This application claims the benefit of German Application No. 102017211970.5, filed on Jul. 12, 2017, which application is hereby incorporated herein by reference in its entirety.
The present application related generally to sensors and, in particular embodiments to a sensor arrangement and a method for testing a sensor arrangement.
Capturing environmental or ambient parameters, such as noise, sound, temperature and gases or gas compositions in the ambient atmosphere, for example, is becoming ever more important within the scope of the implementation of a corresponding sensor system within mobile devices, but also in the application in home automation (“smart home”) and in the automotive sector. Thus, harmful gas concentrations, elevated CO or NOx concentrations, for example, may occur on account of air pollution or else on account of a malfunction of devices situated in the surroundings. Thus, the well-being of the person or any living being in general is influenced strongly by the air quality. Consequently, capturing gases by means of cost-effective, permanently available and linked sensors represents a theme that will come ever more prominently to the fore in future. However, with the ever more comprehensive use of sensors, there is also, in particular, a need to determine, with as little outlay as possible but nevertheless exceedingly reliably, whether the sensor for capturing an ambient parameter is operating correctly or whether a malfunction of the sensor is present or whether a relevant deviation from the predetermined operational parameters of the sensor is already present.
According to exemplary embodiments, a sensor arrangement 100 comprises a pressure transducer 110 with a fluid connection to a volume region 130 having a fluid F, wherein the pressure transducer 110 is embodied, in response to a pressure change ΔP in the volume region 130, to output a pressure signal SP with a signal curve SΔP depending on the pressure change ΔP, a heating element 150 that is embodied to bring about a defined temperature change ΔT of the fluid F situated in the volume region, wherein the temperature change ΔT of the fluid F brings about a pressure change ΔP in the volume region 130, and a processing device 170 that is embodied to ascertain a current functional parameter FIST of the pressure transducer 110 on the basis of the signal curve SΔP of the pressure signal SP obtained in the volume region 130 in the case of a temperature change ΔT brought about by the heating element 150.
According to exemplary embodiments, a method 200 for testing a sensor arrangement 100 includes producing 210 a defined temperature change ΔT of a fluid F situated in a volume region 130, wherein the temperature change ΔT of the fluid F brings about a pressure change ΔP in the volume region 130, capturing 220 the pressure change P in the volume region 130 by a pressure transducer 110 in fluid connection with the volume region 130 having the fluid F, outputting 230 a pressure signal with a signal curve SΔP depending on the pressure change ΔP in response to the pressure change ΔP in the volume region 130, and ascertaining 240 a current functional parameter FIST of the pressure transducer 110 on the basis of the signal curve SΔP of the pressure signal SP, which is obtained during the temperature change ΔT in the volume region 130.
Consequently, exemplary embodiments relate to an acoustic test concept for a sensor arrangement having a pressure transducer and to ascertaining calibration information items for the sensor arrangement having the pressure transducer, wherein the pressure transducer can be embodied, for example, as a capacitive, inductive or piezoelectric sound transducer, such as a microphone, for example.
So-called PAS (PAS=photoacoustic spectroscopy) sensors using a microphone use thermal sources or heating elements to produce the required IR (IR=infrared) radiation. According to exemplary embodiments, use can be made of precisely this thermal source, for example, in order to produce an acoustic pressure change in a volume region, i.e., a measurement volume or back volume of a microphone, wherein a pressure transducer or microphone has a fluid connection to the volume region. On the basis of the signal curve of a pressure change in the volume region, captured by the microphone and caused on account of the heating of the fluid situated therein that is produced in a defined and targeted manner, it is possible, for example, to determine functional parameters of the pressure transducer, such as, e.g., the sensitivity thereof, etc., or else further system properties of the sensor arrangement. A known temperature change, by way of a defined energy, for example, is brought about in the volume region by way of the thermal source that is effective as a heating element. This temperature change can be obtained on the basis of the result of an electrical of thermal characterization of the heat source for the factory or customer test case.
Using this procedure for testing and/or calibrating the sensor arrangement having the pressure transducer, there is no need, for example, for an additional external sound source, wherein the internal thermal source, for example, is used as a thermo-acoustic transducer, wherein the defined temperature change in the volume region brought about by this thermo-acoustic transducer is captured or measured by way of the pressure change in the volume region, resulting therefrom, by means of the pressure transducer or microphone. Any component providing a defined amount of heat can be used as a thermal heat source.
According to exemplary embodiments, the signal curve of the pressure signal, which is obtained in the case of a temperature change in the volume region brought about by the heating element, now can be evaluated on the basis of the “ideal gas law” in order to obtain current operational properties of the pressure transducer, wherein these measured operational properties can be compared to setpoint values in order, ultimately, to ascertain a calibration information item for the pressure transducer or for the sensor arrangement having the pressure transducer.
Exemplary embodiments of apparatuses and/or methods are described in more detail below in an exemplary manner, with reference being made to the attached figures. In the figures:
Before exemplary embodiments of the present invention are explained more specifically in detail below with reference to the drawings, it is pointed out that identical functionally equivalent or identically acting elements, objects, functional blocks and/or method steps are provided with the same reference signs in the different figures, and so the description of said elements, objects, functional blocks and/or method steps that is presented in different exemplary embodiments is mutually interchangeable or can be applied to one another.
Exemplary embodiments relate to a sensor arrangement and a method for testing or calibrating a sensor arrangement, and, in particular to an in situ test of thermo-acoustic microphones or of sensor arrangements using thermo-acoustic microphones. Further, exemplary embodiments relate generally to a calibration method of a sound transducer, such as, e.g., a microphone, or photoacoustic sensor arrangement (PAS=photoacoustic spectroscopy) or of a gas sensor. In some embodiments, a functional parameter of a sensor arrangement or the functionality of a sensor arrangement is monitored and appropriate calibration information is determined therefrom.
Below, the basic construction of a sensor arrangement 100 and the basic functionality thereof according to exemplary embodiments is presented on the basis of the schematic illustrations of
The sensor arrangement 100 has a pressure transducer 110 with a fluid connection to a volume region 130 having a fluid F. According to exemplary embodiments, a fluid may have a gas or gas mixture or a liquid or liquid mixture. Now, the pressure transducer 110 is embodied, in response to a pressure change ΔP in the volume region 130, to output a pressure signal SP with a signal curve SΔP depending on the pressure change ΔP, for example. Now, the sensor arrangement 100 further has a heating element 150 that is embodied to bring about a defined temperature change ΔT of the fluid F situated in the volume region 130, wherein a temperature change ΔT of the fluid F brings about a pressure change ΔP in the volume region 130. The sensor arrangement 100 further has a processing device 170 that is embodied to ascertain a current functional parameter FIST of the pressure transducer 110, or else a calibration information item ICAL for the pressure transducter 110, on the basis of the signal curve SΔP of the pressure signal SP obtained in the volume region 130 in the case of a temperature change ΔT brought about by the heating element 150. At the same time, the processing device 170 can also assume, or else directly contain, the actuation of the heating element 150.
