DE19620435C1 - Negative measurement error compensation method - Google Patents

Abstract

The sensor device includes a device which generates a measurement signal which represents air mass flow. The sensor also includes a correction circuit and a matching circuit. The measurement signal has a negative measurement error caused by pulses of the air mass flow. A correction signal is generated by the correction circuit depending on the amplitude of an oscillation circuit depending on the amplitude of an oscillation of the measurement signal. The oscillation is caused by pulsating of the air mass flow. An output signal is generated by the matching circuit due to the measurement signal influenced by the correction signal.

Description

The invention relates to a method for compensating a Measurement error of a measurement representing an air mass flow signals.

An important area of application of such a method is the measurement of an air mass flow in the intake tract ner internal combustion engine. This measurement is particularly important tig to the combustion process of an internal combustion engine so to be able to control that the pollutant emissions as low as possible is.

The invention is based on a known sensor device (DE 43 42 481 A1) which has a transducer which is in a Bridge circuit is arranged. The transducer becomes a Generated measurement signal that represents the air mass flow. The Measurement signal is, for example, a voltage that is applied to a Wi the state that falls in the same bridge branch as the Auf is arranged. The sensor is, for example, as Hot film resistor formed and on a substrate arranges. In a second bridge branch there is a temperature lower pending high-impedance resistor arranged, whereby the measuring signal is independent of the ambient temperature.

In the known sensor device there is a heating resistor downstream of a main flow direction of air in one Suction nozzle arranged. The heating resistor is heated up when reverse flows of air occur in the suction port. The return air is heated so that it has no heat picks up on the transducer and thus does not ver ver fakes.  

It is known for the substrate of the hot film resistor glass to use. This has the advantage that glass is a thermal insulation gate and therefore no heat coupling to a carrier or to a mass with a large heat capacity. So changes in the air mass flow have an external effect very little delay on the measurement signal. Furthermore can the contacts to the hot film resistor by simple Soldering instead of being made by bonding. The mechanical Stress on the glass is also less than z. B. from Ceramics.

Pulsations occur in the suction port, which are caused by the geometry of the intake tract of an internal combustion engine and depend on the number of cylinders. Pulsations are peri odd fluctuations in air flow that are not necessary must lead to a reversal of the flow direction. Pulsations are particularly pronounced in internal combustion engines with up to four cylinders.

The disadvantage of the operation of the known sensor device is that the measurement signal has a measurement error caused by the fluctuations in the air flow - i.e. due to pulsations - is caused. This mistake is particularly pronounced if glass is used for the substrate. Then he can up amount to 20% of the correct value of the measurement signal.

It is the object of the invention to specify a method through which a measurement error of a measurement signal in the event of pulsations of the Air mass flow is compensated.

The object is achieved by a method with the Features solved according to claim 1.

The solution is based on the knowledge that pulsations ei nes air mass flow lead to a measurement error and that the The amount of this measurement error depends on the amplitude  the pulsation of the air mass flow. This is proportional to the amplitude of an oscillation of the measurement signal or an off output signal.

Advantageous embodiments of the invention are in the Un marked claims.

An embodiment of the invention is below Reference to the schematic drawings explained in more detail.

Show it:

Fig. 1 a sensor device for performing the method OF INVENTION to the invention,

Fig. 2 is an internal combustion engine with the sensor device according to Fig. 1,

Fig. 3 shows a transducer and a control circuit according to FIG. 1,

Fig. 4 is a block diagram of a correction circuit of FIG. 1,

FIG. 5a is a waveform applied to a measurement voltage U _M and a target voltage U _SOllM over time t,

Fig applied. 5b shows a waveform of a voltage U _A1 over time t,

Fig. 5c applied a waveform of a voltage U _A2 over the time t,

Fig. 5d applied a waveform of a voltage U _A3 over the time t,

Fig. 6 is a circuit diagram of the matching circuit,

Fig. 7 is a circuit diagram of the correction circuit.

The same elements become the same across all figures Provide reference numerals.

A sensor device 1 has a sensor 11 , which is connected to a control circuit 12 in an electrically conductive manner. The sensor 11 is formed, for example, as a hot film resistor, which is arranged on a glass substrate. From the transducer 11 , a measurement signal S _M is generated, which represents an air mass flow that flows past the transducer.

The transducer 11 is electrically conductively connected to an adaptation circuit 14 in such a way that the measurement signal S _M is fed to it as an input variable. In the correction circuit 13 , a correction signal S _{K is} generated, which is dependent on the amplitude of an oscillation of the output signal S _A , which is caused by the pulsations of the air mass flow.

The correction circuit 13 is electrically conductively connected to the adaptation circuit 14 , so that the correction signal S _{K is} supplied to the adaptation circuit 14 as an input variable. From the matching circuit 14 , an output signal S _A is generated. For this purpose, suitable circuit means are provided by which the output signal S _{A is} generated by influencing the measuring signal S _M by the correction signal S _K. Thus, the correction signal S _K can advantageously additively superimposed on the measurement signal S _M and the superimposed with the correction signal S _K S _M are amplified measurement signal, thereby generating the input signal from S _A.

