing circuit module, And an operation processing unit and a drive control unit for controlling the second switch unit to connect the integrated electrode to the standby mode sensing circuit module.

The plurality of electrodes may include a plurality of row electrodes formed on the first layer of the touch screen panel and a plurality of row electrodes formed on the second layer of the touch screen panel, A plurality of column electrodes, or the plurality of row electrodes and the plurality of column electrodes.

The plurality of electrodes may include a plurality of row electrodes formed on the first layer of the touch screen panel and a plurality of row electrodes formed on the second layer of the touch screen panel, And the operation processing and drive control unit may control the TX driver to apply a pulse train to one or more column electrodes of the plurality of column electrodes in the touch input standby mode.

In this case, the apparatus further includes a plurality of sensing circuit modules, and a first switch unit connected to the plurality of electrodes and the plurality of sensing circuit modules, wherein the operation processing and drive control unit is configured to, The first switch unit may be controlled to connect each of the electrodes to one of the plurality of sensing circuit modules.

At this time, in the touch input standby mode, the arithmetic processing and driving control unit may control the first switch unit such that not all of the plurality of electrodes are connected to any of the plurality of sensing circuit modules.

At this time, in the touch input operation mode, the operation processing and driving control unit may control the second switch unit such that not all of the plurality of electrodes are connected to the input terminal of the standby mode sensing circuit module.

Wherein the input terminal of the standby mode sensing circuit module and the output terminal of the compensation circuit are connected together to the integrated electrode, and the calculation processing and drive control unit controls the input and output terminals of the standby mode sensing circuit module The direction switching of the first current flowing through the terminal and the switching of the direction of the second current flowing through the output terminal of the compensation circuit are synchronized with each other.

Here, the compensation circuit includes an output terminal, a fourth current source, a fourth switch for connecting the fourth current source to the output terminal, a third current source, and a third switch for connecting the third current source to the output terminal Wherein an input terminal of the standby mode sensing circuit module is connected to the output terminal, and a rising edge of a third control signal for controlling the third switch, a first current flowing through the input terminal, Wherein the rising edge of the fourth control signal for controlling the fourth switch is synchronized with the first switching point at which the first current is switched from the second direction to the first direction, And can be synchronized at the time of conversion.

At this time, the compensation circuit includes a compensation capacitor (C _COMP ); An operational amplifier 300; And a second compensation circuit switch part (401) connected to the input terminal of the operational amplifier to selectively supply two different input voltages, wherein one terminal of the compensation capacitor is connected to the integrated electrode, Wherein the other terminal of the first operational amplifier is connected to the output terminal of the operational amplifier, the standby mode sensing circuit module includes a first operational amplifier and a second operational amplifier, A second reference voltage is applied to the non-inverting input terminal of the second operational amplifier, and the integrated electrode is connected to the inverting input terminal of the first operational amplifier and the inverting input terminal of the second operational amplifier And the potential of the one terminal of the compensation capacitor is selectively connected to the standby mode detection circuit Wherein the voltage of the other terminal of the compensation capacitor is controlled by the voltage of the output terminal of the operational amplifier and the operations of the second compensation circuit switch unit and the sensing circuit switch unit are synchronized with each other, The change of the polarity of the voltage across the compensation capacitor may be synchronized with the operation of the second compensation circuit switch unit and the sensing circuit switch unit.

In this case, the standby mode sensing circuit module is distinguished from the plurality of sensing circuit modules.

The second standby mode sensing circuit module may further include a second standby mode sensing circuit module, wherein the second standby mode sensing circuit module is distinguished from the plurality of sensing circuit modules.

The second standby mode sensing circuit module may further include a second standby mode sensing circuit module, and the second standby mode sensing circuit module may be one of the plurality of sensing circuit modules.

Here, the standby mode sensing circuit module may be any one of the plurality of sensing circuit modules.

According to an aspect of the present invention, there is provided a display device including a plurality of electrodes, a standby mode sensing circuit module, a second switch portion connected to the plurality of electrodes and the standby mode sensing circuit module, It is possible to provide a method of executing a touch input standby mode in a touch input sensing apparatus that provides a standby mode and a touch input operation mode. In this case, the operation processing and driving control unit may include connecting the plurality of electrodes to each other to form an integrated electrode in the touch input standby mode, and connecting the integrated electrode to the standby mode sensing circuit module .

According to the present invention, it is possible to provide a technique for reducing power consumption in the touch input standby mode of the touch input sensing device.

FIG. 1 shows a configuration of a touch input sensing apparatus according to a comparative example.
FIG. 2 illustrates a configuration of a touch input sensing apparatus according to an embodiment of the present invention.
FIG. 3 is a view for explaining the operation principle in the touch input standby mode when the touch input sensing apparatus shown in FIG. 2 operates in a mutual capacitive manner.
FIG. 4 is a view for explaining the operation principle in the touch input standby mode when the touch input sensing apparatus modified from the touch input sensing apparatus shown in FIG. 2 operates in a capacitive manner.
FIG. 5 is a view for explaining an embodiment of the idle mode sensing circuit module 30_T when the touch input sensing apparatus modified from the touch input sensing apparatus shown in FIG. 2 operates in a capacitive manner.
6 is a timing chart showing an operation method of the standby mode sensing circuit module 30_T shown in FIG.
FIG. 7 illustrates a compensation circuit for reducing the capacitance of the integrated electrode viewed from the input stage of the standby mode sensing circuit module, according to an embodiment of the present invention.
FIG. 8 is a timing diagram for explaining the time-dependent operational characteristics of the stray capacitance compensating circuit provided according to the first embodiment of the present invention. FIG.
FIG. 9 shows an example of the internal configuration of the charging current source and the discharging current source shown in FIG. 7 in detail.
10 illustrates an example of a compensation circuit for reducing the value of the capacitance of the integrated electrode viewed from the input of the standby mode sensing circuit module, according to another embodiment of the present invention.
11 is a timing diagram for explaining the time-dependent operation characteristics of the stray capacitance compensation circuit provided according to the third embodiment of the present invention.
FIG. 12 shows an example of a configuration of a touch input sensing apparatus according to an embodiment of the present invention, in which only one standby mode sensing circuit module is provided and the standby mode sensing circuit module is distinguished from the sensing circuit modules.
13 shows an example of a configuration of a touch input sensing apparatus according to another embodiment of the present invention, in which two or more standby mode sensing circuit modules are provided and each standby mode sensing circuit module is distinguished from the sensing circuit modules .
FIG. 14 shows an example of the configuration of a touch input sensing apparatus according to another embodiment of the present invention, in which only one standby mode sensing circuit module is provided, and a specific sensing circuit module serves as the standby mode sensing circuit module .
FIG. 15 illustrates an example of a configuration of a touch input sensing apparatus according to another embodiment of the present invention, in which two or more standby mode sensing circuit modules are provided, and the first standby mode sensing circuit module is distinguished from the sensing circuit modules However, the second standby mode sensing circuit module may serve as a specific sensing circuit module.
FIG. 16 is a view showing the relationship between the integrated electrode shown in FIG. 5 and N row electrodes and M column electrodes included in the touch screen panel.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein, but may be implemented in various other forms. The terminology used herein is for the purpose of understanding the embodiments and is not intended to limit the scope of the present invention. Also, the singular forms as used below include plural forms unless the phrases expressly have the opposite meaning.

