EP2728905A2 - Circuit assembly and method for testing a microphone and system for operating a microphone with such a circuit assembly - Google Patents

Abstract

The circuit arrangement (100) has a test signal generating section (120), through which the microphone (110) is supplied with test alternating voltage, and an evaluation section (130), which is supplied with a measurement signal, particularly after preamplification and a desired value signal and is formed for dispensing a result signal containing the information about a possible defect of the microphone, where the measurement signal is tapped from the microphone. Independent claims are included for the following: (1) a system with an audio signal replay device for operating a microphone; and (2) a method for testing a microphone, particularly a dynamic microphone.

Description

State of the art

The invention relates to a circuit arrangement and a method for testing a microphone. The invention further relates to a system for operating a microphone with such a circuit arrangement.

From the DE 36 36 720 A1 a method for functional testing of a microphone and a Mikrofonprüfeinrichtung are known. In this method, at least one speaker is arranged in a fixed assignment to the microphone and assigned a test signal whose signal frequency is within the working frequency range of the microphone. The phase difference between the microphone output signal and the test signal is measured and compared with a setpoint. If the phase difference is within a tolerance range of the setpoint, then the functionality of the microphone is affirmative, in the other case it is negated. The method is suitable for automating the testing process, which can be triggered and evaluated by a microphone remote location. With the known method, it should be possible, in particular in sound measuring systems in which a large number of microphones are used unmanned, such as sound systems for the location of sound events, at the same time the functionality of several individual microphones at different Before the sound measuring system is put into operation, it must also be checked during operation, so that the measurement result is not falsified by defective microphones. In this method, at least three substantially identical loudspeakers are preferably arranged at the same distance around the microphone and at the same distance from one another and are occupied by the test signal. By multiplying the loudspeakers, it is possible to compensate for errors caused by different wind directions in microphones installed outdoors.

Due to the fixed assignment of at least one, but preferably more loudspeakers to each microphone results for the known microphone testing a total of an unfavorable high circuit complexity.

Disclosure of the invention

The invention has the object to provide a circuit arrangement and a method for testing a microphone, which reduce the required circuit complexity. The invention also has the object of providing a system for operating a microphone with such a circuit arrangement in which such a method can be used.

This object is achieved by a circuit arrangement for testing a microphone, in particular a dynamic microphone, comprising at least a test signal generating stage, by which the microphone can be acted upon by a test AC voltage, and an evaluation stage, the one tapped by the microphone measurement signal, in particular after a pre-amplification, as well as a setpoint signal can be supplied and which is designed to output a information about a possible defect of the microphone containing result signal.

The invention enables a fast, simple and precise testing of the microphone with little circuit complexity. In particular, the expensive, voluminous and energy dissipating loudspeakers used in the above-cited prior art are replaced by a very compact, simply constructed circuit arrangement, which can also be combined by structural, in particular semiconductor integration, preferably with other modules connected to the microphone, that an additional space requirement practically no longer appears. The operation of the circuit arrangement according to the invention causes only a minimal power consumption. The use of a test AC voltage also allows a simple separation between the measurement signal and DC currents in the microphone and thus allows easy measurement without offset error.

According to a preferred embodiment of the circuit arrangement according to the invention, the evaluation stage for detecting an amplitude of the measurement signal, for forming therefrom an amplitude signal and for comparing the amplitude signal with the setpoint signal and for generating the result signal from this comparison is configured. As a result, a simple and offset-free formation of the amplitude signal is achieved. Such an embodiment of the evaluation stage can be used both for analog and for digital signal processing and signal evaluation.

According to another advantageous development, the circuit arrangement according to the invention is characterized in that the test signal generating stage is configured to apply the test AC voltage to the microphone via at least one series impedance. This is preferably at least one high-impedance series impedance. As a result, a current feed is effected in the microphone, so that tapped as a measurement signal directly caused by the test AC voltage AC voltage to microphone connections can be. In addition, a supply of the test alternating voltage that takes place in this way is short-circuit proof. Furthermore, different error cases of the microphone, which make themselves noticeable as idling at the microphone terminals, as a short circuit between the microphone terminals or as a short circuit between at least one of the microphone terminals and ground, can be precisely and uniquely detected by evaluating the measurement signal.

