Abstract:
A method and a device for operating a voice-enhancement system, such as a communication and/or intercom/two-way intercom or duplex telephony device in a motor vehicle, having at least one microphone and at least one loudspeaker for reproducing a signal generated by the microphone, as well as a bandpass filter configured between the microphone and the loudspeaker, the bandpass filter being adjusted as a function of a comparison between the power of the signal generated by the microphone at a test frequency, and the power of the signal generated by the microphone at an at least substantially integral multiple of the test frequency, or as a function of a comparison between the power of the signal generated by the microphone at a test frequency, and the power of the signal generated by the microphone at the test frequency at at least an earlier point in time.

Description:
FIELD OF THE INVENTION  
         [0001]    The present invention relates to a method and to a device for operating voice-enhancement systems, such as communication and/or intercom/two-way intercom or duplex telephony devices in motor vehicles, in which voice signals are picked up via a microphone system and routed to at least one loudspeaker.  
         BACKGROUND INFORMATION  
         [0002]    Methods of, this kind are used in motor vehicles for voice-enhancement duplex telephony or for supporting voice input-controlled electronic or electrical components. The fundamental difficulty that arises is that, depending on the particular operating state, background noise is present in a motor vehicle. It masks the voice commands. Intercom and two-way intercom or duplex telephony systems in motor vehicles are mainly used in large vehicles, minibuses, etc. However, they may also be used in normal passenger cars. When using voice-controlled input units for electrical components in motor vehicles, it is may be important for the background noise to be suppressed or for the voice command to be filtered out.  
           [0003]    A voice-recognition device for a motor vehicle is described in European Published Patent Application No. 0 078 014, in which the status of engine operation and/or motor vehicle movement is signaled or fed in, via sensors, to the amplifier system of the voice-recognition device. Based on this, a noise-level control is used to attempt to filter out the voice command from the background noise.  
           [0004]    A filtering operation is described in International Published Patent Application No. WO 97/34290, where periodic interfering noise signals are filtered out by determining their periods and by using a generator to interfere with them, so that the voice signal remains.  
           [0005]    In German Published Patent Application No. 197 05 471, it is described to support a voice recognition with the aid of transversal filtering.  
           [0006]    In German Published Patent Application No. 41 06 405, a method is described for subtracting noise from the voice signal, a multiplicity of microphones being used. A duplex telephony device having a plurality of microphones is described in German Published Patent Application No. 199 58 836.  
           [0007]    In German Published Patent Application No. 39 25 589, it is described to use a multiple microphone system, in which, in motor vehicle applications, one of the microphones is placed in the engine compartment and one other microphone in the passenger compartment. A subtraction of both signals then follows. A disadvantage in this context is that only the engine noise or the actual running noise of the vehicle itself is subtracted from the total signal in the passenger compartment. Specific secondary noises are disregarded in this case. Also lacking is a feedback suppression. Everywhere that microphones and loudspeakers are placed in acoustically coupleable vicinity, the acoustic signal that is extracted, coupled out or decoupled at the loudspeaker is fed back, in turn, into the microphone. The result is a so-called feedback, and a subsequent overmodulation. Methods for avoiding such an overmodulation are described in European Published Patent Application No. 1 077 013, International Published Patent Application No. WO 02/069487 and International Published Patent Application No. WO 02/21817.  
           [0008]    It is an object of the present invention to provide a method and a device that may improve the verbal communication among the occupants of a vehicle.  
         SUMMARY  
         [0009]    The above and other beneficial objects of the present invention may be achieved by providing a method and a device as described herein.  
           [0010]    In this context, to operate a voice-enhancement system, such as a communication and/or intercom/two-way intercom or duplex telephony device in a motor vehicle, using at least one microphone and at least one loudspeaker to reproduce a signal generated by the microphone, as well as a bandpass filter configured between the microphone and the loudspeaker, the bandpass filter is adjusted as a function of a comparison between the power of the signal generated by the microphone at a test frequency, and the power of the signal generated by the microphone at an at least substantially integral multiple, thus at essentially a harmonic of the test frequency, or as a function of a comparison between the power of the signal generated by the microphone at a test frequency, and the power of the signal generated by the microphone at a test frequency at at least an earlier point in time. One or more frequencies of the signal generated by the microphone may be suitable as a test frequency. In an example embodiment of the present invention, the frequency at which the power of the signal generated by the microphone is mainly at its maximum, is selected as a test frequency. Alternatively, a plurality of frequency components having substantial power are selected as test frequencies.  