FIG. 1 shows a configuration of a touch input sensing apparatus according to a comparative example.

The touch input sensing apparatus 101 includes a touch screen panel 10, a first switch unit 120, a first AFA unit 130, a first TX driving unit 140, and a first calculation processing and driving control unit 150 can do.

The touch screen panel 10 may include N row electrodes Y1 to YN and M column electrodes X1 to XM. Any row electrode and any column electrode may be disposed in different layers, and may be insulated from each other and intersect one another at one point. The arbitrary first row electrode and the arbitrary second row electrode may extend in the row direction, and may be arranged parallel to each other and spaced apart from each other.

The first TX driver 140 may apply a driving pulse having a predetermined pattern to each of the column electrodes. For this purpose, the respective column electrodes may be connected to the first TX driver 140.

The first 1AFE unit 130 may include L sensing circuit modules 30_1 through 30_L. Here, for example, L may be a natural number of 1 to M + N. Each sensing circuit module may include operational amplifiers OA1 to OAL, and feedback capacitors CS1 to CSL. The configuration of each sensing circuit module can be provided in various ways by the prior art. The M column electrodes and / or the N row electrodes may be connected to any one of the sensing circuit modules. Although only one operational amplifier is shown for each sensing circuit module, this is for convenience, and in some embodiments more than two operational amplifiers may be included in each sensing circuit module.

When the sensing circuit module is implemented as a chip, the sensing circuit module can occupy a certain area or more. Therefore, there is a problem that the size of the sensing circuit module increases as the number of sensing circuit modules increases. Therefore, instead of reducing the number of sensing circuit modules, a single sensing circuit module may be connected to several sensing electrodes in a time-division manner, so that they can be used.

The first switch unit 120 may be configured to continuously or selectively connect the row electrodes and / or the column electrodes to any one of the L sense circuit modules.

The first switch unit 120 may include switches SX1 to XX of a first set (set X) for selectively connecting the respective column electrodes to any one of the L sense circuit modules 30_1 to 30_L, To SXM).

The first switch unit 120 may include, for example, a second set (set Y) switches (not shown) for selectively connecting the respective row electrodes to any one of the L sense circuit modules 30_1 to 30_L SY1 to SYN).

The first calculation processing and drive control unit 150 can control the first switch unit 120, the first AFA unit 130, and the first TX drive unit 140.

FIG. 2 illustrates a configuration of a touch input sensing apparatus according to an embodiment of the present invention.

The touch input sensing apparatus 1 may include a touch screen panel 10, a switch unit 20, an AFE unit 30, a TX driving unit 40, and an arithmetic processing and driving control unit 50.

The touch screen panel 10, the switch unit 20, the AFE unit 30, the TX driver 40, and the calculation processing and drive control unit 50 of the touch input sensing apparatus 1 shown in Fig. The touch screen panel 10, the first switch unit 120, the first AFE unit 130, the first TX drive unit 140, and the first operation processing and drive control unit (not shown) of the touch input sensing apparatus 101 shown in FIG. 150).

The touch screen panel 10 may include N row electrodes Y1 to YN and M column electrodes X1 to XM. Any row electrode and any column electrode may be disposed in different layers, and may be insulated from each other and intersect one another at one point. The arbitrary first row electrode and the arbitrary second row electrode may extend in the row direction, and may be arranged parallel to each other and spaced apart from each other.

The TX driver 40 may apply a driving pulse having a predetermined pattern to each of the column electrodes. To this end, each column electrode may be coupled to a TX driver 40.

The AFE unit 30 may include L sensing circuit modules 30_1 to 30_L. Here, for example, L may be a natural number of 1 to M + N. Each sensing circuit module may include operational amplifiers OA1 to OAL, and feedback capacitors CS1 to CSL. The configuration of each sensing circuit module can be provided in various ways by the prior art. The M column electrodes and / or the N row electrodes may be connected to any one of the sensing circuit modules. Although only one operational amplifier is shown for each sensing circuit module, this is for convenience, and in some embodiments more than two operational amplifiers may be included in each sensing circuit module.

In addition, the AFE unit 30 may include a standby mode sensing circuit module 30_T. The standby mode sensing circuit module 30_T may include an operational amplifier OAT, and a feedback capacitor CST. The configuration of the standby mode sensing circuit module 30_T may be provided in various manners by a conventional technique. Some or all of the M column electrodes and / or the N row electrodes may be connected together and connected to the input terminal of the standby mode sensing circuit module 30_T.

When the sensing circuit modules 30_1 to 30_L and the standby mode sensing circuit module 30_T are implemented as chips, the area occupied by the sensing circuit modules 30_1 to 30_L can be larger than a certain level. Therefore, as the number of sensing circuit modules increases, There is a problem. Therefore, instead of reducing the number of sensing circuit modules, a single sensing circuit module may be connected to several sensing electrodes in a time-division manner, so that they can be used.