According to another development of the circuit arrangement according to the invention, the test signal generation stage is designed to generate an at least substantially rectangular test AC voltage. A rectangular test alternating voltage can be further processed both with analog and with digital signal processing and is furthermore simple and preferred by a device processor, by means of which the circuit arrangement according to the invention as well as further modules, with which the microphone can be coupled in a system for audio signal processing, can be controlled digitally generated.

According to a further preferred embodiment of the circuit arrangement according to the invention, the evaluation stage comprises a rectifier arrangement for rectifying the measurement signal, in particular the measurement signal after a preamplification. This allows a simple determination of the amplitude signal, in particular for analog processing of the measurement signal.

According to a further advantageous refinement of the circuit arrangement according to the invention, the evaluation stage comprises a comparison circuit for comparing the amplitude signal with the desired value signal and generating the result signal from this comparison, and the comparison circuit is designed to generate the result signal containing information about a possible defect of the microphone the amplitude signal is larger or smaller by a predefinable difference than the reference signal.

After this training, the amplitude signal is thus compared with a tolerance range for the setpoint signal. If the value of the amplitude signal falls within this tolerance range, a perfect function of the microphone is detected. On the other hand, if the value of the amplitude signal is outside, i. below or above this tolerance range, a faulty function or a defect of the microphone is detected. At a line break or contact break, which is idle, the amplitude signal assumes values above the tolerance range. In the event of a short circuit between the microphone terminals, the amplitude signal assumes values below the tolerance range of the setpoint signal.

According to another embodiment, the circuit arrangement according to the invention is advantageously characterized by a microphone preamplifier stage whose input is connected to the microphone and its output both to the evaluation stage and to an audio signal processing circuit and which is adapted to selectively amplify the measurement signal or one from the microphone delivered audio useful signal. Since such a microphone preamplifier stage is generally provided anyway in connection with an audio signal processing circuit, no additional circuit complexity is required for the amplification of the measurement signal.

In particular, for the operation of dynamic microphones, there is the additional advantage that such microphone preamplifier stages are preferably designed to be DC-coupled by the design of the microphone. This results in no additional circuit complexity for the acquisition of the measurement signal at the same time with a separation between DC or DC components on the microphone and the output from the microphone audio signal useful also a separation of Measuring signal from the DC or DC components and thus a suppression of possible offset error.

In an advantageous development, the evaluation stage is comprised by the audio signal processing circuit. This is preferably advantageous in the case of digital audio signal processing, because this means that already existing modules can be used twice and in this way circuit expenditure is saved.

The object mentioned at the outset is further achieved by a system for operating a microphone, in particular a dynamic microphone, comprising at least a microphone for outputting an audio useful signal, an audio signal processing circuit for processing the audio useful signal and an audio signal reproduction device, the system a circuit arrangement of the type described above for testing the microphone includes. The system may further comprise further subassemblies which serve to process or forward an audio payload signal processed in the audio signal processing circuit, e.g. a telephone unit for transmitting the recorded audio signal from the microphone in a telephone connection.

• Erzeugen einer Prüfwechselspannung, vorzugsweise einer rechteckförmigen Prüfwechselspannung,
• Beaufschlagen des Mikrofons mit der Prüfwechselspannung, vorzugsweise der rechteckförmigen Prüfwechselspannung,
• Abgreifen eines Messsignals vom Mikrofon,
• Zuführen des Messsignals, insbesondere nach einer Vorverstärkung, an die Auswertestufe,
• Zuführen eines Sollwertsignals an die Auswertestufe,
• Vergleichen des Messsignals mit dem Sollwertsignal, und
• Bilden und Abgeben des eine Information über einen möglichen Defekt des Mikrofons enthaltenden Ergebnissignals.