The optional configurations of the sensor arrangement 100 according to further exemplary embodiments, described below, can be applied alternatively or else in any combination (provided nothing else is explicitly presented) to the sensor arrangement 100 illustrated in
According to an exemplary embodiment, the processing device 170 is now embodied to ascertain a current operational parameter FIST of the pressure transducer 110 on the basis of the signal curve SΔP of the pressure signal SP and in order to ascertain the calibration information item ICAL for the pressure transducer 110 therefrom. According to exemplary embodiments, the processing device 170 can further be embodied to control, i.e., activate and subsequently deactivate again, the heating element 150 with a control signal SCONTROL.
According to exemplary embodiments, the heating element 150 further can be embodied as part of the processing device 170.
According to exemplary embodiments, the pressure transducer 110 can be embodied as an absolute pressure sensor element, relative pressure sensor element and/or differential pressure sensor element. Further, the pressure transducer 110 can be embodied to capture the pressure change ΔP in the volume region 130 in relation to a reference pressure PREF in an optional reference volume region 190.
According to exemplary embodiments, an equalization opening or ventilation opening 132 may be provided (optionally) between the volume region 130 and the reference volume region 190. According to exemplary embodiments, the volume region 130 and the reference volume region 190 also can be embodied separately from one another (not shown in
Now, the heating element 150 is embodied to bring about the defined temperature change ΔT in the volume region 130 with the fluid F situated therein, while the reference volume region 190 may be uninfluenced by the temperature change ΔT of the fluid F in the volume region 130, for example, apart from substantially unavoidable heat conduction or heat transmission effects (convection), which are generally negligibly low.
According to exemplary embodiments, the pressure transducer 110 has a membrane or lamella 112 that is deflectable on the basis of the acting pressure or the acting pressure change ΔP, wherein this mechanical deflection can be evaluated or read capacitively, inductively, piezo-resistively, optically, for example, or by means of any other suitable physical effect. By way of example, reading and evaluating the pressure signal can be carried out by the processing device 170.
In the case of a capacitive principle, a deflectable membrane 112 of the pressure transducer 110 thus is exposed to the pressure to be measured. The bend or deflection of the membrane causes a change in the distance between the membrane and a stationary electrode or counterelectrode (not shown in
According to further exemplary embodiments, the deflection or the geometric deformation of the membrane can also be read by means of, e.g., implanted, piezo-resistive resistors in the membrane (not shown in
According to exemplary embodiments, the deformation of the membrane on account of the acting pressure change ΔP can also be captured optically by virtue of the degree of mechanical deflection of the deformable membrane being captured optically.
According to exemplary embodiments, use can be made further of resonant pressure sensors, wherein, in the case of a resonant pressure sensor, a correspondingly designed resonator is connected to the element that detects the pressure, wherein the deformation of the element that detects the pressure has a deformation of the resonator as a consequence and hence a corresponding change in the resonant frequency of the resonator, which can be read and evaluated in turn. Consequently, the resonant frequency of the resonator has a dependence on the pressure to be measured.
The list, above, of different pressure sensor elements should only be considered to be exemplary and not exhaustive since substantially any pressure sensor element can be used as a pressure transducer 110 for the sensor arrangement 100.
According to an exemplary embodiment, the heating element 150 is embodied, upon activation of same, to bring about a temperature increase ΔT that is as defined as possible of the fluid F situated in the volume region 130. Further, according to an exemplary embodiment, the heating element 150, upon deactivation following an activated state of the heating element 150, can be further embodied to bring about a temperature reduction ΔT of the fluid F situated in the volume region 130.
As the explanations below will further show, the heating element 150 can be arranged in full, or else only in part, within the volume region 130 with the fluid F. The heating element 150 also can be arranged outside of the volume region 130 provided the thermal energy provided by the heating element 150 can bring about (directly or indirectly) a temperature change of the fluid F situated therein.
The heating element or else the thermal source 150 is therefore able to modify the fluid temperature, the gas or liquid temperature, for example, in the volume region 130 in a targeted manner, wherein substantially any thermal source can be used to this end. For thermal sources or heating elements 150, use can be made of radiation emitters, such as IR (IR=infrared) emitters, for example, the emitted electromagnetic radiation of which is convertible into thermal energy in the volume region 130 or able to bring about (directly or indirectly) a temperature change of the fluid situated therein, or else of circuit elements such as resistor elements, transistors or diodes, which may be arranged on an ASIC (ASIC=application-specific integrated circuit), for example, or which else may be embodied as separate components. Further, impedances can also be used as thermal sources 150, said impedances, e.g., being switched in the frequency range in order to bring about power losses in these components, with these power losses, in turn, bringing about the temperature increase in the volume region with the fluid F situated therein. Further, the heating element 150 also can be embodied in the pressure transducer 110 and, therein, at the membrane or lamella, for example, which itself then can be effective as a heating structure.
According to an exemplary embodiment, the pressure transducer 110 can be embodied as a sound transducer, for example, wherein the microphone membrane or else the back plate (counterelectrode) itself can be effective as the heating structure of the heating element 150. According to an exemplary embodiment, the heating element 150 also can be implemented by an absorption area within the volume region 130, wherein an optical source, i.e., a source that emits electromagnetic radiation, can be embodied to activate the defined, e.g., dark or black, absorption area by irradiation with light, e.g., laser light, i.e., to bring about a defined temperature increase of the absorption area and hence of the volume region 130 as well.
It is clear from the explanations above that, according to exemplary embodiments, substantially any heat source that can bring about a defined temperature change of the fluid F situated in the volume region 130 can be used as the heating element 150 in the measurement volume or volume region 130. Consequently, the list, above, of heating elements should be considered to be only exemplary and not exhaustive.
According to an exemplary embodiment, the heating element 150 can be embodied to introduce a constant amount of heat (energy) into the volume region 130 for a predetermined time period. According to a further exemplary embodiment, the heating element 150 can be embodied to provide a variable heat energy/time function as a controllable heat source if use is made of a regulator to target a defined temperature, for example.
According to an exemplary embodiment, the “ideal gas law” can be applied to the pressure curve, i.e., to the current pressure P or the pressure change ΔP in the volume region 130, for the sensor arrangement 100, illustrated in
PV=nRT,
where P=current pressure, V=volume, n=number of moles, R=gas constant and T=temperature of the fluid F in the volume region 130.
A volume change (volume increase or volume reduction) ΔV, and resulting therefrom, a pressure change in the form of a pressure increase or pressure reduction ΔP is brought about in the volume region 130 proceeding from a defined temperature change ΔT of the fluid F in the volume region 130 by means of the heating element 150, while a ventilation or equalization is brought about as a pressure equalization between the volume region 130 and the reference volume region 190 through the equalization opening or ventilation opening 132. According to the formula above, the pressure P will be modified according to its known fluid properties (mR), while the temperature T is set with the heating element 150 as a thermal source, while the volume V of the volume region 130 can be considered to be fixedly set up to the transition point, i.e., up to the onset of the ventilation or the said ventilation becoming effective.
On account of the temperature change ΔT in the volume region 130, the pressure P changes taking account of the ventilation time constant or pressure equalization time constant, wherein this can be considered, for example, as a volume equalization between the volume region 130 and the reference volume region 190. Should the thermal pulse for the temperature change ΔT now be defined and known within a tolerance range, the latter can be used as a calibration pulse, for example, since the various properties of the pressure transducer 110 can be derived or extracted from the signal curve SΔP depending on the pressure change ΔP, such as, e.g., the sensitivity from the absolute pressure and the transition behavior in the form of the limit frequency or ventilation frequency.