The switch unit 20 may include a first switch unit 120 and a second switch unit 220.

The first switch 120 may be configured such that the row electrodes and / or the column electrodes are connected to either one of the L sense circuit modules in the touch input operation mode, And may be configured to selectively connect to one.

In this case, in a preferred embodiment, the first switch unit 120 may be configured such that when the user device or the touch input sensing device is in the touch input standby mode, both the row electrodes and the column electrodes And may not be connected to any of the circuit modules 30_1 to 30_L.

For this purpose, the first switch unit 120 may include, for example, a first set (set X) for selectively connecting the respective column electrodes to any one of the L sense circuit modules 30_1 to 30_L And switches SX1 to SXM.

The first switch unit 120 may include, for example, a second set (set Y) switches (not shown) for selectively connecting the respective row electrodes to any one of the L sense circuit modules 30_1 to 30_L SY1 to SYN).

The second switch unit 220 connects the row electrodes and / or the column electrodes with each other to connect the row electrodes and / or the column electrodes to each other in the touch input sensing mode, And to an input terminal of the circuit module 30_T.

In this case, in a preferred embodiment, the second switch 220 is turned on when both the row electrodes and the column electrodes are in the touch input operation mode, And may not be connected to the input terminal of the circuit module 30_T.

To this end, the second switch unit 220 includes, for example, a third set (set TX) switches STX1 to STXM for connecting the respective column electrodes to the standby mode sense circuit module 30_T can do.

And the second switch portion 220 may include, for example, a fourth set (set TY) of switches STY1 to STYN for connecting the respective row electrodes to the standby mode sense circuit module 30_T have.

The calculation processing and drive control section 50 can control the switch section 20, the AFE section 30, and the TX drive section 40. [

The arithmetic processing and drive control section 50 is provided with the first set of switches, the second set of switches, the third set of switches, and the second set of switches so that the switch section 20 can perform the above- It is possible to control the operation of the fourth set of switches.

Also, in a preferred embodiment, the operation processing and drive control unit 50 controls the standby mode detection circuit module 30_T to not operate when the user device or the touch input sensing device is in the touch input operation mode, The L sensing circuit modules may be controlled to operate. In a preferred embodiment, the operation processing and drive control unit 50 controls the standby mode sensing circuit module 30_T to operate when the user equipment or the touch input sensing device is in the touch input standby mode, Lt; RTI ID = 0.0 > sensing module < / RTI >

3 and 4, the touch input sensing device 1 may operate in a mutual capacity mode or a capacitive mode. When operating in the mutual capacitance mode, the configurations of the standby mode sensing circuit module 30_T and the L sensing circuit modules 30_1 to 30_L have the same configuration as disclosed in Korean Patent No. 10-1544115 And the operation principle thereof may be the same as that disclosed in Korean Patent No. 10-1544115. Alternatively, when operating in the self-capacitance mode, the configurations of the standby mode sensing circuit module 30_T and the L sensing circuit modules 30_1 to 30_L may be the same as those disclosed in Korean Patent No. 10-1591293 And the operation principle thereof may be the same as that disclosed in Korean Patent No. 10-1591293.

FIG. 3 is a view for explaining the operation principle in the touch input standby mode when the touch input sensing apparatus shown in FIG. 2 operates in a mutual capacitive manner.

The N row electrodes Y1 to YN are connected to the L sense circuit modules when the user device or the touch input sensing device is in the touch input operation mode On the other hand, the M column electrodes X1 to XM may not be connected to the L sense circuit modules. At this time, the third set of switches and the fourth set of switches are all turned off, and the M column electrodes and the N row electrodes are not connected to the standby mode sense circuit module 30_T can do.

At this time, when the user device or the touch input sensing device is in the touch input standby mode, the switches STY1 to STYN of the fourth set (set TY) may connect the N row electrodes Y1 to YN to each other And may be connected to the standby mode sensing circuit module 30_T. And at this time, the first set of switches, the second set of switches, and the third set of switches may all be turned off. The TX driver 40 may apply a pulse train to only one of the M column electrodes X1 to XM or may apply a plurality of or all of the M column electrodes X1 to XM, The pulse train may be applied.

At this time, the configuration of the standby mode sensing circuit module 30_T and the L sensing circuit modules may have a configuration as disclosed in Korean Patent No. 10-1544115, for example.

FIG. 4 is a view for explaining the operation principle in the touch input standby mode when the touch input sensing apparatus modified from the touch input sensing apparatus shown in FIG. 2 operates in a capacitive manner.

The modified touch input sensing device 1 'may have the function of the TX driving unit 40 removed from the touch input sensing device 1.

The M column electrodes X1 to XM and the N row electrodes Y1 to YN are turned on when the user device or the touch input sensing device is in the touch input operation mode, All of which may be selectively coupled to the L sense circuit modules. At this time, the third set of switches and the fourth set of switches may all be turned off.

At this time, when the user equipment or the touch input sensing device is in the touch input standby mode, the switches STX1 to STXM of the third set (set TX) and the switches STY1 STYN may connect the M column electrodes X1 to XM and the N row electrodes Y1 to YN to the standby mode sensing circuit module 30_T. And at this time, the first set of switches, and the second set of switches can all be turned off.

At this time, the configuration of the standby mode sensing circuit module 30_T and the L sensing circuit modules may have a configuration as disclosed in Korean Patent No. 10-1591293, for example.

FIG. 5 is a view for explaining an embodiment of the idle mode sensing circuit module 30_T when the touch input sensing apparatus modified from the touch input sensing apparatus shown in FIG. 2 operates in a capacitive manner.

The standby mode sensing circuit module 30_T includes an input terminal IN as an input terminal and may include a first output terminal VOUT1 and a second output terminal VOUT2 as output terminals. The output terminal OUTT shown in FIG. 2 can output a difference value between a signal output from the first output terminal VOUT1 and a signal output from the second output terminal VOUT2. The input terminal IN shown in FIG. 5 may be connected to the integrated electrode 11 formed by connecting the M column electrodes X1 to XM and the N row electrodes Y1 to YN.