The above-mentioned object is also achieved by a method for testing a microphone, in particular a dynamic microphone, for implementation with a circuit arrangement and / or in a system of the type described above, the method comprising the following method steps:

• Generating a test alternating voltage, preferably a rectangular test alternating voltage,
• Subjecting the microphone to the test alternating voltage, preferably the rectangular test alternating voltage,
• Picking up a measurement signal from the microphone,
• Supplying the measurement signal, in particular after preamplification, to the evaluation stage,
• Supplying a setpoint signal to the evaluation stage,
• Compare the measurement signal with the setpoint signal, and
• Forming and outputting the information signal containing a possible defect of the microphone.

For a simple and reliable testing of the microphone is possible, which is also easy to automate.

• Figur 1 ein erstes Ausführungsbeispiel einer erfindungsgemäßen Schaltungsanordnung, eingesetzt in einem Ausführungsbeispiel für ein erfindungsgemäßes System,
• Figur 2 einen Ausschnitt des Schaltbildes gemäß Figur 1 und
• Figur 3 ein zweites Ausführungsbeispiel einer erfindungsgemäßen Schaltungsordnung, eingesetzt in einem zweiten Ausführungsbeispiel des erfindungsgemäßen Systems.

Embodiments of the invention are illustrated in the drawings and will be described in more detail below. Show it

• FIG. 1 A first embodiment of a circuit arrangement according to the invention, used in an exemplary embodiment of a system according to the invention,
• FIG. 2 a section of the circuit diagram according to FIG. 1 and
• FIG. 3 A second embodiment of a circuit arrangement according to the invention, used in a second embodiment of the system according to the invention.

In the figures matching elements are provided with the same reference numerals.

In FIG. 1 comprises a circuit arrangement 100 for testing a microphone 110, in particular a dynamic microphone, a test signal generating stage 120, by which the microphone 110 with a test AC voltage, preferably in the low frequency range, can be acted upon. Furthermore, the circuit arrangement 100 comprises an evaluation stage 130 which transmits a measurement signal, which can be picked up by the microphone 110, via a measurement signal input 131 and a setpoint signal via a setpoint signal input 132 can be fed. The evaluation stage 130 is configured to output a result signal containing information about a possible defect of the microphone 110 on a result signal output 133. The above elements are part of a system for operating the microphone 110 which, in addition to the microphone 110 for outputting an audio useful signal, also comprises an audio signal processing circuit 150 for processing the audio useful signal. Then, as in FIG. 3 In more detail, an audio signal playback device 160 or further modules may be included, which serve to process or forward a audio signal processed in the audio signal processing circuit 150, eg a telephone unit 170 for transmitting the audio signal picked up by the microphone 110 into a telephone connection. This in FIG. 1 The system shown also comprises a microphone preamplifier stage 180, whose input formed by two input terminals 181, 182 is connected to the microphone 110 and its output 183 to both the evaluation stage 130 and the audio signal processing circuit 150 and which is adapted to selectively amplify the measurement signal or an output from the microphone 110 audio useful signal.

The test signal generation stage 120 includes a signal source 121 which outputs a rectangular control voltage. The signal source 121 is connected to an input terminal 122 of a transistor network, which is designed as a switch. In this case serve a first transistor 123, in the embodiment according to FIG. 1 implemented as a PNP transistor, and a second transistor 124, designed as an NPN transistor, as switches, which are connected in series with a first and a second series impedance 125, 126 and the microphone 110 between a supply voltage terminal 127 and ground 128. A third transistor 129, implemented as an NPN transistor, forms a voltage inverter for inverting the first transistor 123 at its base terminal from the input terminal 122 to be supplied control voltage. The base terminals of the three transistors 123, 124 and 129 are connected to resistor voltage dividers for operating point adjustment.

By virtue of the rectangular control voltage supplied by the signal source 121, the first and second transistors 123, 124 are alternately both conducting or non-conducting. As a result, the microphone 110 is acted upon at its terminals by a test alternating voltage varying with the rectangular control voltage.

