DE10158836A1 - Method for sensor system calibration in which sensor system can be operated in normal measurement mode or calibration mode, when its sensitivity and resolution are much higher than in normal operating mode - Google Patents

Abstract

Method for calibrating a sensor system that comprises a sensor (10) and a signal processing circuit (12-38). The sensor system can be operated in normal or calibration mode. In calibration mode, measurement resolution and sensitivity are much higher than in normal operating mode. The invention also relates to a corresponding calibration arrangement.

Description

The invention relates to a method for calibration a sensor system according to the preamble of claim 1 and a device for the calibration of a sensor system the preamble of claim 12.

As is known, sensor systems have to be calibrated, to get the most accurate measurement results possible. On Sensor system can be, for example, an electronic measuring system be both sensors and the required electronic circuits for evaluation or preprocessing of the measurement signals generated by the sensors. On Such a sensor system thus not only includes the arrangement or wiring sensors, but also the associated one Measurement signal processing electronics (short Signal processing circuit) and in particular the corresponding algorithms for measurement signal processing.

Problematic when calibrating sensor systems can be the provision of sensor inputs that occur under real measurement conditions. The following is intended this is explained using sensor systems as an example, which are used as non-contact current measurement systems. Basically, however, the aforementioned problem exists with a variety of sensor systems for various physical sensor inputs.

Non-contact current measurement systems include current sensors, with which a current flows through the magnetic field it generates can be measured. The so-called Hall probes, which are from the prior art are known. Since such Hall probes usually have one have some offset in their output signals, it is required to correct this offset, preferably by a calibration of the Hall sensors. To eliminate the Offsets can be, for example, that known from US 4,037,150 Spinning Current principle can be applied.

Hall sensors and probes are used, among other things, for the Measurement of very high currents in the range of kA used. Such sensor systems are also called high-current sensors designated. A high-current sensor can be used, for example, with a Measuring current of approx. -1.5 kA a voltage of typically 0.5 volts, at 0 A of about 2.5 volts and at +1.5 kA of about 4.5 volts deliver.

A typical sensor module for high-current measurement comprises at least one Hall sensor with a signal processing circuit, in particular an amplifier circuit. Hall sensor and amplifier circuit are preferably integrated on one chip. The chip is mounted in the vicinity of the electrical line, which carries the current to be measured, by means of a fastening component. In order to get the most accurate measurements possible, the exact positioning of the chip is important. In the case of a conductor with a cross section of, for example, 10 mm ² , the chip with the Hall sensor can be attached at a distance of approximately 4 mm to the axis of the conductor. This typically creates a magnetic field of approximately 75 mT at the location of the sensor of the chip with an electrical current through the electrical line of 1.5 kA or 50 μT / A.

Smallest position tolerances of the chip and the Hall sensor however, lead to significant changes in the magnetic field, that indirectly to the normal distance from the axis of the conductor decreases. As a result of the chip assembly process however, the position of the Hall sensor within the Housing can only be set to an accuracy of approx. 0.1 mm. This gives inherently an inaccuracy of about 0.1 / 4, d. H. 2.5%. To compensate for this inaccuracy, the Hall Sensor after its installation in the housing or in the module regarding its absolute sensitivity can be calibrated. Just With high current sensors, however, this is due to the high measuring currents economically hardly possible. This is the case all that a calibration reference value of about 1 kA with sufficient accuracy and time Stability must be impressed in the conductor to be measured.

In principle, such problems occur with everyone Sensor system based on that in reality Sensor input sizes works that only under large technical effort over one for a calibration sufficiently long period of time with sufficient accuracy can be impressed. However, as explained above, this is often not economically viable or sometimes technically also not possible at all.

The object of the present invention is therefore a Method and device for calibrating a Propose sensor systems in which with a Reference metric that is much less than one too is a sufficiently precise measurement value Calibration of the sensor system can be carried out. A high-current sensor system with a Reference current of only about 10 A absolutely accurate to about 1% can be calibrated.

This task is accomplished through a calibration procedure a sensor system with the features of claim 1 and by a corresponding device with the features according to Claim 12 solved. Preferred configurations result from the dependent claims.

