JP4282321B2 - Impedance detection device and impedance detection method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an apparatus for detecting impedance such as capacitance of a capacitive sensor, and more particularly to an apparatus for detecting a minute capacitance with high sensitivity and high accuracy.
[0002]
[Prior art]
Conventionally, there is a detection device using an operational amplifier as an impedance detection device (see Patent Document 1 and Patent Document 2). FIG. 11 is a circuit diagram showing an apparatus for detecting a sensor capacitance as an impedance element disclosed in Patent Document 1. As shown in FIG. In this detection circuit, a capacitive sensor 92 formed of electrodes 90 and 91 is connected to an inverting input terminal of an operational amplifier 95 via a signal line 93. A feedback capacitor 96 is connected between the output terminal of the operational amplifier 95 and the inverting input terminal, and an AC voltage Vac is applied to the non-inverting input terminal. The signal line 93 is covered with a shield line 94 and is electrically shielded against disturbance noise. The shield line 94 is connected to the non-inverting input terminal of the operational amplifier 95. The output voltage Vd is taken out from the output terminal of the operational amplifier 95 through the transformer 97.
[0003]
In this detection circuit, the inverting input terminal and the non-inverting input terminal of the operational amplifier 95 are in an immediate short state, and the signal line 93 connected to the inverting input terminal and the shield line 94 connected to the non-inverting input terminal are defined. The potentials are substantially the same. As a result, the signal line 93 is guarded by the shield line 94, that is, the stray capacitance between the two 93 and 94 is canceled, and an output voltage Vd that is hardly affected by the stray capacitance is obtained.
[0004]
[Patent Document 1]
JP-A-9-280806
[0005]
[Patent Document 2]
JP 2001-324520 A
[0006]
[Problems to be solved by the invention]
By the way, for example, in a lightweight and small audio communication device typified by a mobile phone, etc., it is a compact that highly sensitively and faithfully converts an audio signal detected by a capacitive sensor such as a condenser microphone as an impedance element to be detected into an electric signal. Amplifying circuits are required.
[0007]
However, in the above prior art example, for example, it is conceivable to reduce the capacitance of the feedback capacitor 96 in order to improve the sensitivity. However, the commercially available one is only 0.5 pF, and the sensor capacitance is very small. In the present situation, sufficient sensitivity cannot be obtained.
[0008]
It is also possible to increase the AC voltage Vac to improve sensitivity, but the magnitude cannot be greater than the power supply voltage, and signal distortion occurs when used with an amplitude close to the power supply voltage. There is a problem of doing. In addition, when the AC voltage is increased, the current consumption also increases.
[0009]
Accordingly, the present invention has been made in view of such a situation, and provides a highly sensitive impedance detection device and the like used in a lightweight and small device that can accurately detect a minute impedance. For the purpose.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, an impedance detection apparatus according to the present invention is an impedance detection apparatus that outputs a detection signal corresponding to the impedance of a detected impedance element, and an impedance converter that has a high input impedance and a low output impedance; A first impedance element, an operational amplifier, an AC voltage generator for applying an AC voltage to the operational amplifier, and a signal output terminal connected to the output of the operational amplifier A resistor connected in parallel with the detected impedance element; The feedback path of the operational amplifier includes the first impedance element and the impedance converter, and one end of the detected impedance element is input to one end of the first impedance element and the impedance converter. And an AC voltage from the AC voltage generator is applied to the other end of the impedance element to be detected. The detected impedance element and the first impedance element are capacitors. It is characterized by that.
[0011]
Here, the impedance detection device further includes a phase amplitude compensation circuit connected between the AC voltage generator and the other end of the detected impedance element, and the phase amplitude compensation circuit includes the AC voltage generation. An AC voltage from the device may be input, and an output voltage obtained by adjusting at least one of the phase and amplitude of the AC voltage may be output to the other end of the detected impedance element. At this time, it is preferable that the phase amplitude compensation circuit adjusts the phase so that the phase difference between the AC voltages applied to both ends of the impedance element to be detected is 180 degrees.
[0012]
The impedance of the detected impedance element is represented by the sum of an impedance that changes according to a physical quantity to be detected and a fixed reference impedance, and the impedance detection device further includes the detected impedance element. A reference impedance cancellation circuit may be provided that applies a part or all of the flowing current corresponding to the reference impedance to one end of the detected impedance element. The reference impedance cancel circuit includes a cancel voltage generator that generates a voltage dependent on the AC voltage from the AC voltage generation circuit, and an output terminal of the cancel voltage generator and one end of the detected impedance element. What is necessary is just to set it as the structure containing the 2nd impedance element connected.
