阅读说明：本技术 电容检测电路、触控芯片、触摸检测装置及电子设备 (Capacitance detection circuit, touch chip, touch detection device and electronic equipment ) 是由 余倩 于 2020-03-27 设计创作，主要内容包括：本申请提供一种电容检测电路、触控芯片、触摸检测装置及电子设备。本申请提供的电容检测电路,通过将运算放大器的第一输入端连配置为预设电压,利用运算放大器的两个输入端电压相同的特征,从而使得通过运算放大器的第二输入端将触控传感器中的输出电压配置为预设电压,通过改变打码电压驱动的位置,以用同样的电路实现互容与自容检测。此外,将运算放大器输出的单路电流信号复制成多路电流信号后,再利用电流减法电路确定相邻两个通道所输出的电流信号的差分信号,并将差分信号通过电荷放大电路转化为电压,以实现能够同时读取全通道互容差分信号,最后,在进行模数转化后,通过处理电路来确定触控传感器中各个电容器的电容值。(The application provides a capacitance detection circuit, a touch chip, a touch detection device and an electronic device. According to the capacitance detection circuit, the first input end of the operational amplifier is connected and configured to be the preset voltage, the same characteristic of the voltages of the two input ends of the operational amplifier is utilized, so that the output voltage in the touch sensor is configured to be the preset voltage through the second input end of the operational amplifier, and mutual capacitance and self-capacitance detection are achieved through the same circuit by changing the position of the coding voltage drive. In addition, after a single-path current signal output by the operational amplifier is copied into a plurality of paths of current signals, a current subtraction circuit is used for determining a differential signal of the current signals output by two adjacent channels, the differential signal is converted into voltage through a charge amplification circuit, so that the mutual capacitance differential signals of all the channels can be read simultaneously, and finally, after analog-to-digital conversion is carried out, the capacitance value of each capacitor in the touch sensor is determined through a processing circuit.)

1. A capacitance detection circuit, comprising: the circuit comprises an operational amplifier, a current signal copying circuit, a current subtraction circuit, a charge amplifying circuit, an analog-to-digital conversion circuit and a processing circuit;

the first input end of the operational amplifier is used for inputting a preset voltage;

the second input end of the operational amplifier is used for configuring the output voltage in the touch sensor to the preset voltage;

the output end of the operational amplifier is connected with the input end of the current signal copying circuit;

the output end of the current signal copying circuit is connected with the input end of the current subtraction circuit, and the current subtraction circuit is used for determining the differential signal of the current signals output by two adjacent channels;

the output end of the current subtraction circuit is connected with the charge amplification circuit, and the charge amplification circuit is used for converting the differential signal into voltage, amplifying the voltage and inputting the amplified voltage to the analog-to-digital conversion circuit, so that after analog-to-digital conversion is carried out, the touch position is determined through the processing circuit.

2. The capacitance detection circuit according to claim 1, wherein the predetermined voltage is a fixed voltage during mutual capacitance detection, the second input terminal of the operational amplifier is configured to configure the output voltage to be the fixed voltage, so that all current signals flowing through a coupling capacitor, which is a capacitor between the sensing electrode and the driving electrode, flow into the second input terminal of the operational amplifier; alternatively, the first and second electrodes may be,

when the self-capacitance detection is carried out, the preset voltage is a self-capacitance coding voltage, and the second input end of the operational amplifier is used for configuring the output voltage into the self-capacitance coding voltage, so that current signals flowing through the induction capacitor all flow into the second input end of the operational amplifier.

3. The capacitance detection circuit according to claim 2, wherein a second switch is connected to the first input terminal of the operational amplifier;

when the second switch is in a first state, the first input end of the operational amplifier is connected with the fixed voltage input end;

when the second switch is in the second state, the first input end of the operational amplifier is connected with the self-capacitance coding voltage input end.

4. The capacitance detection circuit according to claim 2, further comprising: a first switch;

the first switch is used for selecting the detection coding voltage of the driving channel;

when the first switch is in a first state, the detection coding voltage is a mutual capacitance coding voltage, and correspondingly, the preset voltage is the fixed voltage;

when the first switch is in the second state, the detection coding voltage is the self-capacitance coding voltage, and correspondingly, the preset voltage is the self-capacitance coding voltage.

5. The capacitance detection circuit according to claim 4, wherein when the first switch is in the second state, a first input terminal of another operational amplifier is connected to the self-capacitance coding voltage input terminal, and a second input terminal of the another operational amplifier is configured to output the self-capacitance coding voltage to the driving channel.

6. The capacitance detection circuit according to any one of claims 1 to 5, wherein the current signal replica circuit is a current mirror replica circuit or a PMOS transistor replica circuit.

7. The capacitance detection circuit of claim 6, wherein the current mirror replica circuit comprises a first current mirror, a second current mirror, and a third current mirror;

the input end of the first current mirror is connected with the collector electrode of a first field effect transistor, the grid electrode of the first field effect transistor is connected with the output end of the operational amplifier, the source electrode of the first field effect transistor is connected with one end of a first resistor, and the other end of the first resistor is grounded;

the output end of the first current mirror is respectively connected with the input ends of the second current mirror and the third current mirror, so that the currents output by the output end of the second current mirror and the output end of the third current mirror are the same as the current of the input end of the first current mirror.

8. The capacitance detection circuit according to claim 6, wherein the PMOS transistor replica circuit comprises a first PMOS transistor, a second PMOS transistor, and a third PMOS transistor;

the grid electrode of the first PMOS tube is connected with the output end of the operational amplifier, the collector electrode of the first PMOS tube is connected with one end of a first resistor, and the other end of the first resistor is grounded;

the grid electrode of the second PMOS tube and the grid electrode of the third PMOS tube are respectively connected with the grid electrode of the first PMOS tube, so that the currents output by the collector electrode of the second PMOS tube and the collector electrode of the third PMOS tube are the same as the current input into the grid electrode of the first PMOS tube.

9. The capacitance detection circuit according to any one of claims 1-5, wherein the current subtraction circuit is a current subtractor circuit or an input common mode control circuit.

10. The capacitance detection circuit according to any one of claims 1-5, wherein the charge amplification circuit is a Programmable Gain Amplification (PGA) circuit or an integrator circuit connection.

11. A touch chip comprising the capacitance detection circuit according to any one of claims 1 to 10.

12. A touch detection device comprising the touch chip as claimed in claim 11, wherein the touch detection device determines a trigger position according to the capacitance values of the capacitors determined by the touch chip.

13. An electronic device, comprising: the touch sensing apparatus of claim 12.

Technical Field

The application relates to the technical field of electronics, especially, relate to a capacitance detection circuit, touch chip, touch detection device and electronic equipment.

Background

With the rapid development of electronic technology, the capacitive sensor has a wide application prospect in touch intelligent terminals (e.g., mobile phones, tablets, computers and other intelligent mobile terminals).

In the capacitive sensor, the capacitance value can change along with the touch, and through the capacitance detection circuit, the change of capacitance value is read out to make intelligent terminal can judge user's operation, thereby reach better human-computer interaction experience.

However, as the size of the screen applied to the smart terminal increases and the screen body technology is updated, the capacitance value of the touch screen also increases, and how to implement capacitance detection is a problem that needs to be solved at present under a larger capacitance value.

Disclosure of Invention

The application provides a capacitance detection circuit, a touch chip, a touch detection device and an electronic device, which are used for solving the problem of capacitance detection.

In a first aspect, the present application provides a capacitance detection circuit, comprising: the circuit comprises an operational amplifier, a current signal copying circuit, a current subtraction circuit, a charge amplifying circuit, an analog-to-digital conversion circuit and a processing circuit;

the first input end of the operational amplifier is used for inputting a preset voltage;

the second input end of the operational amplifier is used for configuring the output voltage in the touch sensor to the preset voltage;

the output end of the operational amplifier is connected with the input end of the current signal copying circuit;

the output end of the current signal copying circuit is connected with the input end of the current subtraction circuit, and the current subtraction circuit is used for determining the differential signal of the current signals output by two adjacent channels;

the output end of the current subtraction circuit is connected with the charge amplification circuit, and the charge amplification circuit is used for converting the differential signal into voltage, amplifying the voltage and inputting the amplified voltage to the analog-to-digital conversion circuit, so that after analog-to-digital conversion is carried out, the touch position is determined through the processing circuit.