By way of example, for presentation purposes, the intervals IN in
In the illustration of
Now, the heating element 150 is activated at the time to at the start of the time interval L such that the fluid temperature T increases from the initial temperature T0, i.e., the ambient temperature, for example, to the increased temperature T1, with T1=T0+ΔT, at the time t1 at the end of the time interval L. By way of the defined supplied amount of heat by the heating element 150, the temperature change ΔT can be set to the elevated temperature value T1 within a tolerance range of 50%, 20%, 10% or 1%, for example. In response to the temperature increase ΔT of the fluid F in the volume region 130, there is a corresponding pressure increase ΔP of the fluid F in the volume region 130 with a correspondingly increasing signal curve SΔP. By way of example, an equilibrium state in the form of a local maximum of the signal curve SΔP sets in at the time ta. Here, at the time ta, the pressure increase ΔP in the volume region 130 caused by the temperature increase ΔT of the fluid F and the fluid exchange occurring through the equalization or ventilation opening 132 between the volume region 130 and the reference volume region 190 obtain an equal value.
The temperature curve T which, starting at the time t0, has a temperature increase ΔT having an ever smaller grade, now reaches a substantially thermally stable value T1 by the time t1, while the membrane 112 of the pressure transducer 110 relaxes again. Here, the equalization opening 132 between the volume region 130 and the reference volume region 190 is effective as a pressure release valve and substantially equalizes the pressure conditions in the volume region 130 and the reference volume region 190 again such that the pressure curve at the time t1 (e.g., t1=5τ) in the volume region 130 approximately reaches the initial state S0 again.
By way of example, to a first approximation, the temperature curve in the volume region 130 has a simple exponential function which, in the subsequent intervals, toggles back and forth between the initial temperature T0 and the elevated temperature T1. In the case of a more detailed consideration, the temperature curve can also be assumed to be a plurality of thermal RC functions (exponential functions), which can be coupled to one another.
If the heating element 150 now is deactivated at a time t1, a temperature reduction ΔT of the fluid F situated in the volume region 130, proceeding from the elevated temperature T1, is brought about following the activated state of the heating element 150.
At the time t1, i.e., at the start of the time interval I2, the heating element 150 is now deactivated such that the fluid temperature T reduces again, proceeding from the temperature T1 at the end of the time interval I1. In response to the reduction in temperature ΔT of the fluid F in the volume region 130, there is a corresponding reduction in pressure ΔP of the fluid F in the volume region 130 with a corresponding drop in the signal curve SΔP. By way of example, an equilibrium state in the form of a local minimum of the signal curve SΔP sets in at the time tb. Here, at the time tb, the reduction in pressure ΔP in the volume region 130 brought about by the reduction in temperature ΔT of the fluid F and the fluid exchange occurring through the equalization or ventilation opening 132 between the volume region 130 and the reference volume region 190 obtain an equal value.
The temperature curve T which, starting at the time t1, has a temperature decrease ΔT having an ever smaller drop, now reaches the substantially thermally stable value T0 by the time t2 again, while the membrane 112 of the pressure transducer 110 relaxes again. Here, the equalization opening 132 between the volume region 130 and the reference volume region 190 is effective as a pressure release valve and substantially equalizes the pressure conditions in the volume region 130 and the reference volume region 190 again such that the pressure curve at the time t2 in the volume region 130 reaches the initial state S0 again.
Consequently, there is a deflection of the membrane of the pressure transducer 110 during the time interval I2 between the times t1 and t2 that is in the opposite direction to during the time interval I1.
Now, if the heating element 150 is reactivated at the time t2, a temperature increase ΔT of the fluid F situated in the volume region 130 is brought about again during the time interval I3 following the deactivated state of the heating element 150. Consequently, the explanations in respect of the signal curve during the interval I1 are equally applicable to the time interval I3 again. Equally, the explanations for the time interval I2 are applicable to a possible time interval I4.
By way of example, the intervals IN in
The first and second signal curve S1ΔP, S2ΔP, illustrated in
Now, the heating element 150 is activated at the time t0 at the start of the time interval I1 such that the fluid temperature T increases from the initial temperature T0, i.e., the ambient temperature, for example, to the increased temperature T1, with T1=T0+&77 T, at the time t1 at the end of the time interval I1. By way of the defined supplied amount of heat by the heating element 150, the temperature change ΔT can be set to the elevated temperature value T1 within a tolerance range of 50%, 20%, 10% or 1%, for example. In response to the temperature increase ΔT of the fluid F in the volume region 130, there is a corresponding pressure increase ΔP of the fluid F in the volume region 130 with a correspondingly increasing signal curve SΔ1P or SΔ2P. By way of example, an equilibrium state in the form of a local maximum of the signal curve SΔP sets in at the time ta. Here, at the time ta, the pressure increase ΔP in the volume region 130 caused by the temperature increase ΔT of the fluid F and the fluid exchange occurring through the equalization or ventilation opening 132 between the volume region 130 and the reference volume region 190 obtain an equal value.
The temperature curve T which, following the time ta, has a temperature increase ΔT that reduces ever further, now does not yet reach a substantially thermally stable value T1 by the time t1, while the membrane 112 of the pressure transducer 110 relaxes again. Here, the equalization opening 132 between the volume region 130 and the reference volume region 190 is effective as a pressure release valve and only partly equalizes the pressure conditions in the volume region 130 and the reference volume region 190 again such that the pressure curve at the time t1 in the volume region 130 reaches an intermediate state SX.
If the heating element 150 now is deactivated at the time t1, a temperature reduction AT of the fluid F situated in the volume region 130 is brought about following the activated state of the heating element 150.
At the time t1 at the start of the time interval I2, the heating element 150 is now deactivated such that the fluid temperature T reduces again, proceeding from the temperature T1 at the end of the time interval I1. In response to the reduction in temperature ΔT of the fluid F in the volume region 130, there is a corresponding reduction in pressure ΔP of the fluid F in the volume region 130 with a corresponding drop in the signal curve S1ΔPS2ΔP. By way of example, an equilibrium state in the form of a local minimum of the signal curve S1ΔP, S2ΔP set in at the time tb. Here, at the time tb, the reduction in pressure ΔP in the volume region 130 brought about by the reduction in temperature ΔT of the fluid F and the fluid exchange occurring through the equalization or ventilation opening 132 between the volume region 130 and the reference volume region 190 obtain an equal value.
The temperature curve T which, following the time tb, has a temperature decrease ΔT that reduces ever further, now does not yet reach a thermally stable value by the time t2, while the membrane 112 of the pressure transducer 110 relaxes again. Here, the equalization opening 132 between the volume region 130 and the reference volume region 190 is effective as a pressure release valve and substantially equalizes the pressure conditions in the volume region 130 and the reference volume region 190 again such that the pressure curve at the time t2 in the volume region 130 reaches an intermediate state SY.