[0013]
A signal line connecting one end of the detected impedance element, one end of the first impedance element, and the input terminal of the impedance converter is covered with a shield member, and the shield member includes a potential of the signal line. A voltage having the same potential as that of the first electrode may be applied. For example, the output voltage of the impedance converter is applied to the shield member. At this time, a voltage follower may be used as the impedance converter.
[0014]
Here, the detected impedance element may be a capacitive sensor, and the first impedance element and the second impedance element may be capacitors.
It is preferable that the impedance detection device further includes a potential fixing circuit that fixes a potential at one end of the detected impedance element. The potential fixing circuit may be configured to include a resistor connected between one end of the detected impedance element and a predetermined reference potential or the signal output terminal.
[0015]
In order to achieve the above object, an impedance detection method according to the present invention is a method for detecting the impedance of a detected impedance element, wherein an AC signal is applied to each of two electrical input / output terminals of the detected impedance element. And detecting a changing impedance of the detected impedance element as a detection signal.
[0016]
Here, it is preferable to adjust the phase of each AC signal so that the phase difference is 180 degrees.
Further, among the currents flowing through the detected impedance element, a part or all of the currents corresponding to a reference impedance that does not change according to the detected physical quantity are used as the two electrical input / outputs of the detected impedance element. You may further include the process applied to either one of the terminals. That is, a part or all of the current corresponding to the reference impedance that does not change according to the detected physical quantity is applied to the detection signal output side of the two electrical input / output terminals.
[0017]
Further, the detection signal output side of the two electrical input / output terminals is fixed to a constant potential, or a shield is prepared on the detection signal output side of the two electrical input / output terminals, and the potential of the shield and the It is preferable that the electric input / output terminal on the detection signal output side has the same electric potential.
[0018]
In order to achieve the above object, an impedance detection apparatus according to the present invention is an impedance detection apparatus that outputs a detection signal corresponding to the impedance of a detected impedance element, the inverting input terminal of the detected impedance element. An operational amplifier having one end connected thereto, a first impedance element connected between an inverting input terminal and an output terminal of the operational amplifier, and an AC voltage generator for applying an AC voltage to a non-inverting input terminal of the operational amplifier And a phase / amplitude compensation circuit that adjusts at least one of the phase and amplitude of the AC voltage and outputs the adjusted AC voltage to the other end of the detected impedance element.
[0019]
Here, it is preferable that the phase amplitude compensation circuit performs the adjustment so that the phase difference between the AC voltages applied to both ends of the detected impedance element is 180 degrees.
[0020]
The detected impedance element and the first impedance element may be capacitors. However, in that case, it is preferable that the impedance detection device further includes a resistor connected in parallel with the detected impedance element.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a circuit diagram of a sensor capacitance detection device 10 as an impedance detection device according to an embodiment of the present invention. The sensor capacitance detection device 10 includes an AC voltage generator 11 that generates an AC voltage, a resistor (R1) 12, a resistor (R2) 13, a first operational amplifier 14, and a feedback capacitor 15 (Cf) 15 as a first impedance element. The capacitive sensor 17 as the detected impedance element and the second operational amplifier 16 as the impedance converter are configured to output a detection signal (voltage Vout) corresponding to the capacitance of the capacitive sensor 17 from the signal output terminal 20. .
[0022]
The capacitive sensor 17 is a capacitor that is a detection target of the sensor capacitance detection device 10 and detects various physical quantities using a change in impedance (here, capacitance Cs) such as a capacitor microphone.
[0023]
One end of the AC voltage generator 11 is connected to a predetermined potential (GND in this example), and a constant AC voltage (voltage Vin, angular frequency ω) is generated from the other end (output terminal). A resistor (R 1) 12 is connected between the output terminal of the AC voltage generator 11 and the inverting input terminal of the first operational amplifier 14.
[0024]
The first operational amplifier 14 is a voltage amplifier having an extremely high input impedance and open loop gain. Here, the non-inverting input terminal is connected to a predetermined potential (GND in this example), and the non-inverting input terminal and the inverting input terminal are connected. Is an inverting amplifier that is in the short circuit state. A feedback capacitor 15, a second operational amplifier 16, and a resistor (R 2) 13 are provided as circuit elements between the feedback path of the first operational amplifier 14, that is, between the output terminal and the inverting input terminal of the first operational amplifier 14. They are connected in series in order. In this case, the feedback path is a negative feedback path as shown in the figure, but it is preferable because it is resistant to noise and has operational stability.