In one possible design, when the preset voltage is a fixed voltage, the second input terminal of the operational amplifier is configured to configure the output voltage as the fixed voltage, so that a current signal flowing through a coupling capacitor, which is a capacitor between the sensing electrode and the driving electrode, flows into the second input terminal of the operational amplifier completely; alternatively, the first and second electrodes may be,

when the preset voltage is a self-capacitance coding voltage, the second input end of the operational amplifier is used for configuring the output voltage into the self-capacitance coding voltage, so that all current signals flowing through the induction capacitor flow into the second input end of the operational amplifier.

In one possible design, a second switch is connected to the first input terminal of the operational amplifier;

when the second switch is in a first state, the first input end of the operational amplifier is connected with the fixed voltage input end;

when the second switch is in the second state, the first input end of the operational amplifier is connected with the self-capacitance coding voltage input end.

In one possible design, the capacitance detection circuit further includes: a first switch;

the first switch is used for selecting the detection coding voltage of the driving channel;

when the first switch is in a first state, the detection coding voltage is a mutual capacitance coding voltage, and correspondingly, the preset voltage is the fixed voltage;

when the first switch is in the second state, the detection coding voltage is the self-capacitance coding voltage, and correspondingly, the preset voltage is the self-capacitance coding voltage.

In one possible design, when the first switch is in the second state, the first input terminal of the other operational amplifier is connected to the self-capacitance coding voltage input terminal, and the second input terminal of the other operational amplifier is used for outputting the self-capacitance coding voltage to the driving channel.

In one possible design, the current signal replica circuit is a current mirror replica circuit or a PMOS transistor replica circuit.

In one possible design, the current mirror replica circuit includes a first current mirror, a second current mirror, and a third current mirror;

the input end of the first current mirror is connected with the collector electrode of a first field effect transistor, the grid electrode of the first field effect transistor is connected with the output end of the operational amplifier, the source electrode of the first field effect transistor is connected with one end of a first resistor, and the other end of the first resistor is grounded;

the output end of the first current mirror is respectively connected with the input ends of the second current mirror and the third current mirror, so that the currents output by the output end of the second current mirror and the output end of the third current mirror are the same as the current of the input end of the first current mirror.

In one possible design, the PMOS transistor replica circuit includes a first PMOS transistor, a second PMOS transistor, and a third PMOS transistor;

the grid electrode of the first PMOS tube is connected with the output end of the operational amplifier, the collector electrode of the first PMOS tube is connected with one end of a first resistor, and the other end of the first resistor is grounded;

the grid electrode of the second PMOS tube and the grid electrode of the third PMOS tube are respectively connected with the grid electrode of the first PMOS tube, so that the currents output by the collector electrode of the second PMOS tube and the collector electrode of the third PMOS tube are the same as the current input into the grid electrode of the first PMOS tube.

In one possible design, the current subtraction circuit is a current subtractor circuit or an input common mode control circuit.

In one possible design, the charge amplification circuit is a programmable gain amplification PGA circuit or an integrator circuit connection.

In a second aspect, the present application further provides a touch chip, including: any optional capacitance detection circuit of the first aspect.

In a third aspect, the present application further provides a touch detection apparatus, including: in the capacitance detection circuit according to any one of the first to the second aspects, the touch detection device determines the trigger position according to the capacitance values of the capacitors determined by the capacitance detection circuit.

In a fourth aspect, the present application further provides an electronic device, including: a touch detection apparatus as described in the third aspect.

The application provides a capacitance detection circuit, touch-control chip, touch detection device and electronic equipment, through linking the first input with operational amplifier and configuring into preset voltage, utilize the same characteristic of two input terminal voltages of operational amplifier, thereby make the output voltage configuration of the second input through operational amplifier in with touch-control sensor to preset voltage, with when carrying out mutual capacitance detection, set up preset voltage into fixed voltage, with fixed induction capacitance upper plate voltage, thereby make the current signal of coupling capacitance of flowing through all flow in operational amplifier's second input, with the semaphore loss of the current signal that prevents from coupling capacitance to pass through on corresponding induction capacitance. In addition, when the self-capacitance detection is carried out, the preset voltage is set as the self-capacitance coding voltage, so that the upper plate voltage of the sensing capacitor is synchronized to be the self-capacitance coding voltage, all current signals flowing through the sensing capacitor flow into the second input end of the operational amplifier, and the signal quantity loss of the current signals passing through the sensing capacitor on the corresponding coupling capacitor is prevented. Therefore, the capacitance detection circuit provided by the embodiment can realize mutual capacitance and self-capacitance detection by using the same circuit by changing the position of the coding voltage drive. In addition, the output end of the operational amplifier is connected with the input end of the current signal copying circuit, so that after a single-path current signal output by the operational amplifier is copied into a plurality of paths of current signals, the current subtraction circuit is used for determining a differential signal of the current signals output by two adjacent channels, the differential signal is converted into voltage through the charge amplification circuit, the voltage is amplified and then is used for ADC sampling output, and therefore the purpose that the mutual capacitance differential signals of all channels can be read simultaneously is achieved, and the refresh rate is not lost. Finally, after analog to digital conversion, the touch location is determined by the processing circuitry.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

FIGS. 1A-1B are schematic diagrams of a capacitance detection circuit provided in the prior art;

FIG. 2 is a schematic diagram of another capacitance detection circuit provided in the prior art;

fig. 3 is a schematic structural diagram of a capacitance detection circuit according to an embodiment of the present application;

FIG. 4 is a schematic diagram of another operating state structure of the capacitance detection circuit of the embodiment shown in FIG. 3;

fig. 5 is a schematic structural diagram of a capacitance detection circuit according to another embodiment of the present application;

FIG. 6 is a schematic diagram of another operating state structure of the capacitance detection circuit of the embodiment shown in FIG. 5;

fig. 7 is a schematic structural diagram of a capacitance detection circuit according to yet another embodiment of the present application;

fig. 8 is a schematic diagram of another operating state structure of the capacitance detection circuit in the embodiment shown in fig. 7.

With the foregoing drawings in mind, certain embodiments of the disclosure have been shown and described in more detail below. These drawings and written description are not intended to limit the scope of the inventive concepts in any manner, but rather to illustrate the inventive concepts to those skilled in the art by reference to specific embodiments.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims of the present application and in the drawings described above, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

With the rapid development of electronic technology, the capacitive sensor has a wide application prospect in touch intelligent terminals (e.g., mobile phones, tablets, computers and other intelligent mobile terminals). In the capacitive sensor, the capacitance value can change along with the touch, and through the capacitance detection circuit, the change of capacitance value is read out to make intelligent terminal can judge user's operation, thereby reach better human-computer interaction experience. However, as the size of the screen applied to the smart terminal increases and the screen body technology is updated, the capacitance value of the touch screen also increases, and how to implement capacitance detection is a problem that needs to be solved at present under a larger capacitance value.

In order to increase the sensitivity of capacitance change measurement, the voltage input to the touch screen capacitance is often selected to be greater. As the capacitance variation signal becomes larger, the detected capacitance signal amount of the touch panel itself also needs to be larger. Meanwhile, in order to improve the signal-to-noise ratio, multiple paths of mutual capacitances are often required to be read simultaneously during mutual capacitance detection. Under such conditions, the read circuit is easily saturated. To prevent the read circuit from saturating, a higher dynamic range of the circuit is required, which results in a doubling of the power consumption.

On the other hand, as the distance between the touch screen and the display screen is closer and closer, and the capacitance of the touch screen is increased, larger display screen interference is coupled, and the interference can saturate the front-end circuit. To avoid saturation of the front-end circuit, a larger dynamic range is also required, which not only doubles the power consumption, but also makes most of the read and stored data an interfering signal that is useless for human-computer interaction applications, or a large capacitive signal of the screen itself. In the prior art, in order to achieve higher efficiency of reading circuits and storing effective information, the requirement of large dynamic range needs to be avoided.