The M column electrodes X1 to XM and the N row electrodes Y1 to YN are not necessarily connected to each other in order to form the integrated electrode 11 in another embodiment of the present invention. This will be described later with reference to FIG. 12 to FIG.

The standby mode sensing circuit module 30_T may include a first operational amplifier OA1 and a second operational amplifier OA2.

The first reference voltage VREF_H may be applied to the noninverting input terminal of the first operational amplifier OA1 and the second reference voltage VREF_L may be applied to the non- inverting input terminal of the second operational amplifier OA2 have.

The inverting input terminal of the first operational amplifier OA1 is connected to the input terminal IN through the switch 61 and can be connected to the first reference voltage VREF_H via the switch 71. [ The inverting input terminal of the second operational amplifier OA2 is connected to the input terminal IN through the switch 62 and to the second reference voltage VREF_L via the switch 73. [

The output terminal of the first operational amplifier OA1 may be provided as the first output terminal VOUT1 and may be connected to the second reference voltage VREF_L via the switch 72. [ The output terminal of the second operational amplifier OA2 may be provided as the second output terminal VOUT2 and may be connected to the first reference voltage VREF_H via the switch 74. [

The output terminal and the inverting input terminal of the first operational amplifier OA1 may be connected to each other by the first integrating capacitor C _S1 . The output terminal and the inverting input terminal of the second operational amplifier OA2 can be connected to each other by the second integrating capacitor C _S2 .

The capacitance C _SELF is modeled by summing the sum of the 'sensing capacitance' formed between the integrated electrode 11 and the human finger and the floating capacitance formed between the integrated electrode 11 and any part of the user's equipment. If there is no human finger near the integrated electrode 11, the value of the 'sensing capacitance' may have a value close to 0 and the value of the capacitance C _SELF may have a value close to the floating capacitance .

6 is a timing chart showing an operation method of the standby mode sensing circuit module 30_T shown in FIG. In Fig. 6, the horizontal axis represents time.

The reset signal? _R is a kind of reset signal as a signal for controlling the on / off states of the switches 71, 72, 73,

The first control signal? ₁ is a signal for controlling the ON / OFF state of the switch 61.

The second control signal? ₂ is a signal for controlling the on / off state of the switch 62.

When the first control signal? ₁ , the second control signal? ₂ and the reset signal? _R have a high value, the corresponding switches are turned on and have a low value The corresponding switch is turned off.

The circuit portion including the two switches 61 and 62 may be defined as a sensing circuit switch portion 410 for controlling the directionality of the current flowing through the input terminal of the standby mode sensing circuit module 30_T. Current can flow in or out through the input terminal of the standby mode sensing circuit module 30_T according to the operation of the sensing circuit switch unit 410. [

In FIG. 6, the signal V _IN represents a voltage with respect to time of the input terminal _IN , and the magnitude of the signal V _IN when the first control signal? ₁ has a high value (ex VREF_H is larger than the magnitude (ex: VREF_L) of the signal V _IN when the second control signal? ₂ has a high value can be understood by the configuration of the circuit of FIG. 5 .

The magnitude of the potential at the first output terminal VOUT1 becomes the second reference voltage VREF_L when reset by the switches 71, 72, 73, And thereafter increases by a certain level every time the rising edge of the first control signal? ₁ is reached. The rising level may ideally be determined by the ratio of the magnitude of the capacitor C _SELF to the magnitude of the first integral capacitor C _S1 . The reason for this is that the current I _CSELF flowing through the capacitor C _SELF in the transition period according to the rising edge of the first control signal? _{1 on} the circuit structure of FIG. 5 is all _transmitted through the first integrating capacitor C _S1 It is because it flows.

The magnitude of the potential at the second output terminal VOUT2 becomes the first reference voltage VREF_H when reset by the switches 71, 72, 73, And then falls to a certain level every time the rising edge of the second control signal? ₂ is reached. At this time, the falling level can be ideally determined by the ratio of the magnitude of the capacitor C _SELF to the magnitude of the second integral capacitor C _S2 . The reason for this is that the current I _CSELF flowing through the capacitor C _SELF in the transition period according to the rising edge of the second control signal? _{2 on} the circuit structure of FIG. 5 is all _transmitted through the second integrating capacitor C _S2 It is because it flows.

The integrated electrode 11 is an electrode formed by connecting at least two or more of the M column electrodes X1 to XM and the N row electrodes Y1 to YN in parallel. Therefore, the capacitances and mutual capacities formed by the integrated electrodes 11 have values larger than the capacitances and mutual capacities formed by the respective column electrodes or row electrodes. As a result, the capacity of the feedback capacitor CST of the standby mode sensing circuit module 30_T connected to the integrated electrode 11 to charge the charges moving through the integrated electrode 11 is the same as that of one of the column electrodes It is preferable to design the feedback capacitors CS1, ..., CSL of the sensing circuit modules 30_1, ..., or 30_L connected to the row electrodes to be larger than the feedback capacitors CS1, ..., CSL. However, when the capacity of the feedback capacitor CST of the standby mode sensing circuit module 30_T is increased, a problem that the chip including the standby mode sensing circuit module 30_T increases in size occurs. Therefore, in an embodiment of the present invention, the standby mode sensing circuit module 30_T can perform a desired operation even when the increase amount of the capacity of the feedback capacitor CST of the standby mode sensing circuit module 30_T is limited A compensation circuit described later can be provided.

The value of the capacitance of the integrated electrode 11 viewed from the input terminal IN of the standby mode sensing circuit module 30_T may be a stray capacitance and a sensing capacitance C _TOUCH . At this time, the sensing capacitance C _TOUCH may be a value depending on whether the user inputs touch. The stray capacitance may have a constant value. If the electrical properties of other devices included in the user equipment change with time, the value of the stray capacitance may also change periodically or aperiodically with time.

7 is for explaining a compensation circuit for reducing the value of the capacitance of the integrated electrode 11 viewed from the input terminal of the standby mode sensing circuit module 30_T, according to an embodiment of the present invention.

In order to reduce the value of the capacitance of the integrated electrode 11 connected to the input terminal IN of the standby mode sensing circuit module 30_T is applied to the input terminal IN of the integrated electrode 11 and the standby mode sensing circuit module 30_T A stray capacitance compensation circuit 60 is connected. The stray capacitance compensation circuit 60 may hereinafter simply be referred to as a " compensation circuit ".