Consequently, there is a deflection of the membrane of the pressure transducer 110 during the time interval I2 between the times t1 and t2 that is in the opposite direction to during the time interval I1.
Now, if the heating element 150 is reactivated at the time t2, a temperature increase ΔT of the fluid F situated in the volume region 130 is brought about again during the time interval I3 following the deactivated state of the heating element 150. Consequently, the explanations in respect of the signal curve S1ΔP, S2ΔP during the interval I1 are equally applicable to the time interval I3 again. Equally, the explanations for the time interval I2 are applicable to a possible time interval I4.
According to an exemplary embodiment, the processing device 170 now is embodied to ascertain a current operational parameter FIST of the pressure transducer 110 on the basis of the signal curve SΔP or S1ΔP, S2ΔP, of the pressure signal SP.
According to exemplary embodiments, the processing device 170 can be further embodied to control, i.e., activate and subsequently deactivate again, the heating element 150 using a control signal SCONTROL.
In respect of the signal curves SΔP or S1ΔP, S2≢P, illustrated in
According to exemplary embodiments, the processing device 170 now can be further embodied to compare the current functional parameter FIST to a setpoint functional parameter FSOLL of the pressure transducer 110 and obtain a comparison result, and ascertain the calibration information item for the pressure transducer 110 or the sensor arrangement 100 on the basis of the comparison result. Now, the processing device 170 can be embodied further to set or change, on the basis of the ascertained calibration information FCAL, an operational or actuation parameter for the pressure transducer and/or a processing parameter for the pressure transducer or for the provided pressure signal SP with the signal curve SΔP depending on the change in pressure ΔP, i.e., undertake an appropriate adaptation of the operational parameter or of the processing parameter on the basis of the evaluated signal curve SΔP. Thus, for example, a modified operational parameter of the pressure transducer 110 can bring about a modified actuation of the pressure transducer 110 by the processing device. Further, a modified processing parameter of the pressure transducer 110 can bring about modified conditioning of the pressure signal SP by the processing device.
A current, ascertained functional parameter FIST of the pressure transducer 110 can be determined by means of the limit frequency of the signal curve SΔP, for example. By way of example, the limit frequency fC can be ascertained according to fC=1/τ from the time constant τ of the signal curve SΔP following an exponential function after the time ta or tb. Thus, the limit frequency is directly connected to the signal drop of the exponential function (after the time ta or tb of the signal curve) and it corresponds to the inverse of the time constant τ. Thus, the quicker the drop in the signal of the signal curve SΔP, the higher the limit frequency fC applies, and vice versa. Consequently, a fluid permeability, i.e. a gas or liquid permeability, of one or more equalization openings or ventilation openings 132 of the pressure transducer 110 can be ascertained from the limit frequency fC as current functional parameter FIST. Thus, a reduction in the limit frequency fC can indicate a reduced fluid permeability of the equalization opening(s) 132 of the pressure transducer 110. Consequently, the limit frequency fC can be used to capture particles should, for example, particles be situated at the equalization opening 132 of the pressure transducer 110 and have such dimensions that these are able to block or plug the equalization opening of the pressure transducter 110, at least in part or else completely. Inter alia, it is also possible to detect particles in the sound port 104.
According to a further exemplary embodiment, a signal level or signal amplitude in the form of a maximum signal level in terms of absolute value or a maximum signal amplitude SMAX (or S1MAX and S2MAX) in terms of absolute value of the signal curve SΔP of the pressure signal SP can be ascertained as a current, ascertained functional parameter of the pressure transducer 110 or the sensor arrangement 100. Here, a change in the signal level or in the signal amplitude of the signal curve SΔP indicates a change in the mechanical membrane flexibility of the membrane 112 of the pressure transducer 110.
According to exemplary embodiments, the maximum signal level or the maximum signal amplitude SMAX of the signal curve SΔP further can be ascertained by the processing device 170, wherein a deviation of the signal level or the signal amplitude (of the maximum signal level or the maximum signal amplitude=peak value) of the signal curves SΔP from a setpoint value of the signal level or the signal amplitude may indicate a deviation of the mechanical membrane flexibility of the membrane of the pressure transducer 110 from a corresponding setpoint value for the membrane flexibility.
The maximum signal amplitude SMAX in terms of absolute value (peak value) in the thermo-acoustic stimulation by means of the heating element 150 yields the output signal level of the sound transducer, of a microphone, for example. This maximum signal amplitude (peak value) is a direct indicator for the mechanical membrane flexibility of the membrane of the pressure transducer 110. Consequently, it is possible to set a bias voltage or an electrical bias of the membrane 112 of the pressure transducter 110, for example by the processing device 170, so as to obtain the best possible correspondence of the peak value SMAX of the signal curve SΔP, measured at ta, tb, with the pre-calibrated comparison or setpoint value, which was obtained within the scope of the factory calibration, for example. Thus, the lower the (maximum) signal amplitude, the stiffer the membrane of the pressure transducer generally applies, wherein, consequently, the bias (bias-voltage), for example, can be set to a higher value by the processing device 170 in order to obtain an electrostatic spring softening effect, for example.
Now, the processing device 170 can be further embodied to provide a value for a modified, electrical bias of the membrane of the pressure transducer 110 as a calibration information item FCAL in order to set or obtain the setpoint value for the mechanical membrane flexibility of the pressure transducter 110, at least approximately (within a tolerance range of 50%, 20%, 10% or 1%), on the basis of the modified electrical bias.
Now, for example, the sensor arrangement 100 can have a plurality of pressure transducers 110, which are arranged in an array, for example. Here, the ascertained, current functional parameter can be a phase information item of the respective signal curve SΔP, S1ΔP, S2ΔP, . . . of the pressure signal SP, S1P, S2P, . . . in the plurality of pressure transducers 110. Thus, the ascertained, current functional parameter can be, for example, a phase alignment of the signal curve SΔP of the pressure signal SP in the plurality of pressure transducers 110. Now, the processing device 170 can be further embodied to ascertain a phase alignment of the signal curve SΔP of the respective pressure signal SP of the plurality of pressure transducers, wherein, for example, a different phase alignment of the signal curve SΔP of the respective pressure signal SP indicates an incorrect installation of that pressure transducer which has the different phase alignment in relation to the further pressure transducers. By way of example, an incorrect installation refers to a back-to-front installation (in respect of rear and front side) of a pressure transducer, such as a sound transducer or microphone, for example. Now, the processing device can be embodied further to provide as a calibration information item a value for inverting the pressure signal SP of the pressure transducer in which an inverted phase alignment of the signal curve SΔP of the respective pressure signal SP is present and was ascertained.
Consequently, the phase alignment of the pressure signal of pressure transducers arranged in an array can be ascertained as ascertained, current functional parameter. By reading the phase of the thermo-acoustic pulse or signal curve SΔP, wherein a heating pulse of the heating element 150 brings about an increasing signal curve, for example, on account of the temperature increase and cooling or a temperature reduction yields a falling signal curve, the read pressure signal SP of that pressure transducer or those pressure transducers in which an incorrect phase alignment was determined can be converted or shifted by 180° in order to correct or homogenize the whole read signal.