An essential idea of the invention is that a sensor system has a normal and a Calibration mode of operation included. The calibration mode is now characterized in that the sensitivity and / or measurement resolution of the sensor system compared to the Normal operating mode is or are significantly increased. Thereby it is for example in the case of a high current sensor possible that in calibration mode with a very much lower reference current than in normal operating mode can be worked. The sensor system can thus be calibrated more economically.

The invention is of course not based on High current sensor systems are limited, but can be used with anyone Sensor system can be used advantageously, in which it it is difficult to find one that corresponds to an operating parameter Reference measurand for calibration with sufficient Marking accuracy and temporal stability. Examples of sensor systems in which the invention is advantageous can be used are high pressure and Acceleration measurement systems. To perform the calibration for the To make normal operating mode reproducible, the Increase in sensitivity and / or measurement resolution in the Calibration operating mode at least as accurate and reproducible be like the accuracy of the calibrated sensor system is sought. Typically in Calibration operating mode the sensitivity and / or resolution of the sensor system by at least two orders of magnitude the normal operating mode increased.

The increase in sensitivity and / or measurement resolution in Calibration operating mode can, for example, by a Reduction of the measuring bandwidth compared to the measuring bandwidth can be achieved in normal operating mode.

Alternatively or additionally, you could get one Increasing the measurement resolution and / or sensitivity too due to increased power consumption in the Calibration operating mode compared to the power consumption in Imagine normal operating mode by the sensor system at higher (calibration) operating voltages and / or higher Current consumption is operated.

In a low-power application, it is recommended that the duty Cycle (= ratio of active time to the sum of active Time and sleeping time) of the signal processing circuit increase.

If the temperature response of the sensor system is sufficient is known exactly, it can also be used in calibration mode operate at a temperature at which the effective sensor Input noise is minimal.

The calibration can be done such that during the Calibration operating mode especially after an increase in Sensor sensitivity a zero point adjustment of the minimum one sensor and then at least one Sensor input variable applied to the at least one sensor becomes; this is at least one sensor input variable small compared to the sensor input variable (s) in the Normal operating mode, after calibration is complete about the full deflection of the sensor system output signal or of the sensor system output signals leads. Through the increased sensitivity leads or lead the Sensor input variable (s) but during calibration to a full deflection of the sensor system output signal or the sensor system output signals or at least one large signal swing at the sensor output.

The sensor input variable (s), which is used as a calibration reference is or are used, is or are well defined, because either in the data sheet of the sensor system or the at least one sensor is specified, or the using at least one sensor during calibration Data transfer will be communicated.

The sensor system is preferably calibrated in the Calibration mode automatically by itself Calibration logic.

A calibration record can also be made during calibration be generated that at least one output of the Sensor system is output. Using this protocol, you can for example, the calibration process is evaluated become.

The calibration procedure is preferred in one Embodiment on at least one sensor input variable of controlled at least one sensor. Here, the Calibration by a handshake procedure between the am Output of the sensor system output calibration report and of the at least one sensor input variable.

The invention further relates to a device for Calibration of a sensor system that has at least one sensor and a signal processing circuit for processing at least one signal of the at least one sensor and a normal operating mode for taking measurements via which has at least one sensor. The sensor system is can be brought into a calibration operating mode for calibration, in which is set such that sensitivity and / or Measurement resolution of the sensor system compared to the Normal operating mode is or are significantly increased.

The is preferably in the calibration operating mode Measuring bandwidth compared to the measuring bandwidth in Normal operating mode reduced.

Alternatively or in addition, Calibration mode of operation compared to the power consumption Power consumption in normal operating mode can be increased by the sensor system with an operating voltage and / or Operating current is operated, which or greater than in Normal operating mode is or are.

With a low-power application of the sensor system should the duty cycle of the signal processing circuit must be increased.

The sensor system is preferably in the Calibration operating mode for operation at one temperature trained in which the effective sensor input noise is minimal. This enables particularly precise measurements be achieved.

After all, the sensor system is special preferred embodiment such that during a calibration of the calibration mode at least one sensor and then at least one a sensor input variable to the at least one sensor is created that is small compared to the or Sensor input variable (s) in normal operating mode is or are after the calibration has been completed, approximately to the full scale the sensor output signal or the sensor output signals leads or lead.