The current I _I enters from the integrated electrode 11 into the standby mode sensing circuit module 30_T and the current I _CQ from the integrated electrode 11 enters the stray capacitance compensation circuit 60 in FIG.

The stray capacitance compensation circuit 60 according to the embodiment of the present invention may have a structure as shown in Fig. 7 in order to make the current I _I and the current I _CQ have the same sign . The stray capacitance compensation circuit 60 is connected to the connection electrode 11 of the charging current source I _CHG 121, the discharging current source I _DCHG 122 and the charging current source 121 and the discharging current source 122, And a compensation circuit switch unit 400 for controlling the state of the switching device. The compensation circuit switch unit 400 may include a fourth switch SWL and a third switch SWH. The fourth switch SWL and the third switch SWH may be connected to the integrated electrode 11 and the standby mode sensing circuit module 30_T at the input terminal IN of the standby mode sensing circuit module 30_T.

The charging current source may be hereinafter referred to as a fourth current source, and the discharging current source may be referred to as a third current source.

The fourth switch SWL may connect the output terminal of the charge current source 121 to the input terminal IN in accordance with the fourth control signal? ₄ . The third switch SWH may connect the output terminal of the discharge current source 122 to the input terminal IN in accordance with the third control signal? ₃ .

The current I _CHG provided by the charge current source 121 may be a DC current as a charge compensation current or a current having a predetermined waveform. The current I _DCHG provided by the discharge current source 122 may be a DC current as a discharge compensation current or a current having a predetermined waveform.

The current I _CHG may be supplied from the stray capacitance compensation circuit 60 to the input terminal IN while the fourth switch SWL is kept on, and the amount of charge provided at this time may be given by Q _{COMP_CHG} as follows.

The current I _DCHG can be input from the input terminal IN to the stray capacity compensation circuit 60 while the third switch SWH is kept in the ON state and the amount of charge provided at this time is given by Q _{COMP_DCHG} .

[Equation 1]

The stray capacitance compensation circuit 60 is a circuit that makes the current I _I and the current I _CQ have the same sign. Therefore, the current I _I and the current I _CQ may all have a positive value or both may have a negative value. In other words, if there is no stray capacity compensation circuit 60, part of the current to be input / output to / from the standby mode detection circuit module 30_T may be input / output to the stray capacity compensation circuit 60 because the stray capacity compensation circuit 60 is provided . As a result, the amount of current input / output to / from the standby mode sensing circuit module 30_T decreases, and thus the value of the capacitance of the integrated electrode 11 viewed from the input terminal IN of the standby mode sensing circuit module 30_T becomes C _{COMP_CHG} Or C _{COMP_DCHG} . In the case of the above circuit structure, when the touch input to the integrated electrode 11 is performed and the value of the sensing capacitance C _TOUCH becomes a value other than 0, the change in the sensing capacitance C _TOUCH is sensed more sensitively .

In the circuit shown in Fig. 7, the sensing circuit switch unit 410 and the compensation circuit switch unit 400 operate in synchronization with each other, so that the current I _I input to the standby mode sensing circuit module 30_T and the stray capacitance (I.e., signs) of the current I _CQ input to the compensation circuit 60 are equal to each other.

Preferably, the third switch SWH and the fourth switch SWL in the compensation circuit switch unit 400 are not in the ON state at the same time. For example, the third control signal? ₃ for controlling on / off of the third switch SWH may have the same pattern as the second control signal? ₂ of FIG. 6, The fourth control signal? ₄ for controlling / off can have the same pattern as the first control signal? _{1 in} FIG. That is, the rising edge of the third control signal? ₃ can be synchronized with the rising edge of the second control signal? ₂ , and the rising edge of the fourth control signal? ₄ can be synchronized with the rising edge of the first control signal? ₁ ≪ / RTI >

7, the touch input sensing device according to an embodiment of the present invention may include a standby mode sensing circuit module 30_T, a stray capacitance compensation circuit 60, and an integrated electrode 11 . The input terminal of the standby mode sensing circuit module 30_T and the output terminal of the stray capacitance compensating circuit 60 may be connected to the integrated electrode 11 together. At this time, the standby mode sensing circuit module 30_T may include a sensing circuit switch unit 410 for controlling the sign of the current I _I input to the input terminal of the standby mode sensing circuit module 30_T. The stray capacitance compensation circuit 60 may include a compensation circuit switch unit 400 that operates in synchronization with the sensing circuit switch unit 410. The compensation circuit switch unit 400 is synchronized with the sensing circuit switch unit 410 so that the sign of the current I _I inputted to the input terminal of the standby mode sensing circuit module 30_T and the sign of the current I _I input to the output of the stray capacitance compensating circuit 60 So that the sign of the current I _CQ input to the terminal is synchronized with time. Here can mean that the sign of the current (I _I) and the current (I _CQ) To be synchronized with time, changes also the sign of the current (I _CQ) at the moment the sign of the current (I _I) changes.

At this time, in the first embodiment according to the present invention, the sign of the current I _I and the current I _CQ may be the same at a specific point in time.

FIG. 8 is a timing diagram for explaining the time-dependent operational characteristics of the stray capacitance compensating circuit provided according to the first embodiment of the present invention. FIG.

7 and 8 together, after the reset signal? _R for controlling the on / off states of the switches 71, 72, 73, 74 is changed from the on state to the off state, The signal? ₃ and the fourth control signal? ₄ have the following characteristics.

That is, the third control signal (Φ ₃₎ a second control signal (Φ ₂₎ the first control signal (Φ ₁₎ which is a rise of and synchronized with the rising edge, the fourth control signal (Φ ₄₎ in which the increase of the Synchronized to the rising edge.

At this time, the third on-state duration of the control signal (Φ ₃₎ has a second can be shorter than the on-state duration of the control signal (Φ _2), ON-state duration of the fourth control signal (Φ ₄₎ is first State duration of the control signal? ₁ .