The amplitude of the vibration of the measurement signal S _M and the amplitude of the vibration of the output signal S _A are in a ratio predetermined by the gain in the matching circuit. The advantage of the output signal S _A as an input variable for the correction circuit 13 is that the amplitude of the oscillation of the output signal S _{A is} large. This enables the correction signal S _{K to} be determined more precisely.

Fig. 2 shows an internal combustion engine with the Sensoreinrich device 1 , which is arranged in a suction port 2 . In this exemplary embodiment, a throttle valve 3 is arranged downstream of the sensor device 1 in the intake port. Accordingly, the internal combustion engine is operated according to the Otto principle. For the invention, however, it is immaterial whether it is an internal combustion engine based on the Otto principle or the diesel principle.

The suction nozzle 2 opens into a collector 4, from each of which a suction pipe 5 leads to a cylinder 6 . The output signal of the sensor device 1 is an input variable for a motor control 7 . The output signal S _A serves as a load variable in engine control and is used to calculate the injection time and injection duration for an injection valve. For ge accurate calculation of the air flowing into the cylinder 6 , a flow model of the collector and the suction pipe can also be stored in the engine control. Such a flow model is known per se and is not essential for the invention. Depending on the output signal S _A , the actual air mass flow in the cylinder 6 is determined with the aid of such a flow model. In particular, in the case of transient operating states of the internal combustion engine - that is to say during load change processes - there must be a reliable output signal S _{A for} this. The output signal S _A can also be supplied to other control devices.

Fig. 3 shows a circuit arrangement with the transducer 11 and the control circuit 12. The circuit arrangement comprises a measuring bridge with a first and a second bridge branch as well as a first differential amplifier 122 and a controller 123 . In the first bridge branch, the transducer 11 and a resistor R3 arranged in series therewith are arranged. The pickup 11 is formed, for example, as a hot film resistor and arranged on a glass substrate. In the second bridge branch, a temperature sensor 121 is arranged, which is designed as a temperature-dependent high-resistance. Resistors R1 and R2 are arranged in series with the temperature sensor 121 . The sensor 11 and the temperature sensor 121 are arranged in the suction nozzle 2 .

The measuring bridge is supplied with voltage by the controller 123 at point A. Point B of the measuring bridge is grounded. The operational amplifier 122 is connected at its non-inverting output to a tap point c, which is arranged between the pickup 11 and the resistor R3. The first operational amplifier is connected at its inverting input to a tap point D of the measuring bridge, which is arranged between the resistor R1 and the resistor R2. In the first differential amplifier 122 , the potential difference between the tapping points C and D is accordingly amplified and fed to the controller 123 as a controlled variable. Such a current is embossed by the controller 123 at point A of the measuring bridge, so that the potential difference between the tapping points C and D approaches zero. The temperature sensor 121 and the resistors R1 and R2 are dimensioned 50 so that the power loss of the temperature sensor 121 is so low that the temperature of the temperature sensor 121 practically does not change with the changes in the current at point A, but always corresponds to the temperature of the air mass flow . Changes due to changes in the amount of air mass flow, the temperature of the sensor 11 , so the potential difference between points C and D changes and the controller 123 regulates the current point A accordingly until it reaches a value at which the potential difference between the Ab handle points C and D goes back to zero. A measuring voltage U _M at the tap point C is the measuring signal S _M , which represents the air mass flow.

In FIG. 4 is a block diagram of the correction circuit 13 is shown. The function of the individual elements of the correction circuit 13 will be explained with reference to FIGS . 5a to d, in which waveforms are plotted over time t, where their input signal U should initially correspond to the output signal of the adaptation circuit 14 without the correction circuit 13 acting .

The correction circuit 13 has a filter unit which is designed as a high-pass filter 131 , to which the voltage U is supplied as an input variable.

In Fig. 5a shows a waveform of the voltage U is shown, when the air mass flow pulsations occur. Likewise, the signal curve of a target voltage U _{SOLL is} plotted in FIG. 5 a, which would be expected instead of U if no measuring errors occurred. From a point in time t1 to a point in time t2, the load and accordingly the air mass flow increase. The amplitude of the oscillation of the voltage U increases. From Fig. 5a can be clearly seen that the voltage U has a Meßfeh ler compared to the target voltage U _target. The measurement error is approximately proportional to the amplitude of the oscillation of the voltage U.

The high-pass filter 131 is dimensioned in such a way that oscillations of the voltage U are passed at frequencies which lie in the frequency range of pulsations of the air mass flow. In an internal combustion engine with four cylinders, this frequency range is approximately 23 to 100 Hz.

The voltage U _A1 at the output of the high pass 131 then only has the oscillation of the voltage U, which is caused by the pulsation (cf. FIG. 5b).