The sensor system can be designed such that the Sensor input variable (s) during calibration by a Data transfer to the at least one sensor is transmitted or will.

Furthermore, the sensor system can be designed such that it is in calibration mode via a Calibration logic automatically calibrated itself.

In a further preferred embodiment, this is Sensor system designed such that during the Calibration a calibration record is generated that is on at least one output of the sensor system is output.

The sensor system can also be designed such that the calibration process over at least one Sensor input variable of the at least one sensor controlled becomes.

The sensor system is preferably designed such that that calibration through a handshake process between at the at least one output of the sensor system output calibration report and the at least one Sensor input variable is carried out.

The at least one sensor can preferably be one integrated pressure sensor especially lower Sensitivity (e.g. a so-called High pressure sensor with an FS of z. B. 200 bar), thus at small, harmless pressures of, for example, about 1 bar can be calibrated.

The at least one sensor can also preferably be one integrated acceleration sensor especially lower Sensitivity, which is therefore small, accurate reproducible acceleration values can be calibrated can.

Finally, the at least one sensor can also be a preferably integrated magnetic field sensor in particular low sensitivity, which is therefore low-performance magnetic fields can be calibrated.

In a particularly preferred embodiment, the preferably integrated magnetic field sensor in one module be installed, which also has a conductor and Fastening elements for fastening the module includes. This creates a non-contact high current sensor. Due to the special calibration mode, this can High current sensor with small reference currents - as in easily made available to a production line can - be calibrated.

The at least one sensor can be preferred integrated magnetic field sensor at least one Hall probe, in particular a spinning current Hall probe or 90 ° - switched Hall probe.

In addition, such a chopped Hall probe in an analog front end, d. H. an analog one Signal processing electronics to be integrated in the by chopped offset error compensation the offsets of the at least one Hall probe and / or at least one Amplifier (up to a demodulator, for example) a feedback circuit in the Signal processing circuit with high loop gain be largely suppressed, so amplifiers with moderate control limits can be used.

Furthermore, the special calibration operating mode can a defined calibration protocol and an intelligent one Calibration logic expanded to a self-calibrating sensor become. The target values of the calibration process can be done using Data exchange, for example between an ASIC with the Signal processing circuit and a calibration device be kept flexible within wide limits. Alternatively, you can they are fixed in the data sheet, so that no Data exchange is necessary, and thus the calibration process can run easier and faster.

In particular, a calibration protocol in which ( 1 ) the at least one sensor indicates the status of its calibration state by means of its output signal is recommended (in that the adjustment can be followed at an output of the sensor system and the output signal assumes a clear voltage value when terminated) and ( 2 ) for example the at least one sensor can be informed via at least one sensor input variable that a further phase of the calibration process is now being started or ended (for example by applying or switching off a magnetic field triggering a switching threshold in the case of a contactless current field sensor system). I.e. In the calibration protocol, a handshake procedure is used between the signals sensor input variable and sensor output variable.

The invention will now be described with reference to figures the drawing shown in more detail. Show it:

Fig. 1 shows a first embodiment of an ASIC of the sensor system according to the invention for measuring a linear magnetic field by means of Hall probes,

Fig. 2 shows the current and voltage curves of selected signals of the sensor system at the expiration of a calibration procedure, and

Fig. 3 shows a second embodiment of an ASIC of the sensor system according to the invention for measuring a linear magnetic field by means of Hall probes.

Fig. 1 shows the block diagram of the signal processing part or a signal processing circuit of a sensor system for measuring a linear magnetic field using Hall probes as sensors, which is designed as an ASIC (Application Specific Integrated Circuit). The linear magnetic field of a current to be measured is measured by at least one Hall probe 10 . In practice, two Hall probes usually implement a differential field measurement. The Hall probes are then operated in the so-called spinning current mode (or in the 90 ° switched mode if you only switch back and forth between two directions; indicated by the arrow in block 10 ): number four (not shown) connections of two Hall probes in the Clockwise with 1, 2, 3, 4, the Hall probe is then supplied with current at contacts 1 , 3 in a clock phase 1 and the sum of Hall probe offset and Hall voltage is tapped at contacts 2 , 4 and applied to the inputs of a preamplifier 14 , In the subsequent clock phase 2 , the Hall probe is supplied with current at contacts 2 , 4 and the difference between the Hall probe offset and Hall voltage is tapped at contacts 1 , 3 .