The change of the voltage V _IN at the input terminal IN can be synchronized with the first control signal? ₁ and the second control signal? ₂ .

VOUT1 and VOUT2 shown by a solid line in FIG. 8 indicate outputs when the stray capacitance compensation circuit 60 according to an embodiment of the present invention shown in FIG. 7 is used, and VOUT1 and VOUT2 shown by dotted lines in FIG. 7 shows an output when the stray capacitance compensation circuit 60 according to the embodiment of the present invention shown in Fig. 7 is not used. 8, in the second embodiment according to the present invention, the rising edge of the third control signal? ₃ is synchronized with the rising edge of the first control signal? ₁ , and the fourth control signal? ? ₄ can be synchronized to the rising edge of the second control signal? ₂ .

The first embodiment has the effect of reducing the capacitance of the integrated electrode viewed from the input terminal of the standby mode sensing circuit module 30_T while the second embodiment described above has the effect of reducing the capacitance of the integrated electrode viewed from the input terminal of the standby mode sensing circuit module 30_T, So that the capacitance of the integrated electrode can be increased. Therefore, the above-described first embodiment increases the sensitivity of the standby mode sensing circuit module 30_T, and the second embodiment has the effect of reducing the sensitivity of the standby mode sensing circuit module 30_T.

FIG. 9 shows an example of the internal configuration of the charging current source and the discharging current source shown in FIG. 7 in detail.

The charging current source 121 and the discharging current source 122 may have a configuration corresponding to each other. Hereinafter, the charging current source and the discharging current source may be collectively referred to as the current sources 121 and 122.

The charging current source 121 (= the fourth current source) includes a first transistor M1, a second transistor M2, a third transistor M3, and a third transistor M3 whose sources are connected to a first potential (driving potential VDD) 4 < / RTI > transistor M4. And a current source IREF1 connected to the drain of the first transistor M1.

The drain of the first transistor M1 may be connected to the gates of the first transistor M1, the second transistor M2, the third transistor M3, and the fourth transistor M4.

The currents flowing through the drains of the second transistor M2, the third transistor M3 and the fourth transistor M4 can constitute at least part or all of the output current I _CHG of the charge current source 121 have,

The charge current source 121 includes a fifth transistor M5 whose source is connected to the drain of the second transistor M2, a sixth transistor M6 whose source is connected to the drain of the third transistor M3, And a seventh transistor M7 connected to the drain of the fourth transistor M4.

At this time, the magnitude and shape of the output current of the charge current source 121 may be determined by on / off states of the fifth transistor M5, the sixth transistor M6, and the seventh transistor M7.

The ON / OFF states of the fifth transistor M5, the sixth transistor M6, and the seventh transistor M7 can be controlled by the control signal unit 125. [

The discharging current source 122 (= the third current source) includes a sixteenth transistor M16, a fifteenth transistor M15, a fourteenth transistor M14, and a seventh transistor M14 connected to a second potential (reference potential VEE) 13 < / RTI > transistor M13. And a current source IREF2 connected to the drain of the sixteenth transistor M16.

The drain of the sixteenth transistor M16 may be connected to the gates of the sixteenth transistor M16, the fifteenth transistor M15, the fourteenth transistor M14 and the thirteenth transistor M13.

The currents flowing through the drains of the fifteenth transistor M15, the fourteenth transistor M14 and the thirteenth transistor M13 can constitute at least part or all of the output current I _DCHG of the discharge current source 122 have,

The discharging current source 122 includes a twelfth transistor M12 having a source connected to the drain of the fifteenth transistor M15, an eleventh transistor M11 having a source connected to the drain of the fourteenth transistor M14, And a tenth transistor M10 connected to the drain of the thirteenth transistor M13.

At this time, the magnitude and shape of the output current of the discharge current source 122 may be determined by the ON / OFF states of the twelfth transistor M12, the eleventh transistor M11, and the tenth transistor M10.

The ON / OFF states of the twelfth transistor M12, the eleventh transistor M11, and the tenth transistor M10 can be controlled by the control signal unit 125. [

The control signal unit 125 can receive the first control signal? ₁ and the second control signal? ₂ via the terminals TE1 and TE2. Control signal 125, a first control signal (Φ ₁₎ and a second control signal based on (Φ _2), a third control signal (Φ ₃₎ and the fourth control signal (Φ ₄₎ illustrated in Figure 8 And outputs them through the terminals TE3 and TE4.

In FIG. 9, the transistors M8 and M9 are the switches SWL. SWH.

Hereinafter, a touch input sensing apparatus according to an embodiment of the present invention will be described with reference to FIGS. 7 to 8. FIG. The touch chip may include a standby mode sensing circuit module 30_T and a compensation circuit 60. [ At this time, the input terminal IN of the standby mode sensing circuit module 30_T and the output terminal of the compensation circuit are connected together to the integrated electrode 11, and the input terminal IN of the standby mode sensing circuit module 30_T, The switching of the first current I _I and the switching of the second current I _CQ flowing through the output terminal of the compensation circuit may be synchronized with each other.

At this time, the sign of the first current and the sign of the second current may be the same. Alternatively, the sign of the first current and the sign of the second current may be different from each other.

At this time, the standby mode sensing circuit module 30_T includes a first operational amplifier OA1 and a second operational amplifier OA2, and a non-inverting input terminal of the first operational amplifier receives a predetermined first reference voltage VREF_H ), A predetermined second reference voltage (VREF_L) is applied to the non-inverting input terminal of the second operational amplifier, and the integrated electrode (11) is connected to the inverting input terminal of the first operational amplifier And may be selectively connected to the inverting input terminal of the amplifier through the sense circuit switch unit 410.

Here, the first operational amplifier and the second operational amplifier each include an integral capacitor (C _S1 , C _S2 ) for integrating the current flowing through the input terminal of the standby mode sensing circuit module 30_T, The output signal of the sense circuit module 30_T may be provided as a potential difference between the first output terminal VOUT1 of the first operational amplifier and the second select terminal VOUT2 of the second operational amplifier.

10 shows an example of a stray capacitance compensation circuit 60 according to another embodiment of the present invention.