           [0011]    In another example embodiment of the present invention, the bandpass filter is adjusted both as a function of a comparison between the power of the signal generated by the microphone at the test frequency, and the power of the signal generated by the microphone at an at least substantially integral multiple of the test frequency, as well as as a function of a comparison between the power of the signal generated by the microphone at the test frequency, and the power of the signal generated by the microphone at the test frequency at at least an earlier point in time.  
           [0012]    In another example embodiment of the present invention, the bandpass filter is set to block the component of the signal generated by the microphone, using a stop frequency, (only) when the power of the signal generated by the microphone at the test frequency is greater by more than an upper limiting value than the power of the signal generated by the microphone at the first harmonic of the test frequency. Stop frequency in the context of the present invention may also be a frequency range and not just a single frequency.  
           [0013]    In another example embodiment of the present invention, the upper limiting value is between 20 and 40 dB. The upper limiting value may amount to, e.g., approximately 30 dB.  
           [0014]    In yet another example embodiment of the present invention, the bandpass filter is set so as not to block the component of the signal generated by the microphone, using the stop frequency, when the power of the signal generated by the microphone at the test frequency is greater by less than a lower limiting value than the power of the signal generated by the microphone at the first harmonic of the test frequency.  
           [0015]    In another example embodiment of the present invention, the lower limiting value may be between 5 and 20 dB. The lower limiting value may amount to, e.g., approximately 12 dB.  
           [0016]    In another example embodiment of the present invention, by comparing the power of the signal generated by the microphone at the test frequency with the power of the signal generated by the microphone at the test frequency at at least earlier points in time, it may be decided whether the power of the signal generated by the microphone at the test frequency is increasing exponentially.  
           [0017]    In yet another example embodiment of the present invention, the bandpass filter is set to block the component of the signal generated by the microphone, at the stop frequency, when the decision is made that the power of the signal generated by the microphone at the test frequency is increasing exponentially.  
           [0018]    In another example embodiment of the present invention, the bandpass filter is set to block the component of the signal generated by the microphone, using a stop frequency, (only) when the power of the signal generated by the microphone at the test frequency is greater than a response threshold for longer than a first response time, the first response time, e.g., being greater than, e.g., approximately 750 ms.  
           [0019]    In yet another example embodiment of the present invention, the power is determined at more than one test frequency, and the bandpass filter is set to block the component of the signal generated by the microphone, using the stop frequency, only when the power of the signal generated by the microphone at a test frequency is greater than the power of the signal generated by the microphone for longer than a second response time, at every other test frequency, the second response time advantageously being greater than, e.g., approximately 750 ms.  
           [0020]    In another example embodiment of the present invention, the adjustment or setting of the bandpass filter with respect to the test frequency is repeated, at the earliest, following a minimum response or dead time. The minimum response time may be, e.g., 200 ms to 300 ms.  
           [0021]    In yet another example embodiment of the present invention, the bandpass filter is set to block the component of the signal generated by the microphone at a frequency range around the stop frequency when, following a repetition time, which is greater than the minimum response time, the power of the signal generated by the microphone at the test frequency is greater by more than an upper limiting value than the power of the signal generated by the microphone at the essentially first harmonic of the test frequency, and/or when the decision is made that the power of the signal generated by the microphone at the test frequency is increasing exponentially.  
           [0022]    In yet another example embodiment of the present invention, the bandpass filter is set to block the component of the signal generated by the microphone at an expanded frequency range around the test frequency when, following a repetition time, which is greater than the minimum response time, the power of the signal generated by the microphone at the test frequency is greater by more than an upper limiting value than the power of the signal generated by the microphone at the essentially first harmonic of the test frequency, and/or when the decision is made that the power of the signal generated by the microphone at the test frequency is increasing exponentially.  
           [0023]    In addition to the foregoing, to operate a voice-enhancement system, such as a communication and/or intercom/two-way intercom or duplex telephony device in a motor vehicle, using at least one microphone and at least one loudspeaker to reproduce a signal generated by the microphone, as well as a bandpass filter configured between the microphone and the loudspeaker, the power of the signal generated by the microphone is defined at at least three test frequencies, it being ascertained by evaluating the power of the signal generated by the microphone, at the test frequencies, whether feedback exists, and the bandpass filter being set to block a component of the signal generated by the microphone that exists around a stop frequency, when it is established that feedback exists.  