[0025]
The second operational amplifier 16 is one of impedance converters having an inverting input terminal and an output terminal connected, an extremely high input impedance, and an extremely low output impedance. Here, a voltage follower having a voltage gain of 1 is used. It is composed. One end of a capacitive sensor 17 is connected to the non-inverting input terminal 21 of the second operational amplifier 16 via a signal line 23, while the other end (terminal 24) of the capacitive sensor 17 generates an AC voltage. Connected to the output terminal of the device 11. To the output terminal of the first operational amplifier 14, the output signal of the sensor capacitance detection device 10, that is, the detection signal Vout corresponding to the impedance (here, capacitance) of the capacitive sensor 17 as the detected impedance element is output. A signal output terminal 20 is connected.
[0026]
The operation of the sensor capacity detection device 10 configured as described above is as follows.
Attention is focused on an inverting amplifier circuit including a resistor (R1) 12, a resistor (R2) 13, a first operational amplifier 14, and the like. Both input terminals of the first operational amplifier 14 are in the short circuit state and have the same potential (for example, 0 V), and the input impedance thereof is extremely high, and no current flows. Therefore, all of the current flowing through the resistor (R1) 12 flows through the resistor (R2) 13. From these facts, if the output voltage of the second operational amplifier 16 is V2,
V2 =-(R2 / R1) · Vin (Formula 1)
It becomes. Further, the second operational amplifier 16 constitutes a voltage follower, and both of its input terminals are in an immediate short state, and the input voltage (voltage of the non-inverting input terminal 21) V1 and the output voltage (inverting input terminal and output terminal 22). Since the voltage V2 is equal, the input voltage V1 is
V1 = V2
=-(R2 / R1) · Vin (Formula 2)
Holds.
[0027]
Here, focusing on the capacitive sensor 17, the voltage V1 is applied to one end (signal line 23), and the output voltage Vin of the AC voltage generator 11 is applied to the other end (terminal 24). Therefore, the potential difference Vcs at both ends of the capacitive sensor 17 is
Vcs = (1 + R2 / R1) · Vin (Formula 3)
It becomes. By the way, since the input impedance of the second operational amplifier 16 is very high, all of the current flowing through the capacitive sensor 17 flows through the feedback capacitor 15.
jωCs · Vcs = jωCf · (V1−Vout) (Formula 4)
Is established. By substituting Equation 2 and Equation 3 into Equation 4, the voltage Vout of the signal output terminal 20 is
Vout =-{(1 + Cs / Cf). (R2 / R1) + (Cs / Cf)}. Vi (Formula 5)
It becomes.
[0028]
As can be seen from Equation 5, the voltage Vout of the detection signal output from the signal output terminal 20 of the sensor capacitance detection device 10 is a value depending on the capacitance Cs of the capacitive sensor 17. Therefore, the capacitance Cs can be specified by performing various signal processing on the voltage Vout. Further, as can be seen from the fact that the angular frequency ω is not included in Equation 5, the voltage Vout of the detection signal does not depend on the frequency of the AC signal Vin from the AC voltage generator 11. As a result, a sensor capacitance detection device capable of detecting the capacitance of the capacitive sensor 17 without depending on the frequency of the AC voltage applied to the capacitive sensor 17 (having no frequency-dependent characteristics in the circuit) is realized. Is done. Therefore, for a capacitive sensor 17 such as a condenser microphone whose capacitance value changes at a certain frequency (voice band), the capacitance value is directly specified from the voltage value without correcting the frequency of the detected signal. It becomes possible.
[0029]
Here, the sensor capacitance detection device 10 is compared with a device in which one end (terminal 24) of the capacitive sensor 17 is connected to a reference potential (GND or the like).
In the first place, even if one end (terminal 24) of the capacitive sensor 17 is connected to a reference potential (GND or the like) in the sensor capacitance detecting device 10, the capacitance Cs of the capacitive sensor 17 is connected to the signal output terminal 20. A voltage dependent on is output. The output voltage Vout ′ is
Vout '=-(1 + Cs / Cf). (R2 / R1) .Vin (Formula 6)
It is. As can be seen from a comparison between Equation 6 and Equation 5, the sensor capacitance detection device 10 according to the present embodiment is compared with a device in which one end (terminal 24) of the capacitive sensor 17 is connected to a reference potential (GND or the like). , Cs / Cf increases the gain.
[0030]
For example, when R2 / R1 = Cs / Cf = 1, the sensor capacitance detection device 10 is 1 in comparison with a device in which one end (terminal 24) of the capacitive sensor 17 is connected to a reference potential (GND or the like). .5 times greater sensitivity. That is, the sensitivity can be improved without increasing the amplitude of the AC signal Vin from the AC voltage generator 11.
[0031]
The first operational amplifier 14 is for obtaining a sufficient gain, and the stability of the operation is improved by connecting the non-inverting input terminal to a reference potential (here, GND). Further, since the gain of the second operational amplifier 16 is 1, and the voltages of the inverting input terminal and the output terminal are determined, the voltage of the non-inverting input is determined. In this way, the amplifier for obtaining sufficient gain and the amplifier for determining the voltage are divided, so that the stability of each can be improved and the calculation error can be greatly reduced. ing.