The stray capacitance compensation circuit 60 may include a second compensation circuit switch unit 401 that operates in synchronization with the sensing circuit switch unit 410. The second compensation circuit switch unit 401 is synchronized with the sensing circuit switch unit 410 so that the sign of the current I _I inputted to the input terminal of the standby mode sensing circuit module 30_T and the sign of the current I _I input to the stray capacitance sensing circuit module 30_T, So that the sign of the current (I _CQ ) inputted to the output terminal of the transistor _Q1 is synchronized with time. Here can mean that the sign of the current (I _I) and the current (I _CQ) To be synchronized with time, changes also the sign of the current (I _CQ) at the moment the sign of the current (I _I) changes.

At this time, in the third embodiment according to the present invention, the sign of the current I _I and the current I _CQ may be the same at a specific point in time.

FIG. 11 is a timing diagram for explaining operation characteristics of the stray capacitance compensating circuit provided according to the third embodiment of the present invention with respect to time; FIG.

In Fig. 11, the voltage VS at the output terminal of the operational amplifier 300 can be designed to follow the change pattern of the signal V _IN over time. And in the embodiment shown in Fig. 11, the amount of charge Q _comp accumulated in the compensation capacitor C _comp and the pattern of the sign may follow the pattern indicated by the voltage VS.

10 and 11, in order to implement the third embodiment, the first compensation potential VRH has a voltage VREF_H 'higher than the first reference voltage VREF_H, The potential VRL may have a voltage VREF_L 'that is smaller than the second reference voltage VREF_L (however, VREF_H> VREF_L).

Alternatively, in the fourth embodiment according to the present invention, the sign of the current I _I and the sign of the current I _CQ may be made different at a specific point in time. To implement the fourth embodiment, the first compensation potential VRH shown in Fig. 11 is changed to have a voltage (VREF_H ") smaller than the first reference voltage VREF_H, and the second compensation potential VRL is changed (VREF_H > VREF_L) that is higher than the reference voltage VREF_L.

The third embodiment described above has the effect of reducing the capacitance of the touch input sensing electrode viewed from the input terminal of the touch input sensing circuit. On the other hand, in the fourth embodiment described above, the touch input sensing electrode There is an effect of increasing the value of the capacitance. Therefore, the third embodiment described above increases the sensitivity of the touch input detection circuit, and the fourth embodiment has the effect of reducing the sensitivity of the touch input detection circuit.

12 to 15 illustrate various modified examples of the touch input sensing device provided by the present invention. In particular, a modification of the configuration of the standby mode sensing circuit module and the standby mode sensing circuit module .

2, only one standby mode sensing circuit module 30_T is provided, and the standby mode sensing circuit module 30_T is provided with the sensing circuit modules 30_1 to 30_L and the standby mode sensing circuit module 30_T. Are distinguished from each other. At this time, the second switch unit 220 connects all the N row electrodes Y1 to YN and the M column electrodes X1 to XM included in the touch screen panel 10, To the standby mode sensing circuit module 30_T.

In the touch input sensing apparatus shown in Fig. 13, two or more standby mode sensing circuit modules 30_T are provided, and each standby mode sensing circuit module 30_T is provided with an example that is distinguished from the sensing circuit modules 30_1 to 30_L . At this time, the second switch unit 220 connects some of the N row electrodes Y1 to YN and the M column electrodes X1 to XM included in the touch screen panel 10, Mode sensing circuit module 30_T and a part or all of the remaining part of the standby mode sensing circuit module 30_T is connected to the first standby mode sensing circuit module 30_T and 311 of the at least two standby mode sensing circuit modules 30_T, And can be connected to the standby mode sensing circuit module 30_T, 312.

14, only one standby mode sensing circuit module 30_T is provided, and the specific sensing circuit modules ex_30_1 and the standby sensing circuit modules 30_T are provided in the example . 14, the first sensing circuit module 313 performs the function of the standby mode sensing circuit module 30_T in the touch input standby mode. In the touch input sensing mode, the first sensing circuit module 313 performs functions of the sensing circuit module 30_1 Can be performed.

15, two or more standby mode sensing circuit modules 30_T are provided. Of these, the first standby mode sensing circuit module 311 is connected to the sensing circuit modules 30_1 to 30_L, However, the second standby mode sensing circuit module 313 shows an example in which the specific sensing circuit modules ex230_1 and 30_1_1 perform the role of the specific sensing circuit modules ex. 15, the first sensing circuit module 313 performs the function of the standby mode sensing circuit module 30_T in the touch input standby mode and the function of the sensing circuit module 30_1 in the touch input sensing mode Can be performed. At this time, the second switch unit 220 connects some of the N row electrodes Y1 to YN and the M column electrodes X1 to XM included in the touch screen panel 10, Mode sensing circuit module 30_T and a part or all of the remaining part of the standby mode sensing circuit module 30_T is connected to the first standby mode sensing circuit module 30_T and 311 of the at least two standby mode sensing circuit modules 30_T, Can be connected to the standby mode sensing circuit module 30_T, 313.

In the touch input sensing device according to the preferred embodiment of the present invention described with reference to FIGS. 12 to 15, the number of the standby mode sensing circuit modules 30_T may be always smaller than the number L of the sensing circuit modules 30_1-30_L have.

16 is a diagram showing the relationship between the integrated electrode 11 shown in FIG. 5 and N row electrodes Y1 to YN and M column electrodes X1 to XM included in the touch screen panel 10 to be.

 An equivalent electrode formed by connecting all the N row electrodes Y1 to YN and the M column electrodes X1 to XM by the switch unit 20 may be referred to as the integrated electrode 11. [

Alternatively, as described with reference to FIGS. 13 and 15, when a plurality of standby mode sensing circuit modules 30_T exist, the integrated electrode 11 connected to each standby mode sensing circuit module 30_T, It may be an equivalent electrode in which only a part of the N row electrodes Y1 to YN and the M column electrodes X1 to XM are connected to each other.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the essential characteristics thereof. The contents of each claim in the claims may be combined with other claims without departing from the scope of the claims.