Fig. 1A-1B are schematic structural diagrams of a capacitance detection circuit in the prior art, and as shown in fig. 1A-1B, a capacitance touch system may include a driving channel layer (TX layer) and a sensing channel layer (RX layer). The TX layer includes a plurality of TX channels, and the driving capacitance of the TX channels to ground may include: c_TX1、C_TX2、C_TX3And the like. The RX layer includes a plurality of RX channels, and the RX channels have induced capacitances to ground, such as: c_RX1、C_RX2、C_RX3And the like. At C_TX1And C_RX1A mutual capacitance C exists between_M1In C_TX1And C_RX2A mutual capacitance C exists between_M2In C_TX1And C_RX3There is a coupling capacitance C between_M3。

Specifically, the front end of a fully differential circuit of adjacent reading channels is adopted, the positive end and the negative end of the circuit are respectively connected with adjacent touch screen capacitors, differential mode currents or charges at the two ends are amplified through differential operational amplification, and common mode signals, interference and noise are suppressed. Because the interference of the adjacent channels by the display is basically the same and the capacitances of the touch screens corresponding to the adjacent channels are close to each other, the interference of the display and the capacitance signals of the touch screens can be effectively inhibited as a common mode, and the requirement of the dynamic range of the reading circuit is greatly reduced. However, since the differential circuit requires the adjacent channels to read simultaneously, but with continued reference to fig. 1A-1B, in the Φ 1 state, the RX2 channel can only be differentiated from the RX1 channel adjacent to one side, and the RX3 channel adjacent to the other side needs to be differentiated in the Φ 2 state, so that the method often needs to perform two differencing operations (i.e., the Φ 1 state and the Φ 2 state) in time to obtain the difference between all adjacent channels, so as to save and restore the capacitance variation of all channels. However, time-sharing reading may lose half of the refresh rate of touch screen signal reading, and therefore is not acceptable in high refresh rate smart devices.

Fig. 2 is a schematic structural diagram of another capacitance detection circuit provided in the prior art, in order to ensure that the refresh rate is not reduced and that a differential reading mode for all channels needs to be performed simultaneously. This is a circuit that detects a change in the mutual capacitance semaphore, as shown in fig. 2. Current signal i ═ V generated by TX terminal coding_TXsC_MIs duplicated into two paths through a current mirror and is respectively connected to adjacent reading channels, wherein s is the angular frequency of the coupling capacitor, refer to fig. 2, C_MMay be a coupling capacitor C_M1Or coupling capacitor C_M2Or coupling capacitor C_M3The capacitance value of (2). Then, the currents of the adjacent channels can be subtracted at the same time, so that the differential signals of all channels can be read at the same time, and thus the differential signals of all channels can be obtained for restoring the single-ended signal quantity of each channel or positioning the touch detection.

However, with continued reference to fig. 2, the amount of signal detected by this circuit will be much less than i-V_TXsC_MBecause of the difference from the conventional driving capacitor C_RXThe upper plate is connected with the operational amplifier, and the total current generated by the operational amplifier is equal to V_TXsC_MWill be divided into the driving capacitors C_RXOn larger and larger touch screens, C_RXAlso getting larger, impedance 1/(sC)_RX) The smaller, so more current will flow from the drive capacitor C_RXFlows away without entering the path of the current mirror, which results in a significant loss of signal quality.

In view of the above problems, embodiments of the present invention provide a capacitance detection circuit, which configures a first input terminal of an operational amplifier as a preset voltage, and utilizes the characteristic that voltages at two input terminals of the operational amplifier are the same, so as to configure an output voltage in a touch sensor as the preset voltage through a second input terminal of the operational amplifier, so as to set the preset voltage as a fixed voltage to fix a voltage at an upper plate of an induction capacitor when performing mutual capacitance detection, so that a current signal flowing through a coupling capacitor all flows into the second input terminal of the operational amplifier, and thus, a signal amount loss of the current signal passing through the coupling capacitor on the corresponding induction capacitor is prevented. In addition, when the self-capacitance detection is carried out, the preset voltage is set as the self-capacitance coding voltage, so that the upper plate voltage of the sensing capacitor is synchronized to be the self-capacitance coding voltage, all current signals flowing through the sensing capacitor flow into the second input end of the operational amplifier, and the signal quantity loss of the current signals passing through the sensing capacitor on the corresponding coupling capacitor is prevented. Therefore, the capacitance detection circuit provided by the embodiment can realize mutual capacitance and self-capacitance detection by using the same circuit by changing the position of the coding voltage drive. In addition, the output end of the operational amplifier is connected with the input end of the current signal copying circuit, so that after a single-path current signal output by the operational amplifier is copied into a plurality of paths of current signals, a current subtraction circuit is used for determining a differential signal (current difference signal) current difference signal of the current signals output by two adjacent channels, the differential signal current difference signal is converted into a voltage through a charge amplifying circuit, and the voltage is amplified and then is used for ADC sampling output, so that the mutual capacitance differential signals of all channels can be read simultaneously, and the refresh rate is not lost. Finally, after analog to digital conversion, the touch location is determined by the processing circuitry.

Fig. 3 is a schematic structural diagram of a capacitance detection circuit according to an embodiment of the present disclosure. As shown in fig. 3, the capacitance detection circuit provided in this embodiment includes: the circuit comprises an operational amplifier, a current signal copying circuit, a current subtraction circuit, a charge amplifying circuit, an analog-to-digital conversion circuit and a processing circuit. The first input end of the operational amplifier is used for inputting a preset voltage, wherein the preset voltage is a fixed voltage or a self-capacitance coding voltage. The second input end of the operational amplifier is used for configuring the output voltage in the touch sensor to a preset voltage, so that a current signal flowing through the coupling capacitor or the sensing capacitor flows into the second input end of the operational amplifier, and the coupling capacitor is a capacitor between the sensing electrode and the driving electrode.

The output end of the operational amplifier is connected with the input end of the current signal copying circuit, and the current signal copying circuit is used for copying the single-path current signal output by the operational amplifier into a multi-path current signal. And one output end of the current signal copying circuit is connected with an input end of a current subtraction circuit, and the current subtraction circuit is used for determining a differential signal of the current signals output by two adjacent channels. In addition, the output end of the current subtraction circuit is connected with a charge amplification circuit, the charge amplification circuit is used for converting the differential signal into voltage, amplifying the voltage and inputting the amplified voltage into an analog-to-digital conversion circuit, so that after analog-to-digital conversion is carried out, the capacitance value of each capacitor in the touch sensor is determined through a processing circuit.

In this embodiment, the first input terminal of the operational amplifier is connected and configured to be the preset voltage, and the same characteristic of the voltages at the two input terminals of the operational amplifier is utilized, so that the output voltage of the touch sensor is configured to be the preset voltage through the second input terminal of the operational amplifier, and when mutual capacitance detection is performed, the preset voltage is set to be the fixed voltage to fix the upper plate voltage of the sensing capacitor, so that all current signals flowing through the coupling capacitor flow into the second input terminal of the operational amplifier, and the signal quantity loss of the current signals passing through the coupling capacitor on the corresponding sensing capacitor is prevented. In addition, when the self-capacitance detection is carried out, the preset voltage is set as the self-capacitance coding voltage, so that the upper plate voltage of the sensing capacitor is synchronized to be the self-capacitance coding voltage, all current signals flowing through the sensing capacitor flow into the second input end of the operational amplifier, and the signal quantity loss of the current signals passing through the sensing capacitor on the corresponding coupling capacitor is prevented. Therefore, the capacitance detection circuit provided by the embodiment can realize mutual capacitance and self-capacitance detection by using the same circuit by changing the position of the coding voltage drive. In addition, the output end of the operational amplifier is connected with the input end of the current signal copying circuit, so that after a single-path current signal output by the operational amplifier is copied into a plurality of paths of current signals, the current subtraction circuit is used for determining a differential signal of the current signals output by two adjacent channels, the differential signal is converted into voltage through the charge amplification circuit, the voltage is amplified and then is used for ADC sampling output, and therefore the purpose that the mutual capacitance differential signals of all channels can be read simultaneously is achieved, and the refresh rate is not lost. Finally, after analog-to-digital conversion, the touch position of the object on the touch screen is determined by the processing circuit.

In the touch sensor, the driving capacitance of the driving channel to ground may include: first drive capacitor C_TX1A second driving capacitor C_TX2(not shown), a third drive capacitor C_TX3(not shown in the figure), etc. The sensing channel may include a sensing capacitance to ground: a first inductive capacitor C_RX1A second induction capacitor C_RX2A third inductive capacitor C_RX3And the like. And the coupling capacitor coupled between the driving electrode and the sensing electrode may include: a first coupling capacitor C coupled between the first drive electrode and the first sense electrode_M1A second coupling capacitor C coupled between the first drive electrode and the second induction electrode_M2A first coupling capacitor C coupled between the first drive electrode and the third induction electrode_M3And the like.