[0032]
The present invention is not limited to the sensor capacitance detection device 10 shown in FIG. 1, and various circuits for further improving the performance may be added. An example of the circuit is shown below.
[0033]
FIG. 2 shows a signal for connecting the output terminal of the AC voltage generator 11 and the capacitive sensor 17 (terminal 24) as the detected impedance element in the sensor capacitance detection apparatus 10 as the impedance detection apparatus shown in FIG. A sensor capacitance detection device 30 corresponding to a circuit in which a phase / amplitude compensation circuit 31 is inserted in the line is shown.
[0034]
The phase / amplitude compensation circuit 31 is, for example, a phase adjustment circuit as shown in FIG. 3, and an input signal (AC voltage) so that the phase difference between the signals applied to both ends of the capacitive sensor 17 is reversed. This is a circuit that changes the phase of the output signal of the generator 11 and outputs it to the capacitive sensor 17 (terminal 24).
[0035]
That is, if the voltages of the two signals applied to both ends of the capacitive sensor 17 are Va · sin ωt and Vb · sin (ωt + θ), respectively, the potential difference Va−b is
Va−b = Va · sin ωt−Vb · sin (ωt + θ)
= Va · sin ωt−Vb · (sin ωt · cos θ + cos ωt · sin θ)
= (Va−Vb · cos θ) · sin ωt−Vb · cos ωt · sin θ
It is. This is maximum when cos θ = −1 and sin θ = 0, that is, θ = π (180 degrees). Therefore, the phase / amplitude compensation circuit 31 adjusts the phase of the input signal to improve the sensitivity of the sensor capacitance detection device 30, and the phase of the signal voltage applied to both ends of the capacitive sensor 17 is reversed. Is working.
[0036]
FIG. 4 shows a cancel capacitor (Cc) as a cancel impedance at one end (signal line 23) of a capacitive sensor 17 as a detected impedance element in the sensor capacitance detection device 10 as an impedance detection device shown in FIG. 4 shows an impedance detection device (sensor capacitance detection device 40) including a reference impedance cancellation circuit to which an AC signal generator (V3) 42 for applying an AC voltage via 41 is added.
[0037]
Now, the capacitance Cs of the capacitive sensor 17 is composed of the sum of a steady value (reference capacitance Cd) and a change (change capacitance ΔC) that changes in accordance with a physical quantity such as sound, that is,
Cs = Cd + ΔC
Then, the cancel capacitor (Cc) 41 and the AC signal generator (V3) 42 cancel the output of the signal corresponding to the reference capacitance Cd of the capacitive sensor 17 from the signal output terminal 20, that is, the reference capacitance. It functions as a circuit for canceling Cd.
[0038]
Specifically, among the current flowing through the capacitive sensor 17 from one end (signal line 23) to the other end (terminal 24), a current corresponding to the reference capacitance Cd of the capacitive sensor 17 and an AC signal generator ( The capacity of the cancel capacitor (Cc) 41 and the voltage of the AC signal generator (V3) 42 are set so that the current supplied from the V3) 42 to the signal line 23 via the cancel capacitor (Cc) 41 becomes equal. Keep it. Then, the current flowing through the feedback capacitor 15 becomes equal to the current corresponding to the change capacitance ΔC in the capacitive sensor 17.
jωCf · (V1−Vout) = jωΔC · Vcs (Expression 7)
Is established. Then, by substituting Equation 2 and Equation 3 into Equation 7, the voltage Vout of the signal output terminal 20 is
Vout = − {(1 + ΔC / Cf) · (R2 / R1) + (ΔC / Cf)} · Vi (Equation 8)
It becomes. As can be seen from Equation 8, the voltage Vout of the detection signal output from the signal output terminal 20 of the sensor capacitance detection device 40 is a change capacitance ΔC that changes according to a change in physical quantity among the capacitance Cs of the capacitive sensor 17. Since the value depends only on this and no unnecessary offset component is included, the amplitude can be increased and the sensitivity can be easily improved.
[0039]
As the cancel capacitor (Cc) 41 and the AC signal generator (V3) 42 satisfying the above-mentioned conditions, for example, the capacitance Cc of the cancel capacitor (Cc) 41 is
Cc = Cd
The AC signal generator (V3) 42 may be an inverting amplifier circuit that receives the output signal from the AC voltage generator 11 and outputs the following voltage V3.