The signals of the Hall probe 10 are amplified by the preamplifier 14 in a normal operating mode by approximately a factor of 42. In contrast, in a calibration operating mode, the gain of the preamplifier 14 is increased by a defined factor of approximately 150. In practice, this is done by switching an additional calibration amplifier 16 with a defined gain of approximately 150 into the signal path by means of a first switch S1. The gain factor of approximately 150 is approximately equal to the ratio of half the full scale range (0.5.300A) to the reference current during a calibration process ( 10 A).

The output signal of the preamplifier 14 is fed to a feedback loop or circuit in which an offset feedback circuit 18 generates two error signals from the output signal by periodically reversing the polarity and integrating it. These error signals are in turn fed into the preamplifier 14 by subtracting from the signal of the Hall probe 10 by means of a subtractor 12 and thus lead to a compensation of the probe offset and at the same time also a compensation of the offset of the entire chain including the preamplifier 14 and the calibration amplifier 16 .

This compensation of the two offsets of the Hall probe 10 and the chain mentioned above should be carried out, since otherwise the output of the preamplifier 14 would be limited: if z. B. the preamplifier 14 has a small offset of approximately 1 mV, this would be amplified with an amplification of 42,150 = 6300 to approximately 6.3 V; in reality, the output voltage is of course on an operating voltage of z. B. 3 V limited, so that the preamplifier 14 would be overdriven in this case.

Furthermore, the output signal of the preamplifier 14 is fed to a demodulator 20 for demodulating the signal corresponding to the measured magnetic field and then low-pass filtered by a first or a second low-pass filter 22 or 24 . Both low-pass filters 22 and 24 can alternatively be switched into the signal path by means of a second switch S2. The first low-pass filter 22 has a cut-off frequency of fg _norm , the second low-pass filter has a cut-off frequency of fg _cal . The following applies: fg _standard >> fg _cal .

After the low-pass filtering, a so-called zero field voltage, which is generated by an adjustable DC voltage source 28 , is added to the output signal of one of the low-pass filters 22 or 24 by means of an adder 26 . The signal thus generated is then amplified by an output amplifier 30 and made available at an output pin 36 in a low-resistance manner.

The signal of the output amplifier 30 is also fed to the non-inverting input of a comparator 34 , at the inverting input of which the calibration reference voltage of an adjustable calibration voltage source 32 is present. The output signal of the comparator 34 is fed to a digital adjustment controller 38 , which generates signals for setting the switches S1 and S2 and the amplification of the preamplifier 14 (GDAC) and the voltage of the adjustable DC voltage source 28 (ODAC).

Fig. 2 shows the current and voltage curves of selected signals of the sensor system at the end of a calibration procedure: a voltage VDD (upper diagram) initiates the calibration mode (voltage level VDDnormal and VDDcal) at a time t1 and causes the permanent programming of a OTPROMs (One Time Programmable Read Only memory) at a time t10 (voltage level VDDprog). The signals Vout (voltage, middle diagram) and Ical (current, lower diagram) implement a handshake process in which the current Ical responds to the voltage Vout (at times t3, t4) and vice versa (at times t5, t6). The voltage level Vout1 is the result of a zero point adjustment, Vout2 that of a reference current adjustment and Vout3 results from a zero field voltage adjustment.