The voltage U _A1 is then fed to a rectifier 132 , which is designed either as a one-way rectifier or as a two-way rectifier. In Fig. 5c, the waveform of the voltage U _A2 is shown at the output of the rectifier on the time. In this embodiment, the rectifier is designed as a one-way rectifier, so the voltage U _{A2 has} only one half-wave of the voltage U _A1 - here the positive half-wave. The voltage U _A2 is _fed to the input of a low pass 133 , through which the voltage U _{A2 is} smoothed. The voltage U _A3 , which is the smoothed voltage U _A2 , is then present at the output of the low pass 133 . The voltage U _A3 is therefore directly proportional to the amplitude of the oscillation of the voltage U, which is caused by pulsations in the air mass flow. The correction circuit 13 further comprises an adaptation unit, which is designed as a voltage-controlled current source 134 , in which a correction current I _{K is} generated, which is directly proportional to the voltage U _A3 .

The current steepness S of the voltage-controlled current source 134 is predetermined such that the output voltage U _{A of} the Sensorein direction is raised by the correction current I _K under the action of the correction on the adaptation circuit in such a way that it increases the desired voltage U according to the amplification of the adaptation circuit 14 _SHOULD correspond.

In Fig. 6 is a circuit diagram of the matching circuit 14 is provided. The circuit has a non-inverting amplifier which consists of a second differential amplifier 141, a resistor R4 and a resistor R5. The correction circuit 13 is arranged parallel to its feedback branch. A correction current I _{K is} impressed in the direction shown by the correction circuit 13 . The water correction current leads to an additional drop in voltage across the resistor R4, so that the voltage U _{A is} raised. The voltage U _A results from the following relationship as a function of the measuring voltage U _M and the correction current I _K :

As can be seen from FIG. 6, the correction circuit 13 is supplied with the output voltage U _A as an input variable. If the output voltage U _{A is used} as an input variable in the correction circuit, this has the advantage that the vibration has a large amplitude and therefore simpler components can be used for the correction circuit.

In Fig. 7 a detailed embodiment, the Cor rekturschaltung shown in FIG. 4. Resistors R6 and R7 and capacitor C1 form high pass 131 . The resistors R8 and R9, a third differential amplifier 1321 and the low-pass filter 131 form the rectifier 132 . A resistor R10 and a capacitor C2 form the low pass 133 . A fourth operational amplifier, a transistor 1342 and an opposing stand R11 form the voltage controlled current source 134 .

The transistor 1342 and the resistor R11 are sioned dimen such that the voltage U _A3 such values of the correction current I _K associated with that of the correction current I _C, respectively, the output voltage U _A so raising that the error of the measurement voltage U _M is compensated .

The resistors R9 and R10 have approximately the same resistance values (e.g. 300 K ohms). The resistor R6 has a slightly higher resistance than the resistor R8 (e.g. R6 = 102 K Ohm and R8 100 K Ohm). Noise in the measuring voltage U _M does not affect the voltage U _A2 .

The embodiments of the invention are not limited to the circuit examples shown here. You are suitable for example, also for the realization on one user-specific IC (ASIC).

In a further embodiment of the invention, the sensor device has a processing unit 14 A, in which the output voltage U _A is averaged in each case over a pulsation period. The output voltage U _A thus averaged is then a measure of the mean air mass flow per pulsation period.

In a further embodiment of the invention, the filter unit is designed as a bandpass. This has the advantage that high-frequency noise of the measurement signal S _M does not affect the correction signal S _K.

In a further embodiment of the invention, the Fil tereinheit is designed such that a load change frequency z. B. 1-5 Hz), the measurement signal (S _M ) or the output signal (S _A ) in a load change process in an internal combustion engine, is in its passband. A load change process takes place when the opening angle of a throttle valve of an internal combustion engine is changed (see FIGS. 5a-5d, time t1 to t2). When increasing the opening angle, the air pressure difference upstream and downstream of the throttle valve must first be compensated for. The air mass flow has a periodic settling behavior. If the output signal S _{A is used} as an input variable for an above-mentioned flow model, it is advantageous if the signal components of the measurement signal S _M which are in the range of the load change frequency influence the correction signal. By choosing the cut-off frequency of the low-pass filter 133 , the output signal S _{A can have} aperiodic to periodic transient response during a load change process.

Claims (5)

1. A method for compensating for a measurement error of a measurement signal representing a mass air flow of a sensor in the event of a pulsation of the mass air flow, in which

• - The measurement signal (S _M ) is influenced by a correction signal (S _K ) and thus an output signal (S _A ) is generated, and
• - The correction signal (S _K ) is generated depending on the amplitude of a vibration of the output signal (S _A ) with a frequency in the frequency range of the pulsation.

2. The method according to claim 1, wherein the correction signal S _K ) by rectifying an alternating component of the output signal (S _A ). is produced. 3. The method according to claim 1 or 2, in which the correction signal (S _K ) is smoothed and amplified. 4. The method according to any one of claims 1 to 3, wherein the output signal (S _A ) results from the addition of the correction signal (S _K ) and the measurement signal (S _M ). 5. The method according to any one of claims 1 to 4, wherein the output signal (S _A ) is averaged over a pulsation period.