[0040]
V3 =-(1 + 2, R2 / R1), Vin
Here, the current flowing through the reference capacitor Cd and the current flowing through the cancellation capacitor Cc are set to be equal, but the sensitivity is improved by setting the current supply so as to supplement a part of the current flowing through the reference capacitor Cd. Can be expected.
[0041]
FIG. 5 shows a sensor capacitance detection device 10 as the impedance detection device shown in FIG. 1 in which the signal line 23 is covered with a shield line 25 and the shield line 25 is connected to the output terminal 22 of the second operational amplifier 16. 1 shows a sensor capacitance detection device 50 corresponding to the circuit. The shield line 25 is a conductor that covers the signal line 23 that connects the feedback capacitor 15, the second operational amplifier 16, and the capacitive sensor 17.
[0042]
With this connection, the signal line 23 that transmits a minute signal from the capacitive sensor 17 is guarded by the shield line 25 to which a voltage having the same potential as the signal line 23 is applied, and the influence of stray capacitance is suppressed. At the same time, the entrance of noise from the outside is shielded, and the capacitance can be detected with high accuracy. Therefore, when the capacitive sensor 17, the feedback capacitor 15, and the second operational amplifier 16 (detection circuit) are arranged apart from each other, or when stray capacitance in the signal line 23 becomes a problem, such a sensor capacitance is used. The detection device 50 is effective.
[0043]
6 shows a sensor capacitance detection device 10 as the impedance detection device shown in FIG. 1, in which one end (signal line 23) of the capacitive sensor 17 is connected to a predetermined potential (Vs) 62 through a resistor (R3) 61. The sensor capacity | capacitance detection apparatus 60 equivalent to the made circuit is shown.
[0044]
In FIG. 6A, the resistor (R3) 61 is a high resistance having a high resistance value such that the current flowing therethrough is at least smaller than the current flowing through the capacitive sensor 17. This high resistance is, for example, a resistance of 100 MΩ. The predetermined potential (Vs) 62 is, for example, a reference potential such as GND or 1/2 · VDD (VDD is a power supply voltage). The resistor (R3) 61 and the predetermined potential (Vs) 62 function as a potential fixing circuit that fixes the potential of the signal line 23 and stabilizes the operation of the detection circuit.
[0045]
That is, in the sensor capacitance detection device 10 shown in FIG. 1, the signal line 23 is connected to one end of the feedback capacitor 15, one end of the capacitive sensor 17, and the non-inverting input terminal 21 of the second operational amplifier 16, and floats. It is possible to enter an unstable state where the potential is not deterministically determined. Therefore, in order to avoid such an unstable state, the signal line 23 is connected to a predetermined potential (Vs) 62 via a resistor (R3) 61 having a high resistance value, and the potential is fixed.
[0046]
In FIG. 6B, instead of the predetermined potential (Vs), one end (signal line 23) of the capacitive sensor 17 is connected to Vout 20 via a resistor (R3) 63. As a result, the DC potential of the signal line 23 is stabilized.
FIG. 7 is a diagram showing a simulation result for comparing the sensitivity of the sensor capacity detection device 60 and the conventional sensor capacity detection device shown in FIG. FIG. 7A shows the sensitivity of the sensor capacitance detection device 60 and the conventional device with respect to various values of the sensor capacitance Cs (the capacitance of the capacitive sensor 17 of the present embodiment and the capacitance sensor 92 of the conventional device), that is, the input. 7B is a table showing the ratio of the output voltage Vout (and the output voltage Vd of the conventional device) to the AC voltage Vin (and the AC voltage Vac of the conventional device), and FIG. 7B is shown in FIG. It is the graph which plotted the result.
[0047]
In this simulation, in the sensor capacitance detection device 60, R1 = R2 = 1 kΩ, Cf = 1 pF, R3 = 1 GΩ, Vs, and the potential at the electrode 90 of the conventional device = 1/2 Vdd (half potential of the power supply voltage), The frequency of the input signals Vin and Vac is 100 kHz.
[0048]
As can be seen from FIG. 7B, the sensor capacitance detection device 60 in the present embodiment has a detection sensitivity that is approximately 1.5 times higher than that of the conventional sensor capacitance detection device.
The sensor capacity detection device according to the present invention has been described based on the embodiments. However, the present invention is not limited to these embodiments.
[0049]
For example, the second operational amplifier 16 in the present embodiment constitutes a voltage follower with a voltage gain of 1, but instead, the input impedance is high and the output impedance is low as shown in FIG. It may be an impedance converter.