           [0024]    Stop frequency in the context of the present invention may be the test frequency at which the power of the signal generated by the microphone is at its maximum. In an example embodiment of the present invention, however, the stop frequency is the test frequency, to which a correction frequency is added and at which the power of the signal generated by the microphone is at its maximum; i.e., a correction frequency is added to the test frequency at which the power of the signal generated by the microphone is at its maximum. This correction frequency may be formed as a function of the power of the signal generated by the microphone at the test frequency at which the power of the signal generated by the microphone is at its maximum, as well as a function of the power of the signal generated by the microphone at at least one test frequency existing, e.g., directly, next to this test frequency.  
           [0025]    Thus, the correction frequency may be generated in accordance with:  
             fkorr=sign*fdist*Pmaxneigh/ ( Pmax+Pmaxneigh ), in  
           [0026]    which:  
           [0027]    fkorr represents the correction frequency;  
           [0028]    fdist represents the spacing between the test frequency at which the power of the signal generated by the microphone is at its maximum, and a test frequency having the greatest power, directly next to the test frequency at which the power of the signal generated by the microphone is at its maximum;  
           [0029]    Pmax represents the power of the signal generated by the microphone at the test frequency at which the power of the signal generated by the microphone is at its maximum, (thus Pmax is the power at the test frequency which is greater than the power of every other test frequency);  
           [0030]    Pmaxneigh represents the power of the signal generated by the microphone at which the test frequency having the greatest power, directly next to the test frequency at which the power of the signal generated by the microphone is at its maximum; and  
           [0031]    sign represents an algebraic sign;  
           [0032]    sign being positive when the test frequency having the greatest power, directly next to the test frequency at which the power of the signal generated by the microphone is at its maximum, is greater than the test frequency at which the power of the signal generated by the microphone is at its maximum, sign otherwise being negative.  
           [0033]    This is further described on the basis of the following example:  
           [0034]    192 test frequencies f 1 , f 2 , . . . f 192  are assumed. f 1  is equal to 40 Hz. fdist is 40 Hz for all test frequencies. In addition, for the powers of the signal generated by the microphone, it holds for the test frequencies f 1 , f 2 , . . . f 192 :  
             P ( f   1   , f   2   , . . . f   94 )=1  
             P ( f   95 )=4  
             P ( f   96 )=16  
             P ( f   97 )=2  
             P ( f   98   , f   99   , . . . f   192 )=1  
           [0035]    It then holds that:  
             fkorr= (−)*40 Hz*4(16+2)=−8 Hz  
           [0036]    The test frequency at which the power of the signal generated by the microphone is at its maximum is, thus, 3840 Hz, and the stop frequency is 3832 Hz.  
           [0037]    It may be provided that, at least in certain example embodiments, to generate the correction frequency in accordance with:  
             fkorr=Δf* ( Pneigh right− Pneigh left)/( Pmax+|Pneigh right− Pneigh left|), wherein:  
           [0038]    fkorr represents the correction frequency;  
           [0039]    Δf represents the spacing between two test frequencies;  
           [0040]    Pmax represents the power of the signal generated by the microphone at the test frequency at which the power of the signal generated by the microphone is at its maximum;  
           [0041]    Pneighright represents the power of the signal generated by the microphone at the test frequency directly above (thus to the “right” of) the test frequency at which the power of the signal generated by the microphone is at its maximum; and  
           [0042]    Pneighleft represents the power of the signal generated by the microphone at the test frequency directly below (thus to the “left” of) the test frequency at which the power of the signal generated by the microphone is at its maximum.  
           [0043]    Using the above numerical example as a basis, it holds, therefore, in this case that:  
             fkorr= 40 Hz*(2−4)/(16+|4−2|)=−4.44 Hz  
           [0044]    The test frequency at which the power of the signal generated by the microphone is at its maximum is, thus, 3840 Hz, and the stop frequency 3835.56 Hz.  
           [0045]    In another example embodiment of the present invention, the spacings between at least some of the test frequencies, or all of the test frequencies, are equidistant.  
