DE19708330C1 - Evaluation method for capacitive sensor esp pressure sensor - Google Patents

Abstract

the method involves using a reference capacitor, a measurement capacitor with a measurement capacitance influenced by the measured physical parameter and a periodic, essentially symmetrical input signal (U0). An intermediate signal (U1) is produced by integrating the input signal in the measurement or reference capacitor. The measurement signal (U2) is produced by differentiating the intermediate signal in the reference or measurement capacitor.

Description

The invention relates to an evaluation method for capacitive sensors, in particular for pressure sensors, using a reference capacitor, a measuring capacitor with a measuring capacitance which can be influenced by a physical measured variable and a periodic, essentially symmetrical input signal U ₀ .

Various evaluation methods for capacitive sensors are known. Here it is always about the capacity value or a capacity change of a kapa qualitative or quantitative citation component. Mostly it is in the capacitive component around a capacitor or around the electrode capacitive proximity switch. A second capacitive building is also common element, whose capacity value is used as a reference variable for evaluation is used. In the following, instead of a capacitive component from spoken a capacitor, without being restricted to a Kon is connected in the narrower sense. In the context of the invention under Kon capacitor also understood the electrode of a capacitive proximity switch.

In known evaluation methods for capacitive sensors, as for example in described in DE 30 07 426 A1, the capacity value sought is for example determined via a bridge circuit or as a frequency-determining element used in an oscillator circuit. In another evaluation method like this is known from DE 44 23 907 A1 and DE 44 35 877 A1, the charge transport measured when charging or discharging a capacitor and so the capaci value or the change in capacitance compared to a reference capacitor certainly. The known evaluation methods for capacitive sensors have types specifically different advantages and disadvantages.

In the evaluation method on which the invention is based (DE 44 35 877 A1), are the reference capacitor and the measuring capacitor by means of a common Men load and unload the power source at the same time, the electricity generated a variety ches the actual charging current. This is necessary to avoid the influence of the parasitic leakage currents and capacitances in the overall circuit should be as small as possible hold. Only immediately before the capacitors does the charge actually become required charging current is branched off using a current divider. Generating the multiple  of the charging current together with the power requirement of the clocked power source itself and that of a necessary linearization measure includes an interference-proof connection application in a two-wire transmitter for 4 to 20 mA almost.

The invention is therefore based on the object of an evaluation method for kapa specify zitive sensors that have a low power consumption, with few Components can be realized and has a fast response time.

The evaluation method according to the invention, in which the above-mentioned object is achieved, is now initially and essentially characterized in that by means of the reference capacitor or the measuring capacitor by integrating the input signal U ₀ an intermediate signal U ₁ and by means of the measuring capacitor or the reference capacitor by differentiating the Intermediate signal U _1, the measurement signal U _{2 is} generated.

In the evaluation method according to the invention, the input signal U ₀ is preferably supplied in the form of a low-impedance square-wave voltage to the reference capacitor or the measuring capacitor.

The square wave voltage is integrated into a triangular voltage

converted, where C ₁ represents the capacity required for integration. Subsequently, the triangular signal obtained in this way is differentiated, again causing a square-wave voltage

arises. Here C _{2 is} the capacity required for differentiation.

In the evaluation method according to the invention, both the reference capacitor and the measuring capacitor can be used to integrate the input signal U ₀ and, accordingly, the measuring capacitor or the reference capacitor can be used to differentiate the intermediate signal U ₁ . However, the reference capacitor is preferably used to integrate the input signal U ₀ and the measuring capacitor is used to differentiate the intermediate signal U ₁ . In equations (1) and (2), C ₁ then corresponds to the capacitance of the reference capacitor and C ₂ corresponds to the capacitance of the measuring capacitor. The value of the measurement signal U ₂ is therefore dependent on the ratio of C ₂ to C ₁ , ie on the ratio of the measurement capacitance to the reference capacitance.

According to a further teaching of the invention, the input signal U ₀ and the measurement signal U ₂ can be compared with one another in a subtractor, and thus the voltage swing _Δ U can be determined. The following applies

_Δ U = U ₂ - U ₀ (3)

The evaluation method according to the invention for capacitive sensors is advantageously further characterized in that the input signal U ₀ and the measurement signal U ₂ are given to the subtra here during the positive and the negative half of the period and then to determine the voltage swing _Δ U the partial result during the negative half period _Δ U⁻ the subtotal currency rend subtracting the positive half cycle _Δ U⁺. The differential voltage thus becomes during the positive half of the period

_Δ U⁺ = U ₂ ⁺ - U ₀ ⁺ (4)

and the differential voltage during the negative half of the period

_Δ U⁻ = U ₂ ⁻ - U ₀ ⁻ (5)

recorded separately. The two differential voltages are then subtracted from one another, since they have a different sign. So you get for the voltage swing

This type of evaluation has the advantage that offset errors caused by Ope ration amplifiers occur, compensate each other. In addition, both the charging and discharging cycle of the reference capacitor and the measuring capacitor sators used for signal evaluation.