[0050]
Further, the capacitive sensor connected as the capacitive sensor 17 is not limited to the condenser microphone, but includes an acceleration sensor, a seismometer, a pressure sensor, a displacement sensor, a displacement meter, a proximity sensor, a touch sensor, an ion sensor, a humidity sensor, and a raindrop. Sensor, snow sensor, lightning sensor, alignment sensor, contact failure sensor, shape sensor, end point detection sensor, vibration sensor, ultrasonic sensor, angular velocity sensor, liquid level sensor, gas sensor, infrared sensor, radiation sensor, water level gauge, freezing sensor All transducers (devices) that detect various physical quantities using changes in capacitance, such as known capacitive sensors such as moisture meters, vibrometers, charge sensors, and printed circuit board inspection machines, are included.
[0051]
Further, the sensor capacitance detection device 10 in the present embodiment is configured by two operational amplifiers (the first operational amplifier 14 and the second operational amplifier 16), but may be configured by one operational amplifier.
[0052]
FIG. 9 is a circuit diagram of an impedance detection apparatus 70 according to the present invention configured by one operational amplifier. The impedance detector 70 includes an operational amplifier 73, a detected impedance element (impedance is Zs) 71 such as a capacitive sensor having one end connected to the inverting input terminal of the operational amplifier 73, and the inverting input terminal and output terminal of the operational amplifier 73. A feedback impedance element (impedance is Zs) 72 such as a capacitor connected between and an AC voltage generator 11 connected between a non-inverting input terminal of the operational amplifier 73 and a reference potential (here, ground); A phase / amplitude compensation circuit (voltage gain is −A times) 31 connected between the non-inverting input terminal of the operational amplifier 73 and the other end of the detected impedance element 71 is constituted.
[0053]
In this impedance detection device 70, the inverting input terminal and the non-inverting input terminal of the operational amplifier 73 are in an immediate short state, and the inverting input terminal and the non-inverting input terminal have substantially the same potential. Accordingly, one end of the detected impedance element 71 (a portion connected to the inverting input terminal of the operational amplifier 73) has the same potential as the AC voltage Vin from the AC voltage generator 11. On the other hand, the AC voltage Vin from the AC voltage generator 11 is multiplied by −A by the phase / amplitude compensation circuit 31, and the voltage (−A · Vin) is applied to the other end of the detected impedance element 71. Therefore, a voltage of (1 + A) · Vin is applied to both ends of the detected impedance element 71.
[0054]
Here, for example, assuming that A = 1, that is, the phase / amplitude compensation circuit 31 is adjusted so that the phase difference between the AC voltages applied to both ends of the detected impedance element 71 is 180 degrees, the calculation is performed. The output voltage Vout of the amplifier 73 is
Vout = (1 + 2 ・ Zf / Zs) ・ Vin
It becomes. Incidentally, as in the conventional circuit shown in FIG. 11, one end of the detected impedance element 71 (terminal opposite to the terminal connected to the inverting input terminal of the operational amplifier) is connected to the ground. Then, the output voltage V′out in that case is
V'out = (1 + Zf / Zs) · Vin
It becomes. As can be seen by comparing these two output voltages Vout and V′out, the component (2 · Zf / Zs) that depends on the impedance of the impedance element 71 to be detected out of the output voltage Vout of the impedance detection device 70 is: Compared to the conventional circuit, it is doubled. Therefore, the impedance detection device 70 can detect the impedance of the detected impedance element 71 with higher sensitivity than the conventional circuit.
[0055]
As described above, the present invention can be realized as an impedance detection device including one operational amplifier, or can be realized as an impedance detection device including two operational amplifiers. In other words, the circuit portion in the dotted frame in the impedance detection device using two operational amplifiers shown in FIG. 10A and the impedance detection device using one operational amplifier shown in FIG. The circuit portion in the dotted line frame in FIG. 6 is common in that it is a converter that converts impedance into voltage. For any impedance detection device, the characteristic idea of the present invention, that is, by applying an AC voltage having a phase difference of 180 degrees to both ends of the detected impedance element, the impedance of the detected impedance element can be increased with greater sensitivity. The idea of detecting can be applied.
[0056]
However, the impedance detection apparatus using the two operational amplifiers shown in FIG. 10A has two operational amplifiers that share the functions, that is, one input terminal is connected to the reference potential and is in a stable state. Since the operational amplifier for amplifying the signal and the operational amplifier for ensuring the state of the image short circuit without amplifying the signal are provided, these two functions can be achieved with one operational amplifier. Compared with the realized impedance detection device shown in FIG. 10B, the device operates more stably and can detect a minute impedance change with high accuracy.
[0057]
In the impedance detection device 70 shown in FIG. 9, the detected impedance element 71 and the feedback impedance element 72 are not limited to capacitors, and may be other impedance elements such as resistors. However, when the detected impedance element 71 is a capacitor such as a capacitive sensor, the feedback impedance element 72 is also preferably a capacitor. In that case, since the connection point between the detected impedance element 71 and the feedback impedance element 72 can be in a DC floating state, for example, by connecting a resistor in parallel with the detected impedance element 71, the operation of the circuit can be performed. Can be stabilized.