In a further exemplary embodiment, the sensor arrangement 100 has, once again, a plurality of pressure transducers 110, for example, said pressure transducers, once again, being arranged in an array, for example, wherein the processing device can be further embodied to ascertain a phase offset of the signal curves SΔP of the different pressure signals SP of the plurality of different pressure transducers 110 of the pressure transducer array. Now, the processing device 170 can be further embodied to provide as a calibration information item a phase adaptation of one or more pressure signals SP of the pressure transducer in the pressure transducer array, in which a phase offset of the signal curves SΔP of the pressure signals SP, which exceeds a limit value, was ascertained.
Consequently, according to exemplary embodiments, phase fine tuning is possible in the array of pressure transducers 110, for example by virtue of, further, fine tuning of the phase as a phase shift being carried out in steps of less than or equal to 180°, for example 0.5°, 1°, 2°, 5°, 10°, etc. This phase fine tuning of the sound transducers 110 arranged in an array can be carried out, for example, after the ascertainment and adaptation of the maximum signal amplitude and/or the phase alignment of individual sound transducers 110 in the array (see above), already described above, was carried out. Using this procedure, it is possible, for example, to adapt or correct sound propagation, wherein, further, read coordination is achieved and, consequently, the read quality of the sound transducers 110 arranged in an array can be increased.
According to exemplary embodiments, the sensor arrangement 100 can have a plurality of pressure transducers 110 that are arranged in an array. Here, the ascertained, current functional parameter of the individual pressure transducers 110 also can be used to determine the functionality of the individual pressure transducers 110 as a matter of principle, i.e., ascertain whether individual pressure transducers of the array are defective. By way of example, should it be determined that individual pressure transducers of the array are defective, it is possible to deactivate these, i.e., the output signal thereof is no longer taken into account, for example by the processing device 170.
Further, a symmetry consideration between the resultant signal curve during a temperature increase and, subsequently, during a temperature reduction, i.e., the symmetry between a hot pulse and cool pulse can be ascertained as further ascertained, current functional parameter FIST of the pressure transducer 110.
Consequently, according to an exemplary embodiment, an ascertained functional parameter of the pressure transducer 110 can be an ambient condition or a change in same. By way of example, an ambient condition is an ambient temperature, an ambient atmospheric pressure (ambient air pressure), an ambient humidity and/or an ambient gas component, such as, for example, a CO component, NOx component, etc., in the ambient atmosphere. Now, the processing device 170 can be embodied further to ascertain the calibration information item for the pressure transducer 110 or the sensor arrangement 100 on the basis of a comparison of a portion of the signal curve SΔP of the pressure signal SP during a heating of the fluid F in the volume region 130 and a second portion of the signal curve SΔP of the pressure signal SP during a cooling of the fluid F in the volume region 130. Thus, the processing device 170 can be embodied further to ascertain the calibration information item on the basis of a symmetry consideration between the first and the second portion of the signal curve SΔP of the pressure signal SP.
When considering the symmetry between a hot pulse and cool pulse, it is possible to take account of the fact that, theoretically, the pressure signal curve during the temperature increase, i.e., during a heating thermo-acoustic pulse, and the pressure signal curve during the temperature reduction, i.e., during a cool pulse, should have substantially the same form. However, since different physical conditions, such as thermal couplings, thermal sources and thermal sinks (heatsinks), for example, or else different control parameters, i.e., different thermal boundary conditions, now are present, the two signal curves in the form of the heating and cooling signal curve are not exactly the same but nevertheless very similar. Thus, for example, a changing difference between the two signal curves, i.e., the heating pressure signal curve and the cooling pressure signal curve, can be assumed to be, and taken into account as, an indicator for changing ambient conditions, for example, a changing ambient temperature, etc.
As already presented above, the sensor arrangement 100 can be a photoacoustic sensor arrangement, a pressure sensor arrangement or a differential pressure sensor arrangement having a MEMS pressure sensor or a MEMS differential pressure sensor, or else a sound transducer arrangement or microphone arrangement.
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The processing device 170 i.e., the illustrated ASIC, for example, now is embodied to ascertain a calibration information item for the sound transducer 110 on the basis of the signal curve SΔP of the pressure signal SP, which is obtained during the temperature change ΔT in the volume region 130 brought about by the heating element 150.
Now, for example, the sound transducer 110 is embodied to ascertain a pressure change ΔP in the volume region 130 (back volume of the microphone) in relation to a reference pressure, e.g., atmospheric pressure, in a reference volume region 190, i.e., the ambient region or front volume region. The exemplary embodiments of the sensor arrangement 100 with the pressure transducer 110, illustrated on the basis of
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With reference to the typical signal curves of
If the fluid interchange is less than the minimum recorded pressure change ΔP of the microphone 119, i.e., if the membrane 112 no longer moves, and if the temperature T tends to be interchanged via the structure mechanism of housing wall (lid) 102-1 or else PCB (carrier) 102-2, then the operational state C is reached, in which an equilibrium sets-in between the internal pressure in the volume region 130 and the external pressure in the outer volume 190. Thus, there no longer is any significant pressure interchange.
Since the temperature T now, once again, reaches a thermally stable value at the end of the interval I2 near or at the time t2, the microphone membrane 112 relaxes again, with the equalization or ventilation opening 132 of the microphone membrane 112 once again being effective as a pressure release valve in the other direction and equalizing the internal pressure P in the back volume 130 with the external pressure of the surroundings 190 such that the state of the microphone arrangement 100 of
A current functional parameter FIST of the microphone no now can be ascertained on the basis of the obtained signal curve SΔP of the pressure signal SP, for example by means of the processing device 170 (ASIC), wherein reference in this respect is made to the explanations relating to ascertaining the current functional parameter of
By way of example, a current, ascertained functional parameter FIST of the pressure transducer 110 can be determined by means of the limit frequency of the signal curve SΔP. According to a further exemplary embodiment, a signal level or signal amplitude in the form of a maximum signal level in terms of absolute value or a maximum signal amplitude SMAX in terms of absolute value of the signal curve SΔP of the pressure signal SP can be ascertained as a current, ascertained functional parameter of the pressure transducer 110 or the sensor arrangement 100. Now, for example, the sensor arrangement 100 can have a plurality of pressure transducers 110, which are arranged in an array, for example. Here, the ascertained, current functional parameter can be a phase information item of the respective signal curve SΔP of the pressure signal SP in the plurality of pressure transducers 110. In a further exemplary embodiment, the sensor arrangement 100 has, once again, a plurality of pressure transducers 110, for example, said pressure transducers, once again, being arranged in an array, for example, wherein the processing device can be further embodied to ascertain a phase offset of the signal curves SΔP of the different pressure signals SP of the plurality of different pressure transducers no of the pressure transducer array. The ascertained, current functional parameter of the individual pressure transducers 110 also can be used to determine the functionality of the individual pressure transducers 110 as a matter of principle, i.e., ascertain whether individual pressure transducers of the array are defective. Further, a symmetry consideration between the resultant signal curve during a temperature increase and, subsequently, during a temperature reduction, i.e., the symmetry between a hot pulse and cool pulse can be ascertained as further ascertained, current functional parameter FIST of the pressure transducer 110. Consequently, according to an exemplary embodiment, an ascertained functional parameter of the pressure transducer 110 can be an ambient condition or a change in same. By way of example, an ambient condition is an ambient temperature, an ambient atmospheric pressure (ambient air pressure), an ambient humidity and/or an ambient gas component, such as, for example, a CO component, NOx component, etc., in the ambient atmosphere.