           [0046]    In yet another example embodiment of the present invention, the existence of feedback may only be ascertained when the power of the signal generated by the microphone at the test frequency at which the power of the signal generated by the microphone is at a maximum, is greater by more than an upper limiting value than the power of the signal generated by the microphone at the first harmonic of this test frequency, the upper limiting value, e.g., being between 20 and 40 dB, for the most part, at, e.g., 30 dB.  
           [0047]    In yet another example embodiment of the present invention, the non-existence of feedback is ascertained when the power of the signal generated by the microphone at the test frequency at which the power of the signal generated by the microphone is at a maximum, is greater by less than a lower limiting value than the power of the signal generated by the microphone at the first harmonic of this test frequency, the lower limiting value, e.g., being between 5 and 20 dB, for the most part, at, e.g., 12 dB.  
           [0048]    In another example embodiment of the present invention, the existence of feedback is (only) ascertained when the power of the signal generated by the microphone at the test frequency at which the power of the signal generated by the microphone is at a maximum, is increasing, at least approximately, exponentially.  
           [0049]    In another example embodiment of the present invention, the existence of feedback is (only) ascertained when the power of the signal generated by the microphone is greater, at at least one test frequency, than a response threshold for longer than a first response time. The first response time may be greater than, e.g., approximately 750 ms. The response threshold may be selected as a function of the power of signal S, i.e., of the sum of the power of all test frequencies.  
           [0050]    In another example embodiment of the present invention, the existence of feedback is (only) ascertained when the power of the signal generated by the microphone is greater for longer than a first response time, at at least one test frequency, than the power of the signal generated by the microphone at every other test frequency. The second response time may be greater than, e.g., approximately 750 ms.  
           [0051]    In another example embodiment of the present invention, the adjustment or setting of the bandpass filter is repeated, at the earliest, following a minimum response or dead time, which may be, e.g., between 100 ms and 300 ms.  
           [0052]    In yet another example embodiment of the present invention, the power of the signal generated by the microphone is determined at at least 50, e.g., at 150 to 300 test frequencies.  
           [0053]    In another example embodiment of the present invention, the bandpass filter is a notch filter or a filter bank or multifilter having at least one notch filter. The filter bank may include 10 notch filters, for example.  
           [0054]    In accordance with an example embodiment of the present invention, a method for operating a voice-controlled system, such as a communication and/or an intercommunication device for a motor vehicle, including a microphone, a speaker connected to the microphone and a bandpass filter within a signal path between the microphone and the speaker, the bandpass filter including at least one adjustable parameter includes analyzing the frequency of a signal obtained by the microphone. The method also includes at least one of obtaining a comparison of the power at a certain frequency of the signal and the power of at least one harmonic of the certain frequency and obtaining a comparison of the power at a certain frequency of the signal and the power of the certain frequency at a later instant. The method further includes adjusting the at least one adjustable parameter dependent on the comparison.  
           [0055]    Further aspects and details are set forth below in the following description of exemplary embodiments. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0056]    [0056]FIG. 1 is a schematic view of a motor vehicle.  
         [0057]    [0057]FIG. 2 is a schematic view of an exemplary embodiment of a device according to the present invention.  
         [0058]    [0058]FIG. 3 is a schematic view of a notch filter.  
         [0059]    [0059]FIG. 4 is a schematic view of a filter bank.  
         [0060]    [0060]FIG. 5 illustrates an exemplary embodiment of a flow diagram implemented in a decision logic.  
         [0061]    [0061]FIG. 6 is a power-frequency diagram.  
         [0062]    [0062]FIG. 7 illustrates an exemplary embodiment of query  41  illustrated in FIG. 5.  
         [0063]    [0063]FIG. 8 is a power-frequency diagram.  
         [0064]    [0064]FIG. 9 is a power-frequency diagram.  
         [0065]    [0065]FIG. 10 illustrates another exemplary embodiment of query  41  illustrated in FIG. 5.  
         [0066]    [0066]FIG. 11 illustrates a further exemplary embodiment of a flow diagram implemented in a decision logic.  
         [0067]    [0067]FIG. 12 illustrates an exemplary embodiment of queries  41  and  82 .  