Ideally, U ₀ ⁺ = -U ₀ ⁻ = U ₀ and R ₁ = R ₂ = R, so that the following relationship results for the voltage swing:

The voltage swing is therefore only dependent on the input signal U ₀ and on the ratio of the measuring capacitance to the reference capacitance.

In detail, there are now a multitude of possibilities for the inventive method To further develop evaluation methods for capacitive sensors. Reference is made to this on the one hand on the claims subordinate to claim 1, on the other hand to the description of preferred embodiments in connection with the Drawing. Show in the drawing

Fig. 1 shows a circuit according to a first embodiment of he inventive evaluation method for capacitive sensors,

Fig. 2 shows a circuit according to a second embodiment of the evaluation method according to the invention for capacitive sensors,

Fig. 3 is a diagram of another embodiment of the evaluation method according to the invention for capacitive sensors and

Fig. 4 shows the effect of leakage currents on the measurement signal and the resulting shorter time evaluation window of the sample and hold circuit.

Fig. 1 shows a circuit according to a first embodiment of the inventive evaluation method for capacitive sensors. An input signal U _{0 is} given to the circuit, which is formed here in the form of a square wave voltage. The circuit consists of an integrator 1 , a differentiator 2 and a subtractor 3 . The integrator 1 consists of a reference capacitor 4 , which has a capacitance C ₁ , a resistor 5 with a resistance value R ₁ and an operational amplifier 6 . The differentiator 2 consists of the measuring capacitor 7 , which has a capacitance C ₂ , a resistor 8 with a resistance value R ₂ and a further operational amplifier 9 .

Advantageously, the reference capacitor 4 and the measuring capacitor 7 are connected to one another, so that interference from the outside on the capacitive sensor has only a minor effect on the measurement. Since the non-in inverting inputs of operational amplifiers 6 and 9 are both grounded, we know their inverting inputs as "virtual ground". As a result, both the connection point between the reference capacitor 4 and the resistor 5 and the connection point between the measuring capacitor 7 and the resistor 8 have zero potential, and therefore no leakage currents occur against ground.

The rectangular input signal U ₀ is converted by the integration into the intermediate signal U ₁ , which has the form of a triangular voltage. This triangular voltage is then converted by the differential into the measurement signal U ₂ , which is again rectangular. The measurement signal U ₂ and the input signal U ₀ are given to the subtractor 3 and you get at the output of the subtractor 3, the voltage _{surge Δ} U, which also has the shape of a square wave voltage.

Fig. 2 shows a circuit according to a second embodiment of the inventive evaluation method for capacitive sensors. Here, too, the circuit consists of an integrator 1 , which in turn is composed of a reference capacitor 4 , a resistor 5 and an operational amplifier 6 . Likewise, the capacitance of the reference capacitor 4 is marked with C ₁ and the resistance value of the resistor 5 with R ₁ . According to Fig. 1, the circuit also includes a differentiator 2 with a measuring capacitor 7, a resistor 8 and an operational amplifier 9. Here, too, the capacitance of the measuring capacitor 7 is identified by C ₂ and the resistance value of the resistor 8 by R ₂ .

In contrast to the circuit shown in FIG. 1, the differentiator 2 is followed by a control element 10 , which makes the difference between the input signal U ₀ and the measurement signal U ₂ zero by charging current correction. The charging current correction can be emphasized not only as a controlled variable but also as an output signal.

Fig. 3 is a diagram showing a further embodiment of the evaluation method according to the invention for capacitive sensors. Here too, the evaluation process again consists of the integration of the input signal U ₀ in an integrator 1 and the subsequent differentiation of the intermediate signal U ₁ in a differentiator 2 . The reference capacitor 4 is again part of the integrator 1 and the measuring capacitor 7 is again part of the differentiator 2 .

The output of the integrator 1 is connected to a comparison unit 11 , which consists of a level detector 12 and a comparator 13 . The output of the compa rator 13 is connected to the input of a square wave generator 14 so that when the hysteresis threshold is reached, the square wave generator output signal is inverted. This measure determines the start and end of a pulse of the input signal U ₀ by reaching a certain voltage level of the intermediate signal U ₁ . The circuit therefore does not require a separate clock generator. Because the charging and discharging phase of the capacitors is determined by reaching a certain voltage level of the intermediate signal U ₁ , operational amplifiers used remain in their working range and thus do not wait for an external switchover, which would result in a loss of time. A capacitive sensor according to the evaluation method according to the invention thus has a faster response time.