[0058]
【The invention's effect】
As is apparent from the above description, the impedance detection device according to the present invention applies an AC voltage to the operational amplifier via a resistor, and connects the first impedance element and the impedance converter to the negative feedback path of the operational amplifier. In addition, the impedance of the detected impedance element is detected by connecting the first impedance element and the impedance converter and one end of the detected impedance element with a signal line.
[0059]
As a result, all of the current flowing through the detected impedance element flows through the first impedance element, and an accurate signal corresponding to the impedance value of the detected impedance element is output to the output terminal of the operational amplifier. Can be detected. Since the non-inverting input terminal of the operational amplifier is connected to a predetermined potential and one potential of the input terminal is fixed, the operational amplifier operates stably, the operational error is reduced, and the noise included in the detection signal Is suppressed.
[0060]
Moreover, the impedance detection apparatus according to the present invention applies an alternating voltage whose phase is inverted to both ends of the detected impedance element. Therefore, the impedance value of the detected impedance element can be detected with higher sensitivity. And since the sensitivity is improved without increasing the AC voltage, the problem of increasing current consumption and the problem of causing signal distortion do not occur.
[0061]
Further, by adding a circuit for canceling the reference impedance of the detected impedance element, it is possible to obtain an output signal that depends only on the impedance that changes according to the physical quantity among the impedances of the detected impedance element. As a result, the output signal does not include an unnecessary offset component, and only a component corresponding to a change in physical quantity is included, so that detection sensitivity can be improved.
[0062]
In addition, the signal line connecting the detected impedance element and the detection circuit is covered with a shield member, and by applying a guard voltage having the same potential as the signal line to the shield member, the floating impedance of the signal line is canceled, Noise entry from the outside can be blocked.
[0063]
Connect a signal line that connects a capacitive sensor using a capacitive sensor as a detected impedance element and a capacitor as a first impedance element to the detection circuit to a predetermined reference potential via a resistor having a high resistance value. Thus, the potential of the signal line can be fixed. As a result, the potential of the signal line is prevented from being floated, and the operation of the circuit is stabilized.
[0064]
As described above, according to the present invention, it is possible to detect a minute capacitance or capacitance change of an impedance type sensor with high sensitivity and high accuracy without increasing current consumption. It is suitable as a detection circuit for a capacitive sensor provided in an electronic device, and its practical value is extremely high.
[Brief description of the drawings]
FIG. 1 is a circuit diagram of a sensor capacitance detection device according to an embodiment of the present invention.
2 is a circuit diagram of an apparatus in which a phase / amplitude compensation circuit is added to the sensor capacitance detection apparatus shown in FIG. 1;
FIG. 3 is a circuit diagram showing an example of a phase / amplitude compensation circuit;
4 is a circuit diagram of a device in which a circuit for canceling the reference capacitance of the capacitive sensor is added to the sensor capacitance detection device shown in FIG. 1;
5 is a circuit diagram of a device in which a shield member and a connection for guarding a signal line are added to the sensor capacitance detection device shown in FIG. 1; FIG.
6 is a circuit diagram of a device in which a circuit for fixing the potential of a signal line is added to the sensor capacitance detection device shown in FIG. 1;
7 is a diagram showing a simulation result for comparing the sensitivity of the sensor capacitance detection device shown in FIG. 6 and the conventional sensor capacitance detection device.
FIG. 8 is a circuit diagram showing an example of an impedance converter in place of the second operational amplifier of the sensor capacitance detection device of the present invention.
FIG. 9 is a circuit diagram of an impedance detection apparatus according to the present invention constituted by one operational amplifier.
FIG. 10 is a circuit diagram showing the commonality between an impedance detection device comprising one operational amplifier and an impedance detection device comprising two operational amplifiers according to the present invention.
FIG. 11 is a circuit diagram of a conventional sensor capacitance detection device.