In order to simultaneously perform differential reading of all channels, it is necessary to perform differential processing on any two adjacent channels. To illustrate the mutual capacitance detection principle of the capacitance detection circuit provided in this embodiment, a driving capacitor (e.g., the first driving capacitor C) may be selected_TX1All the first driving capacitors C_TX1A capacitor forming a TX channel after being connected in parallel) and three sensing capacitors (a first sensing capacitor C)_RX1A second induction capacitor C_RX2A third inductive capacitor C_RX3) The detection circuit of (1) is exemplified.

Specifically, referring to FIG. 3, in a touch sensor driveMoving channels, for example: first drive capacitor C_TX1And a first coupling capacitor C_M1Position between and mutual capacitance code-printing voltage input end V_TXConnected, a first drive capacitor C_TX1And a second coupling capacitor C_M2Voltage input end V for mutual capacitance coding_TXConnected, a first drive capacitor C_TX1And a third coupling capacitor C_M3Voltage input end V for mutual capacitance coding_TXAnd (4) connecting.

A first inductive capacitor C_RX1And a first coupling capacitor C_M1And the first operational amplifier A₁Is connected to a second input terminal (e.g., a negative input terminal), a first operational amplifier A₁A first input terminal (e.g., a positive input terminal) and a fixed voltage input terminal V_CMConnected due to the first operational amplifier A₁The voltages at the two input ends are the same, then the first induction capacitor C_RX1And a first coupling capacitor C_M1Voltage V between_RX1Is a V_CM. Wherein, worth to say, the fixed voltage input terminal V_CMThe voltage of the touch-sensing circuit can be determined according to the device characteristics in the current signal replica circuit and the output current, and generally can be about half of the driving voltage of the touch-sensing chip.

Second inductive capacitor C_RX2And a second coupling capacitor C_M2And the second operational amplifier A₂Is connected to a second input terminal (e.g., a negative input terminal), a second operational amplifier A₂A first input terminal (e.g., a positive input terminal) and a fixed voltage input terminal V_CMConnected due to the second operational amplifier A₂The voltages at the two input ends are the same, then the second induction capacitor C_RX2And a second coupling capacitor C_M2Voltage V between_RX2Is a V_CM。

Third inductive capacitor C_RX3And a third coupling capacitor C_M3And a third operational amplifier A₃Is connected to a second input terminal (e.g., a negative input terminal), and a third operational amplifier A₃And a third input terminal (e.g., a positive input terminal) and a fixed voltage input terminal V_CMConnected due to the third operational amplifierA₃The voltages at the two input ends are the same, then the third induction capacitor C_RX3And a third coupling capacitor C_M3Voltage V between_RX3Is a V_CM。

As can be seen, the first inductive capacitance C_RX1A second induction capacitor C_RX2And a third inductive capacitor C_RX3The voltage of the polar plates is fixed to be V_CM. Thus, the first inductive capacitance C_RX1Will not be divided into the first coupling capacitor C_M1The coming current, the second induction capacitor C_RX2Will not be divided into the second coupling capacitor C_M2The coming current, the third induction capacitor C_RX3Will not be divided into the third coupling capacitor C_M3The current coming from the transformer.

While the first operational amplifier A₁Is connected to an input of a first current signal replica circuit 101, the first current signal replica circuit 101 being arranged to couple a first operational amplifier a to an output of the first current signal replica circuit 101₁The output single-path current signal is copied into a multi-path current signal. Second operational amplifier A₂Is connected to an input of a second current signal replica circuit 102, the second current signal replica circuit 102 being arranged to couple a second operational amplifier a to the input of the second current signal replica circuit 102₂The output single-path current signal is copied into a multi-path current signal. Third operational amplifier A₃Is connected to an input of a third current signal replica circuit 103, the third current signal replica circuit 103 being arranged to couple a third operational amplifier a to the output of the third current signal replica circuit 103₃The output single-path current signal is copied into a multi-path current signal.

Then, the output terminals of the current signal replica circuits corresponding to two adjacent channels are connected to the input terminal of the current subtraction circuit, for example: one of the current signals output from the output terminal of the first current signal replica circuit 101 and one of the current signals output from the output terminal of the second current signal replica circuit 102 are input to a first current subtraction circuit 104 to determine a first coupling capacitor C_M1The current signal output by the channel and the second coupling capacitor C_M2The current signals output by the channels are differential signals.

Similarly, one of the current signals output by the output terminal of the second current signal copying circuit 102One of the current signals output from the output terminal of the third current signal replica circuit 103 is input to a second current subtraction circuit 105 to determine a second coupling capacitor C_M2The current signal output by the channel and the third coupling capacitor C_M3The current signals output by the channels are differential signals.

After the output end of the current subtraction circuit outputs the differential signal between the adjacent channels, the differential signal is input to the charge amplification circuit 106, so that the charge amplification circuit 106 converts the differential signal into a voltage and amplifies the voltage, so as to be sampled and output by an Analog-to-Digital Converter (ADC) 107. The charge Amplifier circuit 106 may be a Programmable Gain Amplifier (PGA) circuit or an integrator circuit. After analog-to-digital conversion, the capacitance values of the capacitors in the touch sensor are determined by the processing circuit 108, so that the trigger position is determined according to the determined capacitance values of the capacitors.

Therefore, the driving capacitor and the coupling capacitor are connected with the mutual capacitance coding voltage input end, the sensing capacitor and the coupling capacitor are connected with the second input end of the operational amplifier, the first input end of the operational amplifier is connected with the fixed voltage input end, and the upper plate voltage of the sensing capacitor is fixed by utilizing the characteristic that the voltages of the two input ends of the operational amplifier are the same, so that the loss of the signal quantity of the current signal passing through the coupling capacitor on the corresponding sensing capacitor is prevented. In addition, the output end of the operational amplifier is connected with the input end of the current signal copying circuit, so that after a single-path current signal output by the operational amplifier is copied into a plurality of paths of current signals, the current subtraction circuit is used for determining a differential signal of the current signals output by two adjacent channels, the differential signal is converted into voltage through the charge amplification circuit, the voltage is amplified and then is used for ADC sampling output, and therefore the purpose that the mutual capacitance differential signals of all channels can be read simultaneously is achieved, and the refresh rate is not lost.

With continued reference to FIG. 3, the first drive capacitor C_TX1And a first coupling capacitor C_M1Can be connected with a first switchS₁And the first switch is used for selecting the detection coding voltage of the driving channel. During mutual capacitance detection, the first switch S₁In a first state, the first driving capacitor C_TX1And a first coupling capacitor C_M1Position between and mutual capacitance code-printing voltage input end V_TXConnected, a first drive capacitor C_TX1And a second coupling capacitor C_M2Position between and mutual capacitance code-printing voltage input end V_TXConnected, a first drive capacitor C_TX1And a third coupling capacitor C_M3Position between and mutual capacitance code-printing voltage input end V_TXAnd (4) connecting. Then is added to the first driving capacitor C_TX1Mutual capacitance coding voltage V on electrode_TXIs generated through a first coupling capacitor C_M1A second coupling capacitor C_M2A third coupling capacitor C_M3Respectively is i₁＝V_TXs C_M1，i₂＝V_TXs C_M2，i₃＝V_TXs C_M3。

While the first operational amplifier A₁The first input end of the first switch is connected with a second switch S₂When the second switch S is turned on₂In the first state, the first operational amplifier A₁First input terminal and fixed voltage input terminal V_CMAnd (4) connecting. Second operational amplifier A₂The first input end of the first switch is connected with a second switch S₂When the second switch S is turned on₂In the first state, the second operational amplifier A₂First input terminal and fixed voltage input terminal V_CMAnd (4) connecting. Third operational amplifier A₃The first input end of the first switch is connected with a second switch S₂When the second switch S is turned on₂In the first state, the third operational amplifier A₃First input terminal and fixed voltage input terminal V_CMAnd (4) connecting.