In calibration mode, the ASIC should be adjusted to approx. 1% with a reference current of only approx. 10 A. The reference current is the current to be measured in the calibration mode. This reference current corresponds to a magnetic induction of approximately 500 µT, which can be resolved with an accuracy of approximately 0.5%. This means an equivalent magnetic input noise of about 2.5 µT _RMS . A noise voltage density of approximately 224 nT _RMS / sqrt (Hz) is state of the art (this is achieved, for example, in the Linear Hall Sensor ASIC TLE4990). It follows that the bandwidth of the high-current sensor ASIC must be limited to approximately 125 Hz during calibration. The second low-pass filter 24 shown in the block diagram in FIG. 1 consequently has a cut-off frequency by means of which the cut-off frequency in the signal path can be reduced to approximately 125 Hz in the calibration operating mode, while in the normal operating mode the first low-pass filter 22 with a cut-off frequency between 30 kHz and 100 kHz is used ,

The following defined measurement sequence is carried out in the calibration process (see FIG. 2): The ASIC is informed by means of a pulse sequence of the voltage VDD on a VDD line that a calibration process is started. In the present case, the voltage is increased from the normal operating voltage VDD = 5 V for a period of approximately 10 μs to approximately 1 ms to approximately 8 V (voltage level VDD normal) and then reduced again to approximately 5 V (voltage level VDDcal).

As soon as VDD = 5 V, a zero point adjustment begins, in which the calibration amplifier 16 is switched on by switching switch S1 accordingly in the signal path, by switching to the second low-pass filter 24 by means of the switch S2, the cut-off frequency of the low-pass filtering is throttled to 125 Hz and that Inputs of the preamplifier 14 are short-circuited. The ASIC now executes a zero-point adjustment by setting the adjustable DC voltage source 28 such that the voltage at the output pin 36 is approximately 50% of the operating voltage. For this purpose, he compares the voltage at the output pin 36 with a value of approximately 0.5.VDD by means of the comparator 34 and transfers the result in binary form (0 = smaller, 1 = larger) to the digital adjustment controller 38 . This increments or decrements the adjustable DC voltage source 28 at a speed which is adapted to the 125 Hz band limitation, successive increments / decrements being binary-weighted in order to accelerate the zero point adjustment.

In the meantime, a user of the sensor system can observe the adjustment based on the output voltage at the output pin 36 . The algorithm of the digital balancing controller 38 terminates when the adjustable DC voltage source 28 goes up and down 1 LSB several times. The ASIC stores the setting or ODAC value of the adjustable DC voltage source 28 in a register and signals the end of the zero point adjustment to the user by pulling the output pin 36 to ground. In preparation for the subsequent reference current adjustment, the amplification of the preamplifier 14 is set to a minimum (the preamplifier 14 is designed as a programmable gain amplifier PGA) and the preamplifier inputs are no longer short-circuited.

This is the sign for the user to impress the reference current Ical of about 10 A in the conductor. The magnetic field increases the voltage at output pin 36 to over 50% of VDD. At approx. 70% VDD, the ASIC recognizes that the user has reacted and that a reference current is now being impressed on the conductor. The ASIC then automatically tries to generate a voltage of approximately 90% VDD at the output pin 36 by tuning the preamplifier 14 . The comparator is used again, but its calibration reference voltage is now around 90% of VDD. This adjustment also terminates similarly to the zero point adjustment and leads to the result that the sensitivity of the ASIC in calibration mode is set to S _cal = 0.4.VDD / Ical. In normal operating mode, when the calibration amplifier 16 is removed from the signal path, the sensitivity is consequently S _cal = 0.4.VDD / (150.Ical). The reference current can be a fixed value, which is defined in the data sheet of the ASIC. The result of the reference current adjustment is also stored in a register. Again, the ASIC signals the end of the reference current adjustment to the user by pulling the output pin 36 to ground.

This symbol signals the user to switch off the reference current through the conductor. Since this largely eliminates the magnetic field (apart from background fields and possibly undesirable remanent phenomena), the signal falls below a critical value, which means that the ASIC recognizes that the user has reacted. He therefore begins the zero field voltage adjustment: for this purpose the calibration amplifier 16 is removed from the signal path and the inputs of the preamplifier 14 are short-circuited again. Furthermore, to accelerate the adjustment, the cut-off frequency of the low-pass filtering is reduced from approximately 150 Hz to approximately 30 kHz. .100 kHz increased by switching to the first low-pass filter 22 by means of the first switch S1, because the extreme band limitation is only required by the ASIC with maximum amplification, that is to say when the calibration amplifier 16 is inserted into the signal path.