The differentiator 2 is again followed by a subtractor 3 , which is followed by an amplitude evaluation unit 15 in this embodiment. The amplitude evaluation unit 15 advantageously consists of a sample and hold circuit with an integrati on capacitor. Preferably, the evaluation window of the sample and hold switching device is connected via a time delay unit 16 to the output of the comparator 13 , so that a synchronous detection takes place.

Preferably, as shown in FIG. 3, a linearizer 17 , which consists of a four-pole resistance network, is used for the characteristic curve correction. One pole is connected to the operating voltage and another to ground. In order to ensure low power consumption of the circuit, a passive resistance network without an operational amplifier is preferably used.

The linearizer 17 is followed by an impedance converter 18 , which is used for decoupling the linearizer 17 and the square wave generator 14 .

In Fig. 3 it is also shown in broken lines that the measurement signal U ₂ as the output signal of the differentiator 2 can also be brought out directly, that is to say without a subtractor 3 as in FIG. 1 or a control element 10 as in FIG. 2, as an output signal.

Since, as already described above, the “virtual ground” of the inverting inputs of the operational amplifiers 6 and 9 does not produce any leakage currents, there is also no beveling of the signal swing _Δ U to be evaluated. If such a beveling were to occur, it would have to be compensated for by a sample time arranged symmetrically to the zero crossing of the intermediate signal U ₁ . Since the sample and hold access must wait for the transient response of the operational amplifier after the charge current has been reversed, it must be switched off prematurely after the zero crossing of the intermediate signal U ₁ , in order not to distort the symmetry, although the intermediate signal U _{1 is} still far in the evaluable range lies.

The relationship described above is shown in FIG. 4. The signal deviation _Δ U which is obtained at the output of subtractor 3 is shown again for because event that leakage to ground occur (reference numeral 19), and once for the case that these leakage currents, as in the inventive evaluation method, verhin changed are (Reference number 20 ). The fact that in the evaluation method according to the invention for capacitive sensors, leakage currents which lead to the beveling of the voltage surge _Δ U, are avoided, the sample and hold circuit of the evaluation unit 15 can be integrated over a substantially larger evaluation window. In FIG. 4, the evaluation window of the sample and hold circuit according to the invention the OF INVENTION evaluation with S is _new and the evaluation window of the sample and hold circuit of a conventional evaluation technique with in S _old. There is a considerable gain in dynamics for a capacitive sensor according to the evaluation method according to the invention.

Claims (11)

1. Evaluation method for capacitive sensors, in particular for pressure sensors, using a reference capacitor, a measuring capacitor with a measuring capacitance which can be influenced by a physical measured variable and a periodic, essentially symmetrical input signal U ₀ , characterized in that by means of the reference capacitor or the Measuring capacitor by integrating the input signal U _0, an intermediate signal U ₁ and by means of the measuring capacitor or the reference capacitor by differentiating the intermediate signal U _1, the measuring signal U _{2 is} generated. 2. Evaluation method for capacitive sensors according to claim 1, characterized in that the input signal U ₀ in the form of a square wave voltage is supplied to the reference capacitor or the measuring capacitor with high impedance. 3. Evaluation method for capacitive sensors according to claim 1 or 2, characterized in that the reference capacitor is used to integrate the input signal U ₀ and the measuring capacitor is used to differentiate the intermediate signal U ₁ . 4. Evaluation method for capacitive sensors according to one of claims 1 to 3, because characterized in that the reference capacitor and measuring capacitor together are connected. 5. Evaluation method for capacitive sensors according to one of claims 1 to 4, characterized in that the beginning and end of a pulse of the input signal U _{0 are} determined by reaching a certain voltage level of the intermediate signal U ₁ . 6. Evaluation method for capacitive sensors one of claims 1 to 5, characterized in that the input signal U ₀ and the measurement signal U ₂ are compared in a subtra here and thus the voltage swing _Δ U is determined. 7. Evaluation method for capacitive sensors according to claim 6, characterized in that the input signal U ₀ and the measurement signal U ₂ are given to the subtractor ( 3 ) during the positive and the negative half of the period and then to determine the voltage _{swing Δ} U Partial result _Δ U⁻ during the negative half of the period is subtracted from partial result _Δ U⁺ during the positive half of the period. 8. evaluation method for capacitive sensors according to claim 6 or 7, characterized ge indicates that the subtractor has an amplitude evaluation unit consisting of a sample and hold circuit with an integration capacitor. 9. Evaluation method for capacitive sensors according to one of claims 1 to 5, characterized in that the measurement signal U _{2 is followed by} a control element ( 10 ) which can make the difference between the input signal U ₀ and the measurement signal U ₂ zero by charging current correction . 10. Evaluation method for capacitive sensors according to claim 9, characterized records that the charge current correction as a controlled variable additionally as an output signal is highlighted. 11. Evaluation method for capacitive sensors according to one of claims 1 to 10, characterized in that there is a linearizer for the correction of the characteristic curve from a four-pole resistor network, preferably a passive resistor stand network, is used.