The voltages at the two input ends of the operational amplifier are the same, so that the first induction capacitor C_RX1A second induction capacitor C_RX2And a third inductive capacitor C_RX3The voltage of the polar plates is fixed to be V_CM. Thus, the first inductive capacitance C_RX1Will not be divided into the first coupling capacitor C_M1The coming current, the second induction capacitorC_RX2Will not be divided into the second coupling capacitor C_M2The coming current, the third induction capacitor C_RX3Will not be divided into the third coupling capacitor C_M3The current coming from the transformer.

The current signal replica circuit may be a current mirror replica circuit, and specifically, each current mirror replica circuit includes a first current mirror, a second current mirror, and a third current mirror. Wherein the input end of the first current mirror is connected with the collector of the first field effect transistor, the grid of the first field effect transistor is connected with the first operational amplifier A₁Is connected to the source of the first field effect transistor and the first resistor R₁Is connected to a first resistor R₁The other end of the first current mirror is grounded, and the driving end of the first current mirror is connected with the driving voltage of the chip. The output end of the first current mirror is respectively connected with the input ends of the second current mirror and the third current mirror, so that the currents output by the output end of the second current mirror and the output end of the third current mirror are the same as the current of the input end of the first current mirror.

So that the current flowing through the first current signal replica circuit 101 is I_CM1＝V_CM/R₁-V_TXsC_M1. Similarly, the current flowing through the second current signal replica circuit 102 is I_CM2＝V_CM/R₂-V_TXsC_M2The current flowing through the third current signal replica circuit 103 is I_CM3＝V_CM/R₃-V_TXsC_M3。

After the current on the current mirror is respectively copied by 1 time or adjustable N times, two differential channels (for example: first coupling capacitor C)_M1The channel and the second coupling capacitor C_M2Channel) through a current subtraction circuit (e.g.: NMOS tube) is subtracted: i is_CM1-I_CM2＝N(V_TXsC_M2-V_TXsC_M1). Two other differential paths (e.g. second coupling capacitor C)_M2The channel and the third coupling capacitor C_M3Channel) is subtracted by the current subtraction circuit to obtain: i is_CM2-I_CM3＝N(V_TXsC_M3-V_TXsC_M2)。

Due to the first resistor R₁A second resistor R₂A third resistor R₃The same, and the coupling capacitance of each channel (e.g., the first coupling capacitance C) when the finger is not touched under normal conditions_M1A second coupling capacitor C_M2A third coupling capacitor C_M3) The same is true. Then I_CM1-I_CM2＝N(V_TXsC_M2-V_TXsC_M1)＝0，I_CM2-I_CM3＝N(V_TXsC_M3-V_TXsC_M2)＝0。

However, if a finger touches the first driving capacitor C_TX1The channel TX1 and a second sensing capacitor C_RX2At the boundary of the channel RX2, the second coupling capacitor C_M2Will become smaller by Δ C_MHowever, the coupling capacitances for the other channels remain unchanged. Then at this time, I_CM1-I_CM2＝-NV_TXsΔC_MCorresponding to, I_CM2-I_CM3＝NV_TXsΔC_M. Differential signal I_CM1-I_CM2，I_CM2-I_CM3The voltage is converted into a voltage by entering a charge amplifying circuit and amplified for ADC sampling output.

In addition, the first coupling capacitance C matched with the touch screen_M1A second coupling capacitor C_M2A third coupling capacitor C_M3It is also possible to make a slight difference, in which case the first resistance R can be adjusted₁A second resistor R₂A third resistor R₃The current is trimmed to achieve a differential current that is calibrated to 0 when there is no finger touch. However, in an actual circuit, since the adjustment of the resistance is not continuous, it is difficult to calibrate the differential current to 0 when no finger touches, or the differential current may be calibrated within a preset required range when no finger touches.

Fig. 4 is a schematic diagram of another operating state structure of the capacitance detection circuit in the embodiment shown in fig. 3. As shown in FIG. 4, when the first switch S1 is in the second state during the self-capacitance detection, the first switch S1 is turned on to the other voltage input terminal V_TX1At this time, the first driving capacitor C_TX1And a first coupling capacitor C_M1And a self-capacitance code-printing voltage input end V_DRVConnected, a first drive capacitor C_TX1And a second coupling capacitor C_M2And a self-capacitance code-printing voltage input end V_DRVConnected, a first drive capacitor C_TX1And a third coupling capacitor C_M3And a self-capacitance code-printing voltage input end V_DRVAnd (4) connecting. Optionally, when the first switch S1 is in the second state, the first driving capacitor C_TX1And a first coupling capacitor C_M1And the fourth operational amplifier A₄Is connected to the second input terminal of the fourth operational amplifier A₄First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting.

And, a first operational amplifier A₁Of the first input terminal of the first switch S₂Also goes to a second state, in which the first operational amplifier A₁First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting. Second operational amplifier A₂Of the first input terminal of the first switch S₂Also to a second state, in which the second operational amplifier A₂First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting. Third operational amplifier A₃Of the first input terminal of the first switch S₂Also to a second state, in which the third operational amplifier A₃First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting.

The first operational amplifier A is the same at both input terminals of the operational amplifier₁A second operational amplifier A₂A third operational amplifier A₃The second input ends all select self-capacitance code printing voltage V_DRVA first operational amplifier A₁A second operational amplifier A₂A third operational amplifier A₃Voltage V of the first input terminal_RX1，V_RX2，V_RX3Will follow the self-capacitance code printing voltage V_DRV. Thus, the first inductive capacitance C_RX1A second induction capacitor C_RX2And a third inductive capacitor C_RX3At a current of i₁＝V_DRVsC_RX1，i₂＝V_DRVsC_RX2，i₃＝V_DRVsC_RX3. Due to switching of TX1 electrode to V_TX1And follows the self-capacitance coding voltage V as same as RX1_DRVThen the first coupling capacitance C is changed_M1The voltage of the two end electrodes is the same, so that the current flowing through the first induction capacitor C is not generated_RX1To affect the signal on the current mirror. Similarly, the second coupling capacitor C_M2Has the same voltage between the two ends of the capacitor, thereby not generating the current flowing through the second induction capacitor C_RX2Upper current, third coupling capacitance C_M3The voltage of the two end electrodes is the same, and the third induction capacitor C can not be generated to flow_RX3The current in the capacitor.

After the current on the current mirror is respectively copied by 1 time or adjustable N times, two differential channels (for example: first inductive capacitor C)_RX1The channel and the second inductive capacitor C_RX2Channel) is subtracted by the current subtraction circuit to obtain: i is_CM1-I_CM2＝N(V_DRVs C_RX1-V_DRVs C_RX2). Two other differential channels (e.g. second sensing capacitor C)_RX2The channel and the third inductive capacitor C_RX3Channel) is subtracted by the current subtraction circuit to obtain: i is_CM2-I_CM3＝N(V_DRVsC_RX2-V_DRVsC_RX3)。

When there is no finger touch, I_CM1-I_CM2＝0，I_CM2-I_CM30. However, if the finger touches the channel RX2, the second sensing capacitor C_RX2Increase by Δ C_SThen I_CM1-I_CM2＝-NV_DRVsΔC_SCorresponding to, I_CM2-I_CM3＝NV_DRVsΔC_S. Current difference I_CM1-I_CM2，I_CM2-I_CM3The voltage is converted into a voltage by entering a charge amplifying circuit and amplified for ADC sampling output.

It can be seen that, in this embodiment, by connecting the first switch at a position between the driving capacitor and the coupling capacitor, connecting the second switch at the first input terminal of the first operational amplifier, and by switching the switch states of the first switch and the second switch, when the switch is in the first state, the driving capacitor and the coupling capacitor are connected to the mutual capacitance coding voltage input terminal, and the first input terminal of the operational amplifier is connected to the fixed voltage input terminal, so as to implement the circuit mutual capacitance detection, and when the switch is in the second state, the driving capacitor and the coupling capacitor are connected to the self-capacitance coding voltage input terminal, and the first input terminal of the operational amplifier is also connected to the self-capacitance coding voltage input terminal, so as to implement the circuit self-capacitance detection, in short, the capacitance detection circuit provided by this embodiment changes the position of the coding voltage driving by changing the position of the switch, so as to realize mutual capacitance and self-capacitance detection by using the same circuit.