     
    
     DETAILED DESCRIPTION  
       [0068]    [0068]FIG. 1 is an inside view of a motor vehicle  1  from above. In this context, reference numerals  2  and  3  indicate the front seats, and reference numerals  4 ,  5  and  6  indicate the rear seats of the motor vehicle. Reference numerals  7 ,  8 ,  9 ,  10 ,  11 ,  12 ,  13 ,  14 ,  15 ,  16 ,  17 ,  18 ,  19  and  20  indicate loudspeakers. Reference numerals  21 ,  22 ,  23  and  24  indicate microphones. Loudspeakers  7 ,  8 ,  9 ,  10 ,  11 ,  12 ,  13 ,  14 ,  15 ,  16 ,  17 ,  18 ,  19  and  20  belong, in part, to a music system and, in part, to a communication and/or intercom/two-way intercom or duplex telephony device. They may also be used by both systems.  
         [0069]    In the present exemplary embodiment, loudspeakers  9 ,  17 ,  18 ,  19 ,  20  output a signal generated by microphone  21 . Loudspeakers  7 ,  17 ,  18 ,  19 ,  20  output a signal generated by microphone  22 . Loudspeakers  7 ,  9 ,  19 ,  20  output a signal generated by microphone  23 . Loudspeakers  7 ,  9 ,  17 ,  18  output a signal generated by microphone  24 . In this manner, the possibility of effective verbal communication in a motor vehicle may be enhanced. In principle, the more strongly a signal is amplified between one of microphones  21 ,  22 ,  23 ,  24  and one of loudspeakers  7 ,  9 ,  17 ,  18 ,  19 ,  20 , the more effective the communication is. However, the possibility of implementing such an amplification is limited by possible feedback effects caused by sound radiated by a loudspeaker  7 ,  9 ,  17 ,  18 ,  19 ,  20 , which is received by a microphone  21 ,  22 ,  23 ,  24 , and is subsequently amplified and radiated by loudspeaker  7 ,  9 ,  17 ,  18 ,  19 ,  20 .  
         [0070]    To reduce such a feedback, as illustrated in FIG. 2, a bandpass filter  32  is provided between a microphone  30 , which may be one of microphones  21 ,  22 ,  23 ,  24 , and a loudspeaker  31 , which may be one of loudspeakers  7 ,  9 ,  17 ,  18 ,  19 ,  20 . This filters a signal S generated by microphone  30  and supplies a filtered signal S′, which has certain frequency ranges filtered out, for which a decision logic  33  had recognized the danger of feedback. To this end, decision logic  33  determines filter parameters f c  and Q, which are used to adjust bandpass filter  32 .  
         [0071]    To amplify signal S and/or signal S′, amplifiers may be provided. However, the amplifier function may also be provided by the bandpass filter.  
         [0072]    [0072]FIG. 3 illustrates the characteristic curve of a bandpass filter arranged as a notch filter, amplification V of the bandpass filter being plotted over frequency f. In this context, f c  indicates the mid-frequency of the bandpass filter and Q indicates its quality. To filter a plurality of frequency ranges, bandpass filter  32  may be arranged as a filter bank, as illustrated in FIG. 4. The filter bank may include up to 10 notch filters.  
         [0073]    [0073]FIG. 5 illustrates an exemplary embodiment of a flow diagram implemented in a decision logic  33 . In this context, a test frequency is first defined in a step  40 . To this end, frequency f of signal S is analyzed, and, as illustrated exemplarily in FIG. 6, power P of signal S is determined at, e.g., 192, various test frequencies f n , f n+1 , f n+2 , f n+3 , f n+4 , f n+5 , f n+6 , f n+7 , f n+8 , which are spaced apart by, e.g., 40 Hz. For test frequency f n+5 , at which the power is at its maximum, the following sequence is executed. However, it is also possible for the following sequence to be executed for more than one test frequency.  
         [0074]    It may be provided to average the power over time at test frequencies f n , f n+1 , f n+2 , f n+3 , f n+4 , f n+5 , f n+6 , f n+7 , f n+8 , i.e. to form an average value over time, and to analyze this time average of the power instead of the current or active-power of signal S at test frequencies f n , f n+1 , f n+2 , f n+3 F n+4 , f n+5 , f n+6 , f n+7 , f n+8 . To the extent that the power of signal S is mentioned herein, it may also include the average value of the power formed over a certain time period. In addition, the concept of power in accordance with the present invention, may also include amplitude or its time average. Also to be included in accordance with the present invention are other variations of the power, of the amplitude, or of their time averages, such as normalized quantities, etc. Thus, for instance, in the context of the present invention, the power of signal S at a test frequency f n , may be understood as the value of the power of signal S at this test frequency f n , divided by the sum of the power of signal S at all test frequencies f n , f n+1 , f n+2 , f n+3 , f n+4 , f n+5 , f n+6 , f n+7 , f n+8 .  