[Explanation of symbols]
10, 30, 40, 50, 60 Sensor capacity detection device
11 AC voltage generator
12, 13, 61 resistance
14 First operational amplifier
15 Feedback capacitor
16 Second operational amplifier
17 Capacitive sensor
20 Signal output terminal
21 Non-inverting input terminal of second operational amplifier
22 Output terminal of the second operational amplifier
23 Signal line
24 One end of capacitive sensor
25 Shielded wire
70 Impedance detection device
71 Detected impedance element
72 Feedback impedance element
73 Operational Amplifier

Claims (19)

An impedance detection device that outputs a detection signal corresponding to the impedance of a detected impedance element,
An impedance converter having a high input impedance and a low output impedance, a first impedance element, an operational amplifier, an AC voltage generator for applying an AC voltage to the operational amplifier, and a signal output terminal connected to the output of the operational amplifier And a resistor connected in parallel with the detected impedance element ,
The feedback path of the operational amplifier includes the first impedance element and the impedance converter,
One end of the first impedance element and an input terminal of the impedance converter are connected to one end of the detected impedance element,
An AC voltage from the AC voltage generator is applied to the other end of the detected impedance element ,
The impedance detecting apparatus , wherein the detected impedance element and the first impedance element are capacitors . The impedance detection device further includes a phase amplitude compensation circuit connected between the AC voltage generator and the other end of the detected impedance element,
The phase amplitude compensation circuit receives an AC voltage from the AC voltage generator and outputs an output voltage obtained by adjusting at least one of the phase and amplitude of the AC voltage to the other end of the detected impedance element. The impedance detection device according to claim 1. The impedance detection according to claim 2, wherein the phase amplitude compensation circuit adjusts the phase so that a phase difference between respective AC voltages applied to both ends of the impedance element to be detected is 180 degrees. apparatus. The impedance of the detected impedance element is represented by the sum of an impedance that varies according to a physical quantity to be detected and a fixed reference impedance,
The impedance detection device further includes a reference impedance cancellation circuit that applies a part or all of the current corresponding to the reference impedance to one end of the detected impedance element among the current flowing through the detected impedance element. The impedance detection apparatus according to any one of claims 1 to 3, wherein The reference impedance cancellation circuit is
A cancel voltage generator for generating a voltage depending on the AC voltage from the AC voltage generating circuit;
The impedance detection apparatus according to claim 4, further comprising a second impedance element connected between an output terminal of the cancel voltage generator and one end of the detected impedance element. A signal line connecting one end of the detected impedance element, one end of the first impedance element, and an input terminal of the impedance converter is covered with a shield member,
The impedance detection apparatus according to claim 1, wherein a voltage having the same potential as the potential of the signal line is applied to the shield member. The impedance detection apparatus according to claim 6, wherein an output voltage of the impedance converter is applied to the shield member. The impedance detection apparatus according to claim 1, wherein the impedance converter is a voltage follower. The impedance detection apparatus according to any one of claims 1 to 8, wherein the detected impedance element is a capacitive sensor, and the first impedance element and the second impedance element are capacitors. The impedance detection apparatus according to claim 9, further comprising a potential fixing circuit that fixes a potential at one end of the detected impedance element. The impedance detection apparatus according to claim 10, wherein the potential fixing circuit includes a resistor connected between one end of the impedance element to be detected and a predetermined reference potential or the signal output terminal. A method for detecting the impedance of an impedance element to be detected using the impedance detection device according to claim 1 ,
An impedance detection method comprising a step of applying an AC signal to each of the two electrical input / output terminals of the detected impedance element, and detecting a changing impedance of the detected impedance element as a detection signal. The impedance detection method according to claim 12, wherein the phase of each of the AC signals is adjusted so that the phase difference is 180 degrees. Of the current flowing through the detected impedance element, a part or all of the current corresponding to the reference impedance that does not change according to the detected physical quantity is supplied to the two electrical input / output terminals of the detected impedance element. The impedance detection method according to claim 12, further comprising a step of applying the detection signal to the detection signal output side . 15. A part or all of the current corresponding to a reference impedance that does not change according to the detected physical quantity is applied to the detection signal output side of the two electrical input / output terminals. The impedance detection method described. The impedance detection method according to any one of claims 12 to 15, wherein the detection signal output sides of the two electrical input / output terminals are fixed to a constant potential. A shield is prepared on the detection signal output side of the two electrical input / output terminals, and the potential of the shield and the potential of the electrical input / output terminal on the detection signal output side are set to the same potential. The impedance detection method according to any one of 12 to 16. An impedance detection device that outputs a detection signal corresponding to the impedance of a detected impedance element,
An operational amplifier having one end of the detected impedance element connected to an inverting input terminal;
A first impedance element connected between an inverting input terminal and an output terminal of the operational amplifier;
An AC voltage generator for applying an AC voltage to a non-inverting input terminal of the operational amplifier;
A phase amplitude compensation circuit that adjusts at least one of the phase and amplitude of the AC voltage and outputs the adjusted AC voltage to the other end of the detected impedance element ;
A resistor connected in parallel with the detected impedance element;
The impedance detecting apparatus , wherein the detected impedance element and the first impedance element are capacitors . The impedance detection apparatus according to claim 18, wherein the phase amplitude compensation circuit performs the adjustment so that a phase difference between the AC voltages applied to both ends of the impedance element to be detected is 180 degrees. .

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