FIG. 2 shows as a section of FIG. 1 in a simplified representation, the series connection of the two series impedances 125, 126 and the microphone 110 between the supply voltage terminal 127 and ground 128. The transistors 123, 124 are assumed to be in the conductive state befindlicher and therefore not shown. At the series connection is then in FIG. 2 with UP designated test voltage, which is preferably a test AC voltage. The current caused by it through the series connection generates between the terminals of the microphone 110 a tapped from these terminals measurement signal UM. The resistance values of the series impedances 125, 126 are high relative to the internal resistance of the microphone 110. Thus, the microphone 110 can be impressed with a defined test current, which is preferably a test alternating current, even with a low current intensity to the extent that the type of microphone 110 has such a current intensity allows.

The terminals of the microphone 110 are connected to the input terminals 181 and 182 of the microphone preamplifier stage 180, respectively. The input terminals 181, 182 are each connected via a coupling capacitor 184, 185 and an input resistor 186, 187 to inputs of an operational amplifier 188, which is connected to two RC elements 189, 190 and whose output terminal is the output terminal 183 of the microphone preamplifier stage 180 forms. Through the coupling capacitors 184, 185, DC components superimposed on the measurement signal are kept away from the operational amplifier 188, so that only the rectangular measurement signal is amplified there and supplied to the evaluation stage 130 via the measurement signal input 131 connected to the output terminal 183.

The evaluation stage 130 also contains on the input side a coupling capacitor 134 for disconnecting DC components at the output terminal 183. Via the coupling capacitor 134, the measuring signal input 131 is connected via a series resistor 135 to a peak rectifier 136 formed in the present embodiment from two diodes. The peak rectifier 136 supplies the amplitude signal via a smoothing stage 137 to an amplitude signal output 138 of the evaluation stage 130. Coupling capacitor 134, series resistor 135, peak rectifier 136 and smoothing stage 137 together form a rectifier arrangement.

The evaluation stage 130 further comprises a comparison circuit 140 for comparing the amplitude signal from the amplitude signal output 138 with the setpoint signal, which can be supplied via the setpoint signal input 132. The result signal obtained from this comparison is output via the result signal output 133. The result signal provides information about a possible defect of the microphone 110 when the amplitude signal is larger or smaller by a predetermined difference than the reference signal, i. leaves a tolerance range around the setpoint signal.

The output terminal 183 of the microphone preamplifier stage 180 is further connected to the input of the audio signal processing circuit 150. In regular operation of the system according to FIG. 1 The audio useful signal is supplied from the microphone 110 via the microphone preamplifier stage 180 of the audio signal processing circuit 150 and from this to Playback, recording or the like via an output terminal 151 delivered.

FIG. 3 shows a modification of the system of FIG. 1 especially for use in digital audio signal processing. However, the test signal generation stage 120 and the microphone preamplifier stage 180 are unchanged. In contrast, in this system, a digital audio signal processing circuit 250 is applied, which is fed via the output terminal 183 of the microphone preamplifier stage 180, both the audio useful signal in regular operation and the measurement signal during the testing of the microphone 110. The audio signal processing circuit 250 comprises means for determining the amplitude signal, comparing with a setpoint signal and forming a result signal. The audio signal processing circuit 250 also has two output terminals 251, 252, via which the above-mentioned audio signal playback device 160 and the telephone unit 170 corresponding audio payload signals are fed.

The system according to FIG. 3 is controlled by a control circuit 210, which is formed for example by a device processor. On the one hand, this supplies the rectangular control voltage to the input terminal 122 and, on the other hand, controls the audio signal processing circuit 250 via a control line 211.

In the above-described system according to FIG. 3 For example, the audio signal processing circuit 250 as shown in FIG FIG. 1 again be connected to the result signal output via which the result signal is output. In FIG. 3 However, a variant is shown, according to which the result signal output 133 is connected to the control circuit 210. The result signal is passed here by the audio signal processing circuit 250 via the control line 211 to the control circuit 210 and delivered only from this.

The circuit arrangement according to the invention can preferably be used for testing dynamic microphones, since a DC-decoupled AC amplifier is provided as a microphone preamplifier stage for them in principle. In the case of the circuit arrangement according to the invention, this amplifier serves to amplify the measurement signal during the test procedure. Due to the DC decoupling, the circuit arrangement is robust against offset errors and very accurate in the gain of the measured variable. The supply of the very small test alternating current in the microphone is high-impedance and is therefore robust against short circuits against the supply voltage and ground. The additional circuit complexity for the test is low because already existing circuit parts are used.