         [0075]    Step  40  is followed by query  41 , which checks if there is a danger of feedback. Details pertaining to this query are explained with reference to FIGS. 7 and 10. If there is a danger of feedback, query  41  is followed by a query  42 , as to whether signal S generated by microphone  30  has already been reduced by the bandpass filter by signal components around the test frequency.  
         [0076]    If signal S generated by microphone  30  is not already reduced by the bandpass filter, by signal components around the test frequency, then query  42  is followed by a step  43 , in which the filter parameters, i.e., mid-frequency f c  and quality Q of the bandpass filter, are generated. Mid-frequency f c  is an example of the stop frequency along the lines of the claims. The stop frequency may also be, in particular, the frequency range around mid-frequency f c , which the bandpass filter actually filters out from signal S produced by microphone  30 .  
         [0077]    In the process, mid-frequency f c  may be equated with the test frequency. In an example embodiment of the present invention, however, mid-frequency f c  is the test frequency, to which a correction frequency is added and at which the power of the signal generated by the microphone is at its maximum; i.e., a correction frequency is added to the test frequency at which the power of the signal generated by the microphone is at its maximum. This correction frequency may be formed as a function of the power of the signal generated by the microphone at the test frequency at which the power of the signal generated by the microphone is at its maximum, as well as a function of the power of the signal generated by the microphone at at least one test frequency existing next to this test frequency. Thus, the correction frequency may be generated in accordance with:  
           fkorr =sign* fdist*Pmaxneigh/ ( Pmax+Pmaxneigh ), in  
         [0078]    which:  
         [0079]    fkorr represents the correction frequency;  
         [0080]    fdist represents the spacing between the test frequency at which the power of the signal generated by the microphone is at its maximum, and a test frequency having the greatest power, directly next to the test frequency at which the power of the signal generated by the microphone is at its maximum;  
         [0081]    Pmax represents the power of the signal generated by the microphone at the test frequency at which the power of the signal generated by the microphone is at its maximum;  
         [0082]    Pmaxneigh represents the power of the signal generated by the microphone at which the test frequency having the greatest power, directly next to the test frequency at which the power of the signal generated by the microphone is at its maximum; and  
         [0083]    sign represents an algebraic sign;  
         [0084]    sign being positive when the test frequency having the greatest power, directly next to the test frequency at which the power of the signal generated by the microphone is at its maximum, is greater than the test frequency at which the power of the signal generated by the microphone is at its maximum, sign otherwise being negative.  
         [0085]    In the present exemplary embodiment, the correction frequency is formed in accordance with:  
           fkorr=Δf* ( Pneigh right− Pneigh left)/( Pmax+|Pneigh right− Pneigh left|), in which:  
         [0086]    fkorr represents the correction frequency;  
         [0087]    Δf being the spacing between two test frequencies;  
         [0088]    Pmax represents the power of the signal generated by the microphone at the test frequency at which the power of the signal generated by the microphone is at its maximum;  
         [0089]    Pneighright represents the power of the signal generated by the microphone at the test frequency directly above the test frequency at which the power of the signal generated by the microphone is at its maximum; and  
         [0090]    Pneighleft represents the power of the signal generated by the microphone at the test frequency directly below the test frequency at which the power of the signal generated by the microphone is at its maximum.  
         [0091]    Quality Q is adjusted to a predefined value of, for example, {fraction (1/40)} Hz.  
         [0092]    Step  43  is followed by query  45 , as to whether the program is to be terminated. If the program is not to be terminated, then query  45  is followed by step  40 . Otherwise, the program is ended.  
         [0093]    If signal S generated by microphone  30  is already reduced by the bandpass filter, by signal components around the test frequency, then query  43  is followed by a step  44  in which quality Q is reduced. In this manner, the bandpass filter is adjusted so that it blocks the component of the signal generated by the microphone at an expanded frequency range around mid-frequency f c . Step  44  is followed by step  40 .  