Fig. 5 is a schematic structural diagram of a capacitance detection circuit according to another embodiment of the present application. As shown in fig. 5, in the capacitance detection circuit provided in this embodiment, one driving capacitor (the first driving capacitor C) may be selected_TX1) And three sensing capacitors (first sensing capacitor C)_RX1A second induction capacitor C_RX2A third inductive capacitor C_RX3) The detection circuit of (1) is exemplified.

Specifically, referring to FIG. 5, the first driving capacitor C_TX1And a first coupling capacitor C_M1Position between and mutual capacitance code-printing voltage input end V_TXConnected, a first drive capacitor C_TX1And a second coupling capacitor C_M2Position between and mutual capacitance code-printing voltage input end V_TXConnected, a first drive capacitor C_TX1And a third coupling capacitor C_M3Position between and mutual capacitance code-printing voltage input end V_TXAnd (4) connecting.

A first inductive capacitor C_RX1And a first coupling capacitor C_M1And the first operational amplifier A₁Is connected to a second input terminal (e.g., a negative input terminal), a first operational amplifier A₁A first input terminal (e.g., a positive input terminal) and a fixed voltage input terminal V_CMConnected due to the first operational amplifier A₁The voltages at the two input ends are the same, then the first induction capacitor C_RX1And firstCoupling capacitor C_M1Voltage V between_RX1Is a V_CM。

Second inductive capacitor C_RX2And a second coupling capacitor C_M2And the second operational amplifier A₂Is connected to a second input terminal (e.g., a negative input terminal), a second operational amplifier A₂A first input terminal (e.g., a positive input terminal) and a fixed voltage input terminal V_CMConnected due to the second operational amplifier A₂The voltages at the two input ends are the same, then the second induction capacitor C_RX2And a second coupling capacitor C_M2Voltage V between_RX2Is a V_CM。

Third inductive capacitor C_RX3And a third coupling capacitor C_M3And a third operational amplifier A₃Is connected to a second input terminal (e.g., a negative input terminal), and a third operational amplifier A₃And a third input terminal (e.g., a positive input terminal) and a fixed voltage input terminal V_CMConnected due to the third operational amplifier A₃The voltages at the two input ends are the same, then the third induction capacitor C_RX3And a third coupling capacitor C_M3Voltage V between_RX3Is a V_CM。

First drive capacitor C_TX1And a first coupling capacitor C_M1Is connected with a first switch S₁In the mutual capacitance detection, the first switch S₁In a first state, the first driving capacitor C_TX1And a first coupling capacitor C_M1Voltage input end V for mutual capacitance coding_TXConnected, a first drive capacitor C_TX1And a second coupling capacitor C_M2Voltage input end V for mutual capacitance coding_TXConnected, a first drive capacitor C_TX1And a third coupling capacitor C_M3Voltage input end V for mutual capacitance coding_TXAnd (4) connecting. Then is added to the first driving capacitor C_TX1Mutual capacitance coding voltage V on electrode_TXIs generated through a first coupling capacitor C_M1A second coupling capacitor C_M2A third coupling capacitor C_M3Respectively is i₁＝V_TXs C_M1，i₂＝V_TXs C_M2，i₃＝V_TXs C_M3。

While the first operational amplifier A₁The first input end of the first switch is connected with a second switch S₂When the second switch S is turned on₂In the first state, the first operational amplifier A₁First input terminal and fixed voltage input terminal V_CMAnd (4) connecting. Second operational amplifier A₂The first input end of the first switch is connected with a second switch S₂When the second switch S is turned on₂In the first state, the second operational amplifier A₂First input terminal and fixed voltage input terminal V_CMAnd (4) connecting. Third operational amplifier A₃The first input end of the first switch is connected with a second switch S₂When the second switch S is turned on₂In the first state, the third operational amplifier A₃First input terminal and fixed voltage input terminal V_CMAnd (4) connecting.

The voltages at the two input ends of the operational amplifier are the same, so that the first induction capacitor C_RX1A second induction capacitor C_RX2And a third inductive capacitor C_RX3The voltage of the polar plates is fixed to be V_CM. Thus, the first inductive capacitance C_RX1Will not be divided into the first coupling capacitor C_M1The coming current, the second induction capacitor C_RX2Will not be divided into the second coupling capacitor C_M2The coming current, the third induction capacitor C_RX3Will not be divided into the third coupling capacitor C_M3The current coming from the transformer.

The current signal replica circuit may be a current mirror replica circuit, and specifically, each current mirror replica circuit includes a first current mirror, a second current mirror, and a third current mirror. Wherein the input end of the first current mirror is connected with the collector of the first field effect transistor, the grid of the first field effect transistor is connected with the first operational amplifier A₁Is connected to the source of the first field effect transistor and the first resistor R₁Is connected to a first resistor R₁The other end of the first current mirror is grounded, and the driving end of the first current mirror is connected with the driving voltage of the chip. The output end of the first current mirror is respectively connected with the input ends of the second current mirror and the third current mirror, so that the output end of the second current mirror and the input end of the third current mirrorThe current output by the output end is the same as the current of the input end of the first current mirror.

So that the current flowing through the first current signal replica circuit 101 is I_CM1＝V_CM/R₁-V_TXsC_M1. Similarly, the current flowing through the second current signal replica circuit 102 is I_CM2＝V_CM/R₂-V_TXsC_M2The current flowing through the third current signal replica circuit 103 is I_CM3＝V_CM/R₃-V_TXsC_M3。

After the current on the PMOS tube is respectively copied by 1 time or adjustable N times, two differential channels (for example: first coupling capacitor C)_M1The channel and the second coupling capacitor C_M2Channel) is subtracted by the current subtraction circuit to obtain: i is_CM1-I_CM2＝N(V_TXsC_M2-V_TXsC_M1). Two other differential paths (e.g. second coupling capacitor C)_M2The channel and the third coupling capacitor C_M3Channel) is subtracted by the current subtraction circuit to obtain: i is_CM2-I_CM3＝N(V_TXsC_M3-V_TXsC_M2)。

In this embodiment, a fully differential charge amplifier may be adopted, and currents of two differential channels flow from the positive and negative ends of the fully differential charge amplifier.

Due to the first resistor R₁A second resistor R₂A third resistor R₃The same, and the coupling capacitance of each channel (e.g., the first coupling capacitance C) when the finger is not touched under normal conditions_M1A second coupling capacitor C_M2A third coupling capacitor C_M3) The same is true. Then I_CM1-I_CM2＝N(V_TXsC_M2-V_TXsC_M1)＝0，I_CM2-I_CM3＝N(V_TXsC_M3-V_TXsC_M2)＝0。

However, if a finger touches the first driving capacitor C_TX1The channel TX1 and a second sensing capacitor C_RX2At the boundary of the channel RX2, the second coupling capacitor C_M2Will become smaller by Δ C_MHowever, the coupling capacitances for the other channels remain unchanged. Then at this time, I_CM1-I_CM2＝-NV_TXsΔC_MCorresponding to, I_CM2-I_CM3＝NV_TXsΔC_M. Differential signal I_CM1-I_CM2，I_CM2-I_CM3The voltage is converted into a voltage by entering a charge amplifying circuit and amplified for ADC sampling output. After analog-to-digital conversion, the capacitance values of the capacitors in the touch sensor are determined through the processing circuit, and therefore the trigger position is determined according to the determined capacitance values of the capacitors.

In addition, the first coupling capacitance C matched with the touch screen_M1A second coupling capacitor C_M2A third coupling capacitor C_M3It may also be slightly different, in which case the first resistance R can be adjusted₁A second resistor R₂A third resistor R₃The current is trimmed to achieve a differential current that is calibrated to 0 when there is no finger touch.

Fig. 6 is a schematic diagram of another operating state structure of the capacitance detection circuit in the embodiment shown in fig. 5. As shown in FIG. 6, when the first switch S1 is in the second state during the self-capacitance detection, the first switch S1 is turned on to the other voltage input terminal V_TX1At this time, the first driving capacitor C_TX1And a first coupling capacitor C_M1And self-capacitance code printing voltage input end V_DRVConnected, a first drive capacitor C_TX1And a second coupling capacitor C_M2And self-capacitance code printing voltage input end V_DRVConnected, a first drive capacitor C_TX1And a third coupling capacitor C_M3And self-capacitance code printing voltage input end V_DRVAnd (4) connecting. Optionally, when the first switch is in the second state S1, the first driving capacitor C_TX1And a first coupling capacitor C_M1And a fourth operational amplifier A₄Is connected to the second input terminal of the fourth operational amplifier A₄First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting.