The same adjustment routine is carried out as for the zero adjustment, ie the current ODAC value is incremented or decremented until the output voltage at the output pin 36 is automatically trimmed to approximately 50% VDD. This current ODAC value overwrites the ODAC value previously determined in the zero point adjustment. In practice, the two values mostly differ, since the offset is not completely eliminated by the spinning current hall technique and has therefore been multiplied by different gains. For normal operation, however, the ODAC value that results without inserting the calibration amplifier 16 is relevant. Therefore, this value is determined last and overwrites the first value. This order can of course also be changed if additional registers are used which buffer the calibration data.

The activities of a user mentioned above can can of course be carried out automatically. The circuitry measures required for this are familiar to a specialist in the field of sensor systems. On at this point it should only be noted that for example a appropriately programmed microprocessor the activities of the user can take over. The microprocessor controls then automatically switching on and off as well as setting the Reference current.

Due to the high sensitivity of the sensor system during the calibration mode of operation, if the system is configured incorrectly, interference (EMC) may be interpreted by the sensor as a signal "start reference current measurement" or "end reference current measurement". However, since the system is intended to be highly interference-free in normal operating mode, it is also possible with some caution not to allow the sensor to have any unacceptably large interferences during the calibration operating mode, especially since the sensor is already calibrated in the complete module (with EMC capacities and shield housing) can be. Additional interference immunity is achieved if the signals "start reference current measurement" or "end reference current measurement" must be present for a minimum period of time before they are interpreted by the ASIC. Since these signals are obtained by further processing the output voltage at the output pin 36 , they are already largely eliminated from short-term interference by the second low-pass filter 24 . In addition, any spikes on the output pin 36 can be detected, for example, by a digital storage oscilloscope connected to it, or also automatically by means of an appropriate device, and the calibration process can be started again.

The end of the zero field voltage adjustment is again indicated to the user by the ASIC pulling the output pin 36 to ground. Then the user can set the operating voltage to e.g. B. Increase 17 V. This causes the ASIC to write its current bit combinations for the values GDAC and ODAC into its OTPROM and then to prevent further, unwanted changes to the OTPROM by setting a memlock bit. The ASIC is thus calibrated. If the user does not increase the operating voltage, the ASIC is calibrated, but its calibration constants will be lost during the next power down.

The above-described adjustment process by means of comparator 34 and digital adjustment control 38 can of course be significantly improved with the aid of an ADC (analog-digital converter) instead of comparator 34 . The ADC then tells the digital adjustment controller 38 how far the current measured value at the output pin 36 is from the target value, so that the number of iterations can be greatly reduced, which speeds up the calibration process.

In an improved system, after the Reference current and before programming the OTPROM Data transfer take place in which the user uses the ASIC reports how large the calibration current was. Thereby simplify the requirements for the Calibration current source, since it then only has to be stable, but not absolutely exact, because the absolute accuracy will determined by back-measuring the calibration current and the ASIC communicated after the end of the reference current adjustment phase. The ASIC can use this to determine the internal calibration logic Calculate the real achieved sensitivity and if necessary by correcting its calibration bit pattern small Compensate for reference current errors.

Furthermore, before the start of the reference current measurement Data transfer take place that the ASIC the desired Communicates target sensitivity. This allows the user to Choice of the calibration current within certain limits the final resolution of the system.

Fig. 3 shows a second embodiment of the signal processing analog part shows an integrated magnetic field sensor with a spinning current Hall probe 50, which provides two measurement signals, and a feedback loop which extracts a signal proportional to the offset of the Hall probe 50 and a Vorverstärkerkette error signal and a compensation in pre-amplifier 52 and 54 feeds.

The two measurement signals of Hall probe 50 are fed to preamplifiers 52 and 54 , respectively. The output signals of the preamplifiers 52 and 54 are each fed back via an adjustable voltage divider 56 to the inverting inputs of the preamplifiers 52 and 54 , as a result of which the amplification can be set. The two output signals of the preamplifiers 52 and 54, which are proportional to the magnetic field, are demodulated by signal demodulators 58 and each filtered by a low-pass filter 60 or 62 ; the low-pass filtered signals are then fed to the non-inverting or inverting input of a differential amplifier 64 . A zero field voltage of an adjustable DC voltage source 72 is added to its single output signal by an adder 66 . Finally, the signal generated in this way is made available at an output pin 70 by means of a power amplifier 68 .