         [0094]    Provided that there is no danger of feedback, query  41  is followed by query  45  or optionally by a step  46  in which the filtering of signal S generated by microphone  30 , around the test frequency, is ended.  
         [0095]    An example embodiment of the present invention provides for query  41  to be repeated, at the earliest following a minimum response or dead time, in the present exemplary embodiment, the minimum response time being, e.g., 200 ms to 300 ms.  
         [0096]    [0096]FIG. 7 illustrates an exemplary embodiment of query  41 . Next, a query  50  checks whether the power of signal S generated by microphone  30  at the test frequency is greater, by not less than a lower limiting value Δ1, than the power of signal S generated by microphone  30 , at the first harmonic (thus twice) the test frequency. Lower limiting value Δ1 is between 5 and 20 dB, for example. The lower limiting value Δ1 may amount for the most part to, e.g., 12 dB. This query is illustrated, by example, in FIG. 8, f H0  indicating the test frequency, f H1 , f H2 , f H3  and f H4  indicating the first, second, third, and fourth harmonic of the test frequency, and f H1/2  indicating the first subharmonic of the test frequency. P indicates the power at a frequency f. Query  50  thus checks whether:  
           P ( f   H0 )− P ( f   H1 )≧Δ1  
         [0097]    Provision may optionally be made, to supplement query  50  by one or more of the queries:  
           P ( f   H0 )− P ( f   H1/2 )≧Δ1  
           P ( f   H0 )− P ( f   H2 )≧Δ1  
           P ( f   H0 )− P ( f   H3 )≧Δ1  
           P ( f   H0 )− P ( f   H4 )≧Δ1  
         [0098]    it being possible, as the case may be, for other limiting values to be selected, as well.  
         [0099]    Test frequencies f n , f n+1 , f n+2 , f n+3 , f n+4 , f n+5 , f n+6 , f n+7 , f n+8  illustrated in FIG. 6 are to be distinguished from the subharmonics/harmonics f H1/2 , f H1 , f H2 , f H3  and f H4  illustrated in FIGS. 8 and 9, respectively. If, for instance, 192 test frequencies f 1 , f 2 , . . . f 192  are assumed, which are spaced apart by 40 Hz, f 1  being equal to 40 Hz, and if f 44 =f H0 , thus the test frequency at which the power of signal S generated by microphone  30  is at its maximum, then f H1 =f 88  and f H2 =f 122 .  
         [0100]    If the power of signal S generated by microphone  30  at the test frequency is greater, by not less than a lower limiting value Δ1, than the power of signal S generated by microphone  30  at the first harmonic of the test frequency, then query  50  is followed by a query  51 . Query  51  checks whether the power of signal S generated by microphone  30  at the test frequency is greater, by not less than an upper limiting value Δ2, than the power of signal S generated by microphone  30 , at the first harmonic of the test frequency. Upper limiting value Δ2 is between 20 and 40 dB, for example. Upper limiting value Δ2 may amount to, e.g., approximately 30 dB. This query is illustrated, by example, in FIG. 9, f H0  indicating test frequency, f H1 , f H2 , f H3  and f H4  indicating the first, second, third, and fourth harmonic of the test frequency, and f H1/2  indicating the first subharmonic of the test frequency. P indicates the power at a frequency f. Query  51  thus checks whether:  
           P ( f   H0 )− P ( f   H1 )≧Δ2  
         [0101]    Provision may optionally be made, to supplement query  51  by one or more of the queries:  
           P ( f   H0 )− P ( f   H1/2 )≧Δ2  
           P ( f   H0 )− P ( f   H2 )≧Δ2  
           P ( f   H0 )− P ( f   H3 )≧Δ2  
           P ( f   H0 )− P ( f   H4 )≧Δ2  
         [0102]    it being possible, as the case may be, for other limiting values to be selected, as well.  
         [0103]    If the power of signal S generated by microphone  30  at the test frequency is greater, by not more than an upper limiting value Δ2, than the power of signal Sqgenerated by microphone  30  at the first harmonic of the test frequency, then query  51  is followed by a query  52 , which, by comparing the power of signal S generated by microphone  30  at the test frequency, to the power of signal S generated by microphone  30  at the test frequency at at least an earlier point in time, checks whether the power of the signal generated by the microphone is increasing exponentially at the test frequency.  