And, a first operational amplifier A₁Of the first input terminal of the first switch S₂Also goes to a second state, in which the first operational amplifier A₁First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting. Second operational amplifier A₂Of the first input terminal of the first switch S₂Also to a second state, in which the second operational amplifier A₂First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting. Third operational amplifier A₃Of the first input terminal of the first switch S₂Also to a second state, in which the third operational amplifier A₃First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting.

The first operational amplifier A is the same at both input terminals of the operational amplifier₁A second operational amplifier A₂A third operational amplifier A₃The second input ends all select self-capacitance code printing voltage V_DRVA first operational amplifier A₁A second operational amplifier A₂A third operational amplifier A₃Voltage V of the first input terminal_RX1，V_RX2，V_RX3Will follow the self-capacitance code printing voltage V_DRV. Thus, the first inductive capacitance C_RX1A second induction capacitor C_RX2And a third inductive capacitor C_RX3At a current of i₁＝V_DRVsC_RX1，i₂＝V_DRVsC_RX2，i₃＝V_DRVsC_RX3. Due to switching of TX1 electrode to V_TX1And follows the self-capacitance coding voltage V as same as RX1_DRVThen the first coupling capacitance C is changed_M1The voltage of the two end electrodes is the same, and the current can not flow through the first induction capacitor C_RX1To affect the signal on the current mirror. Similarly, the second coupling capacitor C_M2The voltage of the two end electrodes is the same, and the current can not flow through the second induction capacitor C_RX2Upper current, third coupling capacitance C_M3The voltage of the electrodes at both ends is the same, and no current is generatedThird inductive capacitor C_RX3The current in the capacitor.

After the current on the current mirror is respectively copied by 1 time or adjustable N times, two differential channels (for example: first inductive capacitor C)_RX1The channel and the second inductive capacitor C_RX2The channel where the current is located) is as follows after the common mode control circuit CCA absorbs the common mode current: i is_CM1-I_CM2＝N(V_DRVs C_RX1-V_DRVs C_RX2). Two other differential channels (e.g. second sensing capacitor C)_RX2The channel and the third inductive capacitor C_RX3The channel where the current is located) is as follows after the common mode control circuit CCA absorbs the common mode current: i is_CM2-I_CM3＝N(V_DRVsC_RX2-V_DRVsC_RX3). Compared with the current subtractor circuit shown in fig. 4, the differential signal output by directly subtracting the two currents has lower noise.

When there is no finger touch, I_CM1-I_CM2＝0，I_CM2-I_CM30. However, if the finger touches the channel RX2, the second sensing capacitor C_RX2Increase by Δ C_SThen I_CM1-I_CM2＝-NV_DRVsΔC_SCorresponding to, I_CM2-I_CM3＝NV_DRVsΔC_S. Current difference I_CM1-I_CM2，I_CM2-I_CM3The voltage is converted into a voltage by entering a charge amplifying circuit and amplified for ADC sampling output.

Fig. 7 is a schematic structural diagram of a capacitance detection circuit according to yet another embodiment of the present application. As shown in fig. 7, in the capacitance detection circuit provided in this embodiment, one driving capacitor (the first driving capacitor C) may be selected_TX1) And three sensing capacitors (first sensing capacitor C)_RX1A second induction capacitor C_RX2A third inductive capacitor C_RX3) The detection circuit of (1) is exemplified.

In order to simultaneously perform differential reading of all channels, it is necessary to perform differential processing on any two adjacent channels. Is composed ofThe mutual capacitance detection principle of the capacitance detection circuit provided in this embodiment can be explained by selecting one driving capacitor (the first driving capacitor C)_TX1) And three sensing capacitors (first sensing capacitor C)_RX1A second induction capacitor C_RX2A third inductive capacitor C_RX3) The detection circuit of (1) is exemplified.

Specifically, referring to FIG. 7, the first driving capacitor C_TX1And a first coupling capacitor C_M1Position between and mutual capacitance code-printing voltage input end V_TXConnected, second drive capacitor C_TX2And a second coupling capacitor C_M2Position between and mutual capacitance code-printing voltage input end V_TXConnected, third drive capacitor C_TX3And a third coupling capacitor C_M3Position between and mutual capacitance code-printing voltage input end V_TXAnd (4) connecting. Wherein the first drive capacitor C_TX1Is any one of the capacitors in the first capacitor set, the first sensing capacitor C_RX1Is any one of the second capacitor set, the second sensing capacitor C_RX2Is a first inductive capacitor C_RX1The corresponding adjacent channel induction capacitor and the third induction capacitor C_RX3Is a second inductive capacitor C_RX2The inductive capacitance of the corresponding adjacent channel.

A first inductive capacitor C_RX1And a first coupling capacitor C_M1And the first operational amplifier A₁Is connected to a second input terminal (e.g., a negative input terminal), a first operational amplifier A₁A first input terminal (e.g., a positive input terminal) and a fixed voltage input terminal V_CMConnected due to the first operational amplifier A₁The voltages at the two input ends are the same, then the first induction capacitor C_RX1And a first coupling capacitor C_M1Voltage V between_RX1Is a V_CM。

Second inductive capacitor C_RX2And a second coupling capacitor C_M2And the second operational amplifier A₂Is connected to a second input terminal (e.g., a negative input terminal), a second operational amplifier A₂A first input terminal (e.g., a positive input terminal) and a fixed voltage input terminal V_CMConnected due to secondary movementComputing amplifier A₂The voltages at the two input ends are the same, then the second induction capacitor C_RX2And a second coupling capacitor C_M2Voltage V between_RX2Is a V_CM。

Third inductive capacitor C_RX3And a third coupling capacitor C_M3And the third operational amplifier A₃Is connected to a second input terminal (e.g., a negative input terminal), and a third operational amplifier A₃And a third input terminal (e.g., a positive input terminal) and a fixed voltage input terminal V_CMConnected due to the third operational amplifier A₃The voltages at the two input ends are the same, then the third induction capacitor C_RX3And a third coupling capacitor C_M3Voltage V between_RX3Is a V_CM。

First drive capacitor C_TX1And a first coupling capacitor C_M1Is connected with a first switch S₁In the mutual capacitance detection, the first switch S₁In a first state, the first driving capacitor C_TX1And a first coupling capacitor C_M1Voltage input end V for mutual capacitance coding_TXConnected, a first drive capacitor C_TX1And a second coupling capacitor C_M2Voltage input end V for mutual capacitance coding_TXConnected, a first drive capacitor C_TX1And a third coupling capacitor C_M3Voltage input end V for mutual capacitance coding_TXAnd (4) connecting. Then is added to the first driving capacitor C_TX1Mutual capacitance coding voltage V on electrode_TXIs generated through a first coupling capacitor C_M1A second coupling capacitor C_M2A third coupling capacitor C_M3Respectively is i₁＝V_TXs C_M1，i₂＝V_TXs C_M2，i₃＝V_TXs C_M3。

While the first operational amplifier A₁The first input end of the first switch is connected with a second switch S₂When the second switch S is turned on₂In the first state, the first operational amplifier A₁First input terminal and fixed voltage input terminal V_CMAnd (4) connecting. Second operational amplifier A₂The first input end of the first switch is connected with a second switch S₂When the second switch S is turned on₂In the first state, the second operational amplifier A₂First input terminal and fixed voltage input terminal V_CMAnd (4) connecting. Third operational amplifier A₃The first input end of the first switch is connected with a second switch S₂When the second switch S is turned on₂In the first state, the third operational amplifier A₃First input terminal and fixed voltage input terminal V_CMAnd (4) connecting.

The voltages at the two input ends of the operational amplifier are the same, so that the first induction capacitor C_RX1A second induction capacitor C_RX2And a third inductive capacitor C_RX3The voltage of the polar plates is fixed to be V_CM. Thus, the first inductive capacitance C_RX1Will not be divided into the first coupling capacitor C_M1The coming current, the second induction capacitor C_RX2Will not be divided into the second coupling capacitor C_M2The coming current, the third induction capacitor C_RX3Will not be divided into the third coupling capacitor C_M3The current coming from the transformer.