Further, the additional boundary conditions, such as, for example, humidity, ambient air pressure, etc., can be taken into account when evaluating the microphone signal. By way of example, this can be carried out if the heat capacity of the system 100 changes considerably. In principle, these parameters or boundary conditions are only incorporated into the exponential function of the thermals or the temperature curve; the latter then becomes slightly faster (steeper) or slower (flatter). If the measurement intervals are selected to be sufficiently long (e.g., longer than the worst-case scenario), then these effects should drop out again, i.e., have a negligible influence. By way of example, this is the case if these effects, already as per definition, lie far below the corner frequency (lower limit frequency fC) of the microphone and are therefore very much damped, i.e., below the SNR (signal-to-noise ratio) of the microphone 110.
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Exemplary embodiments of a method 200 for testing a sensor arrangement 100 are now described below on the basis of
In the method 200, a defined temperature increase ΔT of a fluid F situated in a volume region 130 is initially produced in a step 210, wherein the temperature change ΔT of the fluid F brings about a pressure change ΔP in the volume region 130.
Now, the pressure change ΔP in the volume region 130 by a pressure transducer 110 is captured in a step 220, wherein the pressure transducer 110 is in fluid connection with the volume region 130 having the fluid F.
A pressure signal SP with a signal curve SΔP depending on the pressure change ΔP is output in a step 230 in response to the pressure change ΔP in the volume region 130.
A calibration information item ICAL for the pressure transducer 110 is ascertained in a step 240 on the basis of the signal curve SΔP of the pressure signal SP, wherein the signal curve SΔP is obtained during the temperature change ΔT in the volume region 130.
By way of example, the pressure change ΔP in the volume region 130 is captured in relation to a reference pressure PREF in a reference volume region 190 in the step 220 of capturing the pressure change ΔP in order to output the pressure signal SP with the signal curve SΔP depending on the pressure change ΔP.
The step 210 of producing a defined temperature change now can be further carried out, for example, by virtue of the heating element 150 being initially activated in order to bring about a defined temperature increase of the fluid F situated in the volume region 130 and the heating element 150 then subsequently being deactivated following the activated state of same in order to bring about a defined temperature reduction of the fluid F situated in the volume region 130.
In step 240 of ascertaining the calibration information item, a current functional parameter FIST of the pressure transducer 110 further can be ascertained on the basis of the signal curve SΔP of the pressure signal SP, whereupon the current functional parameter FIST can be compared to a setpoint functional parameter FSOLL of the pressure transducer 110 in order to obtain a comparison result, and wherein, further, the calibration information item for the pressure transducer 110 can be ascertained on the basis of the comparison result.
Further, in an optional step 250, an operational parameter or processing parameter can be changed for the pressure transducer 110 on the basis of the calibration information item, wherein a modified operational parameter of the pressure transducer 110 brings about a modified actuation of the pressure transducer 110 and wherein a modified processing parameter of the pressure transducer 110 brings about modified conditioning and/or processing of the pressure signal SP.
According to exemplary embodiments, the processing device 170 of
A flowchart or a block diagram for testing or calibrating a sensor arrangement 100 is now described below on the basis of
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These values should only be assumed to be exemplary and can vary depending on the actual configuration of the sensor arrangement 100.
In
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In
Optionally, the measurement can be effected in a loop; i.e., the test or calibration process either can be terminated here or it can be repeated and run through again accordingly at
Now, a few application options and further aspects of the present concept of the present sensor arrangement 100 and of the concept for testing and calibrating the sensor arrangement 100 are discussed in general terms below.
As already presented above, the present concept is applicable, for example, to microphone arrangements 100 or else to photoacoustic sensors (gas measurement systems) 100 using a microphone 110.
Photoacoustic sensors (PAS sensors) use the photoacoustic effect, in which electromagnetic radiation is absorbed by molecules, with the pressure variations resulting from the absorption being detected directly by means of the pressure transducer 110. Here, different phases can be considered during the production of the photoacoustic signal. Initially, the electromagnetic radiation is absorbed by the molecules at very specific wavelengths. The resultant increase in energy or increase in temperature is shown by a faster movement of the molecules, leading to a pressure increase in the system. In a closed volume, the pressure change or pressure increase is captured by a microphone, for example, and so the absorbed electromagnetic energy is converted into sound. A source of electromagnetic energy with a broadband emission produces a maximum photoacoustic signal in a measurement volume. The emitted electromagnetic radiation is modulated and coupled into the photoacoustic cell filled with the target gas by way of a defined measurement distance. The microphone 110 in the photoacoustic cell 100 detects the pressure variation that arises by the modulated radiation influx. If molecules of the target gas are situated in the measurement distance, some of the electromagnetic radiation is already absorbed in the measurement distance. As a result, there is a reduction in the signal in the photoacoustic cell. By contrast, if no target gas is in the measurement chamber, the pressure signal measured there is at a maximum. The pressure signal consequently provides a statement about the size of the portion of the target gas in the measurement chamber.
Thus, for example, the present concept can be applied to a photoacoustic gas sensor (PAS sensor) 100 and can be considered to be a general microphone calibration concept. Since any thermal source that is able to change the gas temperature during the measurement can be used as a heating element 150, use can also be made of an infrared (IR) emitter, as is used in PAS thermal sources, according to exemplary embodiments.
Now, the processing device 170 can ascertain a current functional parameter FIST of the pressure transducer 110 on the basis of the signal curve SΔP of the pressure signal SP or a calibration information item for the pressure transducer 110. Thus, an operational parameter or processing parameter for the pressure transducer 110 can be modified on the basis of the calibration information item, wherein a modified operational parameter of the pressure transducer 110 brings about a modified actuation of the pressure transducer and wherein a modified processing parameter of the pressure transducer 110 brings about a modified conditioning and/or processing of the pressure signal SP.
According to exemplary embodiments, the processing device 170 of
Since the described test or calibration concept does not use any additional external components and an internal sound source is used as a heat source, the present concept can be used during a calibration in practical use (in the field calibration). Exemplary embodiments further describe a possible factory-side or the customer-side acoustic calibration routine, which is used as an in situ measurement.
Exemplary embodiments of the sensor arrangement 100 or of the method 200 for testing or calibrating the sensor arrangement 100 are applicable without much outlay to existing gas sensor concepts, wherein the test and calibration process, in particular, can be significantly reduced in relation to the previous procedures in the case of PAS gas sensors.
Exemplary embodiments of the present description are focused on an acoustic test concept and a corresponding microphone calibration, for example. Since most PAS sensors already use thermal sources to produce the IR light thereof, precisely this type of heat source, for example, can be used according to exemplary embodiments to produce an acoustic pressure change in the volume region 130 in order to determine the microphone sensitivity and, further, additional system properties. One requirement consists in a known temperature at the heat source, which is the result of the electric or thermal characterization of the factory or customer test case, for example. No additional external or internal sound source is required with the present concept, with the internal thermal source being used as a heating element (as a thermo-acoustic transducer), wherein the temperature change caused by the heating element is captured by the pressure transducer or microphone 110. Consequently, a heating resistor, a closing resistance RON of a transistor or a component that emits electric power losses by heating the same can be used as a heat source.