In normal operation, the audio useful signal of the microphone in the microphone preamplifier stage is potential-free and symmetrically amplified. In the audio signal processing circuit, the amplified audio payload signal for reproduction, e.g. for a hands-free telephone or passenger announcement in a vehicle, processed and the audio signal playback device, e.g. formed by vehicle speakers, or supplied to a telephone unit. The test signal generation stage and the evaluation stage have no influence on the signal processing of the audio user signal.

By varying the pulse to pause ratio of the test AC voltage, i. the rectangular control voltage at the input terminal 122 of the transistor network in the test signal generation stage, 120, the nominal impedance range of the circuit arrangement for testing the microphone can be varied. This makes it possible to carry out a flexible measurement or test over a wide impedance range of the microphone to be tested.

Claims (10)

Circuit arrangement (100) for testing a microphone (110), in particular a dynamic microphone, at least comprising a test signal generating stage (120), by which the microphone (110) can be acted upon by a test alternating voltage (UP), and an evaluation stage (130), in that a measurement signal (UM) which can be tapped off from the microphone (110) can be supplied, in particular after a preamplification, and a setpoint signal and which is designed to output a result signal containing information about a possible defect of the microphone (110). Circuit arrangement (100) according to claim 1, characterized in that the evaluation stage (130) for detecting an amplitude of the measurement signal (UM), for forming therefrom an amplitude signal and for comparing the amplitude signal with the setpoint signal and for generating the result signal from this comparison is configured , Circuit arrangement (100) according to claim 1 or 2, characterized in that the test signal generating stage (120) is designed to load the microphone (110) with the test alternating voltage (UP) via at least one series impedance (125, 126). Circuit arrangement (100) according to one or more of the preceding claims, characterized in that the test signal generating stage (120) is designed to generate an at least substantially rectangular test alternating voltage (UP). Circuit arrangement (100) according to one or more of the preceding claims, characterized in that the evaluation stage (130) comprises a rectifier arrangement (136) for rectifying the measurement signal (UM), in particular of the measurement signal after preamplification. Circuit arrangement (100) according to one or more of the preceding claims, characterized in that the evaluation stage (130) comprises a comparison circuit (140) for comparing the amplitude signal with the desired value signal and generating the result signal from this comparison, and in that the comparison circuit (140) is designed to generate the information signal containing a possible defect of the microphone (110) when the amplitude signal by a predetermined difference is greater or less than the setpoint signal. Circuit arrangement (100) according to one or more of the preceding claims, characterized by a microphone preamplifier stage (180), whose input (181, 182) to the microphone (110) and the output (183) both with the evaluation stage (130) and is connected to an audio signal processing circuit (150) and which is adapted to selectively amplify the measurement signal (UM) or an output from the microphone (110) audio useful signal. Circuit arrangement (200) according to claim 7, characterized in that the evaluation stage of the audio signal processing circuit (250) is included. A system (100, 110, 150, 160, 200, 250) for operating a microphone (110), in particular a dynamic microphone, at least comprising a microphone (110) for outputting an audio useful signal, a An audio signal processing circuit (150; 250) for processing the audio payload signal and an audio signal reproducing device (160), characterized by a circuit arrangement (100; 200) according to any one of claims 1 to 8. Method for testing a microphone (110), in particular a dynamic microphone, for implementation with a circuit arrangement (100; 200) according to one or more of Claims 1 to 8 and / or in a system (100, 110, 150, 160, 200, 250) according to claim 9, characterized by the method steps: Generating a test alternating voltage (UP), preferably a rectangular test alternating voltage (UP), Subjecting the microphone (110) to the test alternating voltage (UP), preferably the rectangular test alternating voltage (UP), Picking up a measuring signal (UM) from the microphone (110), Supplying the measurement signal (UM), in particular after preamplification, to the evaluation stage (130), Supplying a setpoint signal to the evaluation stage (130), • Compare the measuring signal (UM) with the setpoint signal, and Forming and outputting the result signal containing information about a possible defect of the microphone (110).

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