X1 to XM, Y1 to YN: a plurality of electrodes 10: touch screen panel
11: Integrated electrodes 30_1 to 30_L: A plurality of sensing circuit modules
30_T: standby mode detection circuit module 40: TX driving section
50: operation processing and drive control section 120: first switch section
220: second switch part 410: sensing circuit switch part
OA1: first operational amplifier OA2: second operational amplifier
VREF_H: first reference voltage VREF_L: second reference voltage

Claims (14)

A touch input sensing apparatus for providing a touch input standby mode and a touch input operation mode,
A plurality of electrodes;
Standby mode sensing circuit module;
A second switch connected to the plurality of electrodes and the standby mode sensing circuit module;
An operation processing and driving control unit for controlling the second switch unit to connect the plurality of electrodes to each other to form an integrated electrode and to connect the integrated electrode to the standby mode sensing circuit module in the touch input standby mode; And
And a compensation circuit including a fourth switch for connecting the fourth current source to the output terminal, a third current source, and a third switch for connecting the third current source to the output terminal,
An input terminal of the standby mode sensing circuit module is connected to the output terminal,
Wherein the rising edge of the third control signal for controlling the third switch is synchronized at a first switching point at which the first current flowing through the input terminal is switched from the first direction to the second direction,
A rising edge of a fourth control signal for controlling the fourth switch is synchronized to a second switching point at which the first current is switched from the second direction to the first direction,
Wherein a current provided by the fourth current source flows in a direction from the fourth current source toward the output terminal and a current provided by the third current source flows in a direction from the output terminal toward the third current source there is,
Touch input sensing device. The method according to claim 1,
The plurality of electrodes may include:
A plurality of row electrodes formed on the first layer of the touch screen panel and a plurality of column electrodes formed on the second layer of the touch screen panel,
The plurality of row electrodes, or
The plurality of column electrodes, or
The plurality of row electrodes and the plurality of column electrodes
≪ / RTI >
Touch input sensing device. The method according to claim 1,
And a TX driver,
Wherein the plurality of electrodes are a plurality of row electrodes formed on a first layer of a touch screen panel and a plurality of row electrodes among a plurality of column electrodes formed on a second layer of the touch screen panel,
Wherein the calculation processing and drive control unit controls the TX driving unit to apply pulse trains to one or more column electrodes of the plurality of column electrodes in the touch input standby mode,
Touch input sensing device. The method according to claim 1,
A plurality of sensing circuit modules; And
A first switch connected to the plurality of electrodes and the plurality of sensing circuit modules;
Further comprising:
Wherein the operation processing and drive control unit controls the first switch unit to connect each of the plurality of electrodes to any one of the plurality of sensing circuit modules in the touch input operation mode,
Touch input sensing device. 5. The method of claim 4,
Wherein the arithmetic processing and drive control unit controls the first switch unit so that all of the plurality of electrodes are not connected to any of the plurality of sense circuit modules in the touch input standby mode,
Touch input sensing device. The method according to claim 1,
Wherein the arithmetic processing and driving control unit controls the second switch unit such that all of the plurality of electrodes are not connected to the input terminal of the standby mode sensing circuit module in the touch input operation mode,
Touch input sensing device. The method according to claim 1,
Wherein the fourth current source comprises:
A first transistor and a second transistor whose source is connected to a first potential; And
A current source coupled to a drain of the first transistor;
/ RTI >
A drain of the first transistor is connected to gates of the first transistor and the second transistor,
The current flowing through the drain of the second transistor constitutes at least a part of the output current of the fourth current source,
Touch input sensing device. 8. The method of claim 7,
Wherein the fourth current source comprises:
A third transistor whose source is connected to the first potential;
A fifth transistor having a source connected to a drain of the second transistor; And
A sixth transistor having a source connected to a drain of the third transistor;
Further comprising:
A drain of the first transistor is connected to a gate of the third transistor,
The current flowing through the drain of the second transistor and the current flowing through the drain of the third transistor constitute at least a part of the output current of the fourth current source,
Wherein a magnitude and a shape of an output current of the fourth current source are determined by ON / OFF states of the fifth transistor and the sixth transistor,
Touch input sensing device. The method according to claim 1,
Wherein the third current source comprises:
A 16th transistor and a 15th transistor whose source is connected to a second potential; And
A current source coupled to a drain of the sixteenth transistor;
/ RTI >
The drain of the sixteenth transistor is connected to the gates of the sixteenth transistor and the fifteenth transistor,
And the current flowing through the drain of the fifteenth transistor constitutes at least a part of the output current of the third current source.
Touch input sensing device. The touch input sensing device of claim 4, wherein the standby mode sensing circuit module is distinguished from the plurality of sensing circuit modules. 11. The method of claim 10,
A second standby mode sensing circuit module,
And the second standby mode sensing circuit module is distinguished from the plurality of sensing circuit modules.
Touch input sensing device. 11. The method of claim 10,
A second standby mode sensing circuit module,
And the second standby mode sensing circuit module is any one of the plurality of sensing circuit modules.
Touch input sensing device. The touch input sensing device of claim 4, wherein the standby mode sensing circuit module is any one of the plurality of sensing circuit modules. A second switch unit connected to the plurality of electrodes and the idle mode sensing circuit module, an arithmetic processing and driving control unit, and an output terminal, a fourth current source, and the fourth current source, And a third switch for connecting the third current source to the output terminal, wherein the compensation circuit includes a touch input standby mode and a touch providing a touch input operation mode, A method for executing a touch input standby mode at an input sensing device,
Wherein the operation processing and driving control unit includes connecting the plurality of electrodes to each other to form an integrated electrode in the touch input standby mode and connecting the integrated electrode to the standby mode sensing circuit module,
An input terminal of the standby mode sensing circuit module is connected to the output terminal,
Wherein the rising edge of the third control signal for controlling the third switch is synchronized at a first switching point at which the first current flowing through the input terminal is switched from the first direction to the second direction,
A rising edge of a fourth control signal for controlling the fourth switch is synchronized to a second switching point at which the first current is switched from the second direction to the first direction,
Wherein a current provided by the fourth current source flows in a direction from the fourth current source toward the output terminal and a current provided by the third current source flows in a direction from the output terminal toward the third current source there is,
How to activate touch input standby mode.

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