The present concept for testing and calibrating a sensor arrangement can be used by the customer for an in situ calibration of the pressure transducer or microphone in a photoacoustic gas sensor. The acoustic calibration can also be carried out in advance on the factory-side or during the run-time during automatic calibration processes for fine-tuning at the customer. The entire signal processing can be handled by the processing device (ASIC) 170 with raw data and/or with post-processed data.
Thus, exemplary embodiments describe an acoustic in situ calibration without external acoustic excitations. The acoustic excitations are produced internally by means of a heating source, i.e., the heating element 150, and thermo-acoustic coupling. The thermal source, i.e., the heater, resistor, component with electrical power losses, etc., couples the thermal energy into the measurement chamber gas, i.e., the fluid in the volume region 130, leading to a pressure increase, i.e., heating, or a pressure decrease, i.e., cooling. The transient behavior now indicates pressure transducer or microphone characteristics, such as amplitude or limit frequency, for example. The limit frequency can also be used taking account of the ventilation or equalization concept to distinguish between a tight and a non-tight housing.
According to a first aspect, a sensor arrangement 100 can comprise the following features: a pressure transducer 110 with a fluid connection to a volume region 130 having a fluid F, wherein the pressure transducer 110 is embodied, in response to a pressure change ΔP in the volume region 130, to output a pressure signal SP with a signal curve SΔP depending on the pressure change ΔP, a heating element 150 that is embodied to bring about a defined temperature change ΔT of the fluid F situated in the volume region, wherein a temperature change ΔT of the fluid F brings about a pressure change ΔP in the volume region 130, and a processing device 170 that is embodied to ascertain a current functional parameter FIST of the pressure transducer 110 on the basis of the signal curve SΔP of the pressure signal SP obtained in the volume region 130 in the case of a temperature change ΔT brought about by the heating element 150.
According to a second aspect with reference to the first aspect, the pressure transducer 110 can be embodied to capture the pressure change ΔP in the volume region 130 in relation to a reference pressure PREF in a reference volume region 190.
According to a third aspect with reference to the first aspect, the pressure transducer 110 can have a differential pressure sensor or an absolute pressure sensor.
According to a fourth aspect with reference to the first aspect, the heating element 150, upon activation, can be embodied to bring about a defined temperature increase ΔT of the fluid F situated in the volume region 130.
According to a fifth aspect with reference to the first aspect, the heating element 150, upon deactivation following an activated state of same, can be further embodied to bring about a temperature reduction ΔT of the fluid F situated in the volume region 130.
According to a sixth aspect with reference to the first aspect, the processing device 170 can be further embodied to ascertain a calibration information item ICAL for the pressure transducer 110 on the basis of the current functional parameter FIST of the pressure transducer 110.
According to a seventh aspect with reference to the sixth aspect, the processing device 170 can be further embodied to compare the current functional parameter FIST to a setpoint functional parameter FSOLL of the pressure transducer 110 and obtain a comparison result, and to ascertain the calibration information item ICALL, for the pressure transducer 110 on the basis of the comparison result.
According to an eighth aspect with reference to the first aspect, the processing device 170 can be further embodied to change an operational parameter and/or a processing parameter for the pressure transducer 110 on the basis of the calibration information item ICAL.
According to a ninth aspect with reference to the eighth aspect, the processing device 170 can be embodied to bring about a modified actuation of the pressure transducer 110 on the basis of the modified operational parameters of the pressure transducer 110.
According to a tenth aspect with reference to the eighth aspect, the processing device 170 can be embodied to bring about modified conditioning or processing of the pressure single SP on the basis of the modified processing parameter of the pressure transducer 110.
According to an eleventh aspect with reference to the sixth aspect, the current functional parameter can be a fluid permeability of one or more equalization openings of the pressure transducer 110.
According to a twelfth aspect with reference to the eleventh aspect, the processing device 170 can be further embodied to ascertain a lower limit frequency fC of the signal curve SΔP, wherein a reduction in the lower limit frequency indicates a reduced fluid permeability of one or more equalization openings of the pressure transducer 110.
According to a thirteenth aspect with reference to the sixth aspect, the current functional parameter can be based on a mechanical membrane flexibility of a membrane of the pressure transducer 110.
According to a fourteenth aspect with reference to the thirteenth aspect, the processing device 170 can be further embodied to ascertain a maximum signal amplitude of the signal curve SΔP, wherein a change in the maximum signal amplitude of the signal curve SΔP indicates a change in the mechanical membrane flexibility of the membrane of the pressure transducer 110.
According to a fifteenth aspect with reference to the thirteenth aspect, the processing device 170 can be further embodied to ascertain a maximum signal amplitude of the signal curve SΔP, wherein a deviation of the maximum signal amplitude of the signal curve SΔP from a setpoint value indicates a deviation of the mechanical membrane flexibility of the membrane of the pressure transducer from the setpoint value.
According to a sixteenth aspect with reference to the thirteenth aspect, the processing device 170 can be embodied to provide a value for a modified, electrical bias of the membrane of the pressure transducer as the calibration information item ICAL in order to obtain, at least approximately, the setpoint value for the mechanical membrane flexibility of the pressure transducer 110 on the basis of the modified, electrical bias.
According to a seventeenth aspect with reference to the sixth aspect, the sensor arrangement 100 can have a plurality of pressure transducers 110, wherein the current functional parameter is a phase information item of the respective signal curve SΔP of the pressure signal SP in the plurality of pressure transducers 110.
According to an eighteenth aspect with reference to the seventeenth aspect, the current functional parameter can be a phase alignment of the signal curve SΔP of the pressure signal in the plurality of pressure transducers.
According to a nineteenth aspect with reference to the seventeenth aspect, the processing device 170 can be further embodied to ascertain a phase alignment of the signal curve SΔP of the respective pressure signal of the plurality of pressure transducers 110, wherein a different phase alignment of the signal curve SΔP of the respective pressure signal SP indicates an incorrect installation of the pressure transducter 110, for example.
According to a twentieth aspect with reference to the nineteenth aspect, the processing device 170 can be further embodied to provide a value for an inversion of the pressure signal SP of the pressure transducers 110 in which an inverted phase alignment of the signal curve SΔP of the respective pressure signal SP is present, as the calibration information item ICAL.
According to a twenty-first aspect with reference to the seventeenth aspect, the sensor arrangement can have a plurality of pressure transducers that are arranged in a pressure transducer array, wherein the processing device 170 is further embodied to ascertain a phase offset of the signal curves SΔP of the pressure signals SP from a plurality of different pressure transducers 110, 110-1 of the pressure transducer array.
According to a twenty-second aspect with reference to the twenty-first aspect, the processing device 170 can be further embodied to provide a phase adaptation of one or more pressure signals SP of the pressure transducers in the pressure transducer array as a calibration information item ICAL.