The current signal replica circuit may be a PMOS transistor replica circuit, and specifically, each PMOS transistor control circuit includes a first PMOS transistor, a second PMOS transistor, and a third PMOS transistor. Specifically, the grid electrode of the first PMOS transistor is connected with the output end of the first operational amplifier, and the collector electrode of the first PMOS transistor is connected with the first resistor R₁Is connected to a first resistor R₁And the other end of the same is grounded. The grid electrode of the second PMOS tube and the grid electrode of the third PMOS tube are respectively connected with the grid electrode of the first PMOS tube, so that the currents output by the collector electrode of the second PMOS tube and the collector electrode of the third PMOS tube are the same as the current input into the grid electrode of the first PMOS tube.

So that the current flowing through the first current signal replica circuit 101 is I_CM1＝V_CM/R₁-V_TXsC_M1. Similarly, the current flowing through the second current signal replica circuit 102 is I_CM2＝V_CM/R₂-V_TXsC_M2The current flowing through the third current signal replica circuit 103 is I_CM3＝V_CM/R₃-V_TXsC_M3。

The currents on the PMOS transistors are respectively copiedAfter 1 or an adjustable N times, two differential channels (e.g. the first coupling capacitor C)_M1The channel and the second coupling capacitor C_M2Channel) is subtracted by the current subtraction circuit to obtain: i is_CM1-I_CM2＝N(V_TXsC_M2-V_TXsC_M1). Two other differential paths (e.g. second coupling capacitor C)_M2The channel and the third coupling capacitor C_M3Channel) is subtracted by the current subtraction circuit to obtain: i is_CM2-I_CM3＝N(V_TXsC_M3-V_TXsC_M2)。

Due to the first resistor R₁A second resistor R₂A third resistor R₃The same, and the coupling capacitance of each channel (e.g., the first coupling capacitance C) when the finger is not touched under normal conditions_M1A second coupling capacitor C_M2A third coupling capacitor C_M3) The same is true. Then I_CM1-I_CM2＝N(V_TXsC_M2-V_TXsC_M1)＝0，I_CM2-I_CM3＝N(V_TXsC_M3-V_TXsC_M2)＝0。

However, if a finger touches the first driving capacitor C_TX1The channel TX1 and a second sensing capacitor C_RX2At the boundary of the channel RX2, the second coupling capacitor C_M2Will become smaller by Δ C_MHowever, the coupling capacitances for the other channels remain unchanged. Then at this time, I_CM1-I_CM2＝-NV_TXsΔC_MCorresponding to, I_CM2-I_CM3＝NV_TXsΔC_M. Differential signal I_CM1-I_CM2，I_CM2-I_CM3The voltage is converted into a voltage by entering a charge amplifying circuit and amplified for ADC sampling output.

In addition, the first coupling capacitance C matched with the touch screen_M1A second coupling capacitor C_M2A third coupling capacitor C_M3It may also be slightly different, in which case the first resistance R can be adjusted₁A second resistor R₂A third resistor R₃To trim the current to achieveThe differential current is calibrated to 0 when touched by a finger.

Fig. 8 is a schematic diagram of another operating state structure of the capacitance detection circuit in the embodiment shown in fig. 7. As shown in FIG. 8, when the first switch S1 is in the second state during the self-capacitance detection, the first switch S1 is turned on to the other voltage input terminal V_TX1At this time, the first driving capacitor C_TX1And a first coupling capacitor C_M1And a self-capacitance code-printing voltage input end V_DRVConnected, a first drive capacitor C_TX1And a second coupling capacitor C_M2And a self-capacitance code-printing voltage input end V_DRVConnected, a first drive capacitor C_TX1And a third coupling capacitor C_M3And a self-capacitance code-printing voltage input end V_DRVAnd (4) connecting. Optionally, when the first switch is in the second state S1, the first driving capacitor C_TX1And a first coupling capacitor C_M1And the fourth operational amplifier A₄Is connected to the second input terminal of the fourth operational amplifier A₄First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting.

And, a first operational amplifier A₁Of the first input terminal of the first switch S₂Also goes to a second state, in which the first operational amplifier A₁First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting. Second operational amplifier A₂Of the first input terminal of the first switch S₂Also to a second state, in which the second operational amplifier A₂First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting. Third operational amplifier A₃Of the first input terminal of the first switch S₂Also to a second state, in which the third operational amplifier A₃First input terminal and self-capacitance code-printing voltage input terminal V_DRVAnd (4) connecting.

The first operational amplifier A is the same at both input terminals of the operational amplifier₁A second operational amplifier A₂A third operational amplifier A₃The second input ends all select self-capacitance code printing voltage V_DRVA first operational amplifier A₁A second operational amplifier A₂A third operational amplifier A₃Voltage V of the first input terminal_RX1，V_RX2，V_RX3Will follow the self-capacitance code printing voltage V_DRV. Thus, the first inductive capacitance C_RX1A second induction capacitor C_RX2And a third inductive capacitor C_RX3At a current of i₁＝V_DRVsC_RX1，i₂＝V_DRVsC_RX2，i₃＝V_DRVsC_RX3. Due to switching of TX1 electrode to V_TX1And follows the self-capacitance coding voltage V as same as RX1_DRVThen the first coupling capacitance C is changed_M1The voltage of the two end electrodes is the same, and the current can not flow through the first induction capacitor C_RX1To affect the signal on the current mirror. Similarly, the second coupling capacitor C_M2The voltage of the two end electrodes is the same, and the current can not flow through the second induction capacitor C_RX2Upper current, third coupling capacitance C_M3The voltage of the two end electrodes is the same, and the third induction capacitor C can not be generated to flow_RX3The current in the capacitor.

After the current on the PMOS tube is respectively copied by 1 time or adjustable N times, two differential channels (for example: a first induction capacitor C)_RX1The channel and the second inductive capacitor C_RX2Channel) is subtracted by the current subtraction circuit to obtain: i is_CM1-I_CM2＝N(V_DRVs C_RX1-V_DRVs C_RX2). Two other differential channels (e.g. second sensing capacitor C)_RX2The channel and the third inductive capacitor C_RX3Channel) is subtracted by the current subtraction circuit to obtain: i is_CM2-I_CM3＝N(V_DRVsC_RX2-V_DRVsC_RX3)。

When there is no finger touch, I_CM1-I_CM2＝0，I_CM2-I_CM30. However, if the finger touches the channel RX2, the second sensing capacitor C_RX2Increase by Δ C_SThen I_CM1-I_CM2＝-NV_DRVsΔC_SCorresponding to, I_CM2-I_CM3＝NV_DRVsΔC_S. Current difference I_CM1-I_CM2，I_CM2-I_CM3The voltage is converted into a voltage by entering a charge amplifying circuit and amplified for ADC sampling output.

In this embodiment, by connecting a first switch between the driving capacitor and the coupling capacitor, connecting a second switch at the first input terminal of the first operational amplifier, by switching the switch states of the first switch and the second switch, when the switches are in the first state, the driving capacitor and the coupling capacitor are connected with the input end of the mutual capacitance coding voltage, the first input end of the operational amplifier is connected with the input end of the fixed voltage, thereby realizing the mutual capacitance detection of the circuit, and when the switch is in the second state, the driving capacitor and the coupling capacitor are connected with the self-capacitance code printing voltage input end, the first input end of the operational amplifier is also connected with the self-capacitance code printing voltage input end, thus, the circuit self-capacitance detection is realized, in short, the capacitance detection circuit provided by the implementation changes the position of the switch, therefore, the position of the coding voltage drive is changed, and mutual capacitance and self-capacitance detection are realized by the same circuit. In addition, since the voltage drop of the PMOS transistor used in this embodiment is smaller than that of the current mirror, the capacitance detection circuit provided by this embodiment can be driven by a lower driving voltage.

In addition, an embodiment of the present application further provides a touch chip, including the capacitance detection circuit provided in any of the above embodiments.

An embodiment of the present application further provides a touch detection device, including the capacitance detection circuit provided in any of the above embodiments, where the touch detection device determines the trigger position according to the capacitance values of the capacitors determined by the capacitance detection circuit.

In addition, an embodiment of the present application further provides an electronic device, and the touch detection device provided in any of the above embodiments.

Other embodiments of the present application will be apparent to those skilled in the art from consideration of the specification and practice of the application disclosed herein. This application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the application and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the application being indicated by the following claims.

It will be understood that the present application is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the application is limited only by the appended claims.