Not shown is the digital balancing circuit, which measures the output voltage and compares it with a reference voltage, and if necessary the amplification of the preamplifiers 52 and 54 via the signal GDAC (for calibration current adjustment) or the voltage of the adjustable DC voltage source 72 via the signal ODAC (for the zero point and during zero field voltage adjustment) in such a way that the output voltage at output pin 70 is brought into agreement with the reference voltage. In certain phases of the calibration process, an additional amplifier (not shown) can be inserted into the preamplifiers 52 and 54 , which increases the gain. In principle, this does not differ in operation from preamplifiers 52 and 54 with adjustable amplification. The short-circuit switches at the inputs of the preamplifiers 52 and 54 are also not shown. The cut-off frequency of the low-pass filters 60 and 62 after the two demodulators 58 are variable and can be reduced to a sufficiently great extent during the calibration process.

The feedback path is formed by a series circuit comprising offset demodulators 74 , two offset low-pass filters 76 and 78 , an offset integrator 80 with differential output, two capacitors 82 and 84 and a current amplifier 86 . The offset integrator 80 generates a differential error signal, which is converted into a current by means of the current amplifier 86 . In principle, this current represents the error or offset in the signals of the Hall probe 50 and is therefore fed to the inverting inputs of the preamplifiers 52 and 54 for compensation. Legend: 10 Hall probe
12 subtractors
14 preamplifiers
16 calibration amplifiers
18 offset feedback circuit
20 demodulator
22 first low pass filter
24 second low pass filter
26 adders
28 adjustable DC voltage source
30 output amplifiers
32 adjustable calibration voltage source
34 comparator
36 output pin
38 digital adjustment control
50 Spinning Current Hall probe
52 preamplifiers
54 preamplifiers
56 adjustable voltage divider
58 (signal) demodulators
60 low pass filters
62 low pass filter
64 differential amplifiers
66 adders
68 power amplifiers
70 output pin
72 adjustable DC voltage source
74 offset demodulators
76 Offset low pass filter
78 offset low-pass filter
80 offset integrator
82 capacitor
84 capacitor
86 current amplifiers

Claims (28)