According to a twenty-third aspect with reference to the sixth aspect, the current functional parameter can be an ambient condition.
According to a twenty-fourth aspect with reference to the twenty-third aspect, the ambient condition can be an ambient temperature, an ambient air pressure, an ambient humidity and/or an ambient gas component in the ambient atmosphere.
According to a twenty-fifth aspect with reference to the twenty-third aspect, the processing device 170 can be further embodied to ascertain the calibration information item ICAL on the basis of a comparison between a first signal curve of the pressure signal in the case of a heating of the fluid F in the volume region 130 and a second signal curve of the pressure signal in the case of a cooling of the fluid F in the volume region.
According to a twenty-sixth aspect with reference to the twenty-fifth aspect, the processing device 170 can be further embodied to ascertain the calibration information item ICAL on the basis of a symmetry consideration between the first and the second signal curve of the pressure signal.
According to a twenty-seventh aspect with reference to the first aspect, the sensor arrangement 100 can be a photoacoustic sensor arrangement.
According to a twenty-eighth aspect with reference to the first aspect, the sensor arrangement 100 can be a pressure sensor arrangement with an MEMS pressure sensor.
According to a twenty-ninth aspect, a method 200 for testing a sensor arrangement 100 can include the following steps: producing 210 a defined temperature change ΔT of a fluid F situated in a volume region 130, wherein the temperature change ΔT of the fluid F brings about a pressure change ΔP in the volume region 130, capturing 220 the pressure change ΔP in the volume region 130 by a pressure transducer 110 in fluid connection with the volume region 130 having the fluid F, outputting 230 a pressure signal with a signal curve SΔP depending on the pressure change ΔP in response to the pressure change ΔP in the volume region 130, and ascertaining 240 a current functional parameter FIST of the pressure transducer 110 on the basis of the signal curve SΔP of the pressure signal SP, which is obtained during the temperature change ΔT in the volume region 130.
According to a thirtieth aspect with reference to the twenty-ninth aspect, the pressure change ΔP in the volume region 130 can be captured in relation to a reference pressure PREF in a reference volume region 190 in the step 220 of capturing the pressure change ΔP in order to output the pressure signal SP with the signal curve SΔP depending on the pressure change ΔP.
According to a thirty-first aspect with reference to the twenty-ninth aspect, the step of producing 210 a defined temperature change ΔT further can include the following step: activating 220A a heating element 150 in order to bring about a defined temperature increase AT of the fluid F situated in the volume region 130, and/or deactivating 220B the heating element 150 following an activated state of same in order to bring about a temperature reduction of the fluid F situated in the volume region 130.
According to a thirty-second aspect with reference to the twenty-ninth aspect, the ascertaining step 240 further can include the following steps: ascertaining a calibration information item ICAL for the pressure transducer 110 on the basis of the current functional parameter FIST of the pressure transducer 110 by comparing the current functional parameter FIST to a setpoint functional parameter FSOLL of the pressure transducer 110 in order to obtain a comparison result and by determining the calibration information item ICAL for the pressure transducer 110 on the basis of the comparison result.
According to a thirty-third aspect with reference to the twenty-ninth aspect, the method 200 further can include the following step: changing 250 an operational parameter or processing parameter for the pressure transducer 110 on the basis of the calibration information item, wherein a modified operational parameter of the pressure transducer 110 brings about a modified actuation of the pressure transducer 110 and wherein a modified processing parameter of the pressure transducer 110 brings about modified conditioning of the pressure transducer.
Although some aspects have been described in connection with an apparatus, it goes without saying that these aspects are also a description of the corresponding method, which means that a block or a structural element of an apparatus can also be understood as a corresponding method step or as a feature of a method step. Similarly, aspects which have been described in connection with or as a method step are also a description of a corresponding block or detail or feature of a corresponding apparatus. Some or all of the method steps can be executed by a hardware apparatus (or by using a hardware apparatus), such as a microprocessor, a programmable computer or an electronic circuit for example. In some exemplary embodiments, some or a plurality of the most important method steps can be executed by such an apparatus.
Depending on particular implementation requirements, exemplary embodiments of the invention may be implemented in hardware or in software or at least partly in hardware or at least partly in software. The implementation can be carried out by using a digital storage medium, for example a floppy disk, a DVD, a Blu-ray disk, a CD, a ROM, a PROM, an EPROM, an EEPROM or a FLASH memory, a hard disk or another magnetic or optical memory which stores electronically readable control signals which can interact, or interact, with a programmable computer system such that the respective method is carried out. Therefore, the digital storage medium may be computer-readable.
Some exemplary embodiments according to the invention thus comprises a data storage medium which has electronically readable control signals which are capable of interacting with a programmable computer system such that one of the methods described herein is carried out.
Generally, exemplary embodiments of the present invention may be implemented as a computer program product with a program code, the program code being operative so as to carry out one of the methods when the computer program product is executed on a computer.
By way of example, the program code may also be stored on a machine-readable storage medium.
Other exemplary embodiments comprise the computer program for carrying out one of the methods described herein, wherein the computer program is stored on a machine-readable storage medium. In other words, one exemplary embodiment of the method according to the invention is therefore a computer program which has a program code for carrying out one of the methods described herein when the computer program is executed on a computer.
A further exemplary embodiment of the methods according to the invention is therefore a data storage medium (or a digital storage medium or a computer-readable medium) on which the computer program for carrying out one of the methods described herein is recorded. The data storage medium or the digital storage medium or the computer-readable medium is typically tangible and/or nonvolatile.
A further exemplary embodiment of the method according to the invention is therefore a data stream or a sequence of signals which represent(s) the computer program for carrying out one of the methods described herein. The data stream or the sequence of signals may be configured, by way of example, to be transferred via a data communication link, for example via the Internet.
A further exemplary embodiment comprises a processing device, for example a computer or a programmable logic component, which is configured or customized to carry out one of the methods described herein.
A further exemplary embodiment comprises a computer on which the computer program for carrying out one of the methods described herein is installed.
A further exemplary embodiment according to the invention comprises an apparatus or a system which is designed to transmit a computer program for carrying out at least one of the methods described herein to a receiver. The transmission can take place electronically or optically, for example. The receiver may be a computer, a mobile device, a memory device or a similar apparatus, for example. The apparatus or the system may comprise a file server for transmitting the computer program to the receiver, for example.
In some exemplary embodiments, a programmable logic component (for example a field-programmable gate array, an FPGA) can be used to carry out some or all functionalities of the methods described herein. In some exemplary embodiments, a field-programmable gate array can interact with a microprocessor in order to carry out one of the methods described herein. Generally, the methods in some exemplary embodiments are carried out by an arbitrary hardware apparatus. This may be a universally useable piece of hardware such as a computer processor (CPU) or hardware which is specific to the method, such as an ASIC.
The exemplary embodiments described above are merely an illustration of the principles of the present invention. It goes without saying that modifications and variations of the arrangements and details described herein will be apparent to other persons skilled in the art. It is therefore intended that the invention be limited only by the scope of protection of the patent claims which follow and not by the specific details which have been presented herein by means of the description and the explanation of the exemplary embodiments.
Number | Date | Country | Kind |
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102017211970.5 | Jul 2017 | DE | national |