1. A method for calibrating a sensor system which has at least one sensor ( 10 ; 50 ) and a signal processing circuit ( 12-38 ; 52-86 ) for processing at least one signal of the at least one sensor, and measurements in a normal operating mode via the at least one sensor ( 10 ; 50 ), characterized in that the sensor system for calibration is brought into a calibration operating mode in which the sensitivity and / or measurement resolution of the sensor system is or are significantly increased compared to the normal operating mode. 2. The method according to claim 1, characterized in that in calibration mode, the measurement bandwidth compared to Measurement bandwidth is reduced in normal operating mode. 3. The method according to claim 1 or 2, characterized in that compared to power consumption in calibration mode the power consumption is increased in normal operating mode, by the sensor system with an operating voltage and / or an operating current is operated, the or the larger than is in normal operating mode. 4. The method according to any one of claims 1 to 3, characterized in that in a low-power application of the sensor system, the duty cycle of the signal processing circuit ( 12-38 ; 52-86 ) is increased. 5. The method according to any one of the preceding claims, characterized in that the sensor system in calibration mode at a Temperature is operated at which the effective sensor Input noise is minimal. 6. The method according to any one of the preceding claims, characterized in that a zero point adjustment of the at least one sensor ( 10 ; 50 ) takes place during the calibration operating mode and then at least one sensor input variable is applied to the at least one sensor, which is small compared to the sensor input variable or variables (n) is in the normal operating mode, which after the calibration has been completed leads to the full deflection of the sensor system output signal or the sensor system output signals. 7. The method according to claim 6, characterized in that the sensor input variable (s) during calibration a data transfer to the at least one sensor is or will be transmitted. 8. The method according to any one of the preceding claims, characterized in that the sensor system automatically calibrates itself in the calibration operating mode via a calibration logic ( 38 ). 9. The method according to any one of the preceding claims, characterized in that a calibration protocol is generated during the calibration, which is output at at least one output ( 36 ; 70 ) of the sensor system. 10. The method according to claim 9, characterized in that the calibration process is controlled via at least one sensor input variable of the at least one sensor ( 10 ; 50 ). 11. The method according to claim 10, characterized in that the calibration is carried out by a handshake method between the calibration protocol output at the at least one output of the sensor system ( 36 ; 70 ) and the at least one sensor input variable. 12. Device for calibrating a sensor system, the at least one sensor ( 10 ; 50 ) and a signal processing circuit ( 12-38 ; 52-86 ) for processing at least one signal of the at least one sensor and a normal operating mode for carrying out measurements on the at least one Sensor ( 10 ; 50 ), characterized in that the sensor system for calibration can be brought into a calibration operating mode in which it is set such that the sensitivity and / or measurement resolution of the sensor system is or are significantly increased compared to the normal operating mode. 13. The apparatus according to claim 12, characterized in that in calibration mode, the measuring bandwidth compared to the Measurement bandwidth is reduced in normal operating mode. 14. The apparatus of claim 12 or 13, characterized in that compared to power consumption in calibration mode the power consumption is increased in normal operating mode, by the sensor system with an operating voltage and / or an operating current is operated, the or the larger than is in normal operating mode. 15. Device according to one of claims 12 to 14, characterized in that in a low-power application of the sensor system, the duty cycle of the signal processing circuit ( 12-38 ; 52-86 ) is increased. 16. The device according to one of claims 12 to 15, characterized in that the sensor system is operating in calibration mode is formed at a temperature at which the effective Sensor input noise is minimal. 17. The device according to one of claims 12 to 16, characterized in that the sensor system is designed such that a zero point adjustment of the at least one sensor ( 10 ; 50 ) takes place during the calibration operating mode and then at least one sensor input variable is applied to the at least one sensor, which is or are small in comparison to the sensor input variable (s) in the normal operating mode, which, after the calibration has been completed, leads to the full deflection of the sensor output signal or the sensor output signals. 18. The apparatus according to claim 17, characterized in that the sensor system is designed such that the Sensor input variable (s) during calibration a data transfer to the at least one sensor is or will be transmitted. 19. Device according to one of claims 12 to 18, characterized in that the sensor system is designed such that it automatically calibrates itself in the calibration operating mode via a calibration logic ( 38 ). 20. Device according to one of claims 12 to 19, characterized in that the sensor system is designed such that a calibration protocol is generated during calibration, which is output at at least one output ( 36 ; 70 ) of the sensor system. 21. The apparatus according to claim 20, characterized in that the sensor system is designed such that the calibration process is controlled via at least one sensor input variable of the at least one sensor ( 10 ; 50 ). 22. The apparatus according to claim 21, characterized in that the sensor system is designed such that the calibration is carried out by a handshake method between the calibration protocol output at the at least one output of the sensor system ( 36 ; 70 ) and the at least one sensor input variable. 23. Device according to one of claims 12 to 22, characterized in that the at least one sensor ( 10 ; 50 ) is a pressure sensor. 24. Device according to one of claims 12 to 22, characterized in that the at least one sensor ( 10 ; 50 ) is an acceleration sensor. 25. Device according to one of claims 12 to 22, characterized in that the at least one sensor ( 10 ; 50 ) is a magnetic field sensor. 26. The device according to claim 25, characterized in that the magnetic field sensor ( 10 ; 50 ) is installed in a module, which further comprises a current conductor and fastening elements for fastening the module, so that a non-contact current sensor is formed. 27. The device according to claim 25 or 26, characterized in that the magnetic field sensor ( 10 ; 50 ) has at least one Hall probe, in particular a spinning current Hall probe or Hall probe connected at 90 °. 28. The apparatus according to claim 27, characterized in that the signal processing circuit has a feedback circuit ( 18 ; 74-86 ) with high loop gain in order to offset the at least one Hall probe ( 10 ; 50 ) and / or at least one amplifier ( 14-16 ; 52 , 54 ) to suppress.