         [0104]    [0104]FIG. 10 illustrates another exemplary embodiment of query  41 . Next, a query  60  checks whether the power of signal S generated by microphone  30  is greater at the test frequency than a predefined limiting value. In this case, a query  61  follows which corresponds to query  50 . Queries  62  and  63  correspond to queries  51  and  52 .  
         [0105]    [0105]FIG. 11 illustrates an exemplary embodiment of a flow diagram implemented in decision logic  33 . The functional sequence begins with a step  81 , which corresponds to step  40  illustrated in FIG. 5. Step  81  is followed by a query  82 , which corresponds to query  41  illustrated in FIG. 5 and which checks if there is a danger of feedback. FIGS. 7 and 10 illustrate exemplary embodiments of query  82 . In connection with the exemplary embodiment illustrated in FIG. 11, it may be provided to implement a feedback detection (query  82 ), as indicated in FIG. 12.  
         [0106]    Provided that there is no danger of feedback or that feedback is not ascertained, query  82  is followed by a query  83  corresponding to query  45  as to whether the program is to be terminated. If the program is not to be terminated, then query  93  is followed by step  81 . Otherwise, the program is ended.  
         [0107]    If there is a danger of feedback, query  82  is followed by a query  83  corresponding to  42 , as to whether signal S generated by microphone  30  has already been reduced by the bandpass filter by signal components around the test frequency. If signal S generated by microphone  30  is already reduced by the bandpass filter, by signal components around the test frequency, then query  83  is followed by a query  85 , or alternatively by a query  84 .  
         [0108]    Query  84  queries as to whether a notch filter is available. If a notch filter is available, query  84  is followed by a step  88 , which corresponds to step  43  and in which filter parameters, i.e., for the exemplary embodiment, mid-frequency f c  and quality Q of the bandpass filter, are produced. If, on the other hand, query  84  reveals that no notch filter is available, then query  84  is followed by a step  86  in which the power of signal S is reduced by a reduction factor, which may be between, e.g., 2 dB and 5 dB, for the most part, e.g., at 3 dB. Step  86  is followed by a step  87  in which the entire cycle is halted for a pause time of, e.g., approximately 3 s. However, this step may be executed only once per cycle.  
         [0109]    Query  85  checks whether a further expansion of the frequency range in which the bandpass filter is blocking, thus a further reduction in its quality Q, would provide that a predefined minimal quality may not be attained. If further expanding the frequency range provides that a predefined minimal quality may not be attained, then query  85  is followed by a step  89 , or alternatively by a step  91 . In step  91  which corresponds to step  44 , quality Q is reduced.  
         [0110]    Steps  87 ,  88  and  91  are followed by a step  92  in which the sequence is paused for a minimum response or dead time, the minimum response or dead time in the present exemplary embodiment being, e.g., 100 ms.  
         [0111]    In step  89 , the power of signal S is reduced by a reduction factor, which may be between, e.g., 2 dB and 5 dB, for the most part, e.g., at 3 dB. Step 89 is followed by a step  90  in which the entire cycle is halted for a pause time of, e.g., approximately 3 s.  
         [0112]    [0112]FIG. 7 illustrates an exemplary embodiment of query  82 , in accordance with which query  41  may also be implemented. In this context, a query  95  first checks whether the power of signal S generated by microphone  30  at the test frequency is greater, for longer than 750 ms, than the power of signal S generated by microphone  30 , at every other test frequency. If the power of signal S generated by microphone  30  at the test frequency is greater, for longer than 750 ms, than the power of signal S generated by microphone  30 , at every other test frequency, then query  95  is followed by a query  96 . Otherwise, query  95  is followed by query  93 .  
         [0113]    Query  96  checks whether the power of signal S generated by microphone  30  at the test frequency is greater, by not less than 12 dB, than the power of signal S generated by microphone  30 , at the first harmonic of (thus twice) the test frequency. If the power of signal S generated by microphone  30  at the test frequency is greater, by not less than 12 dB, than the power of signal S generated by microphone  30  at the first harmonic of the test frequency, then query  96  is followed by a query  97 . Otherwise, query  96  is followed by query  93 .  
         [0114]    A query  97  checks whether the power of signal S generated by microphone  30  is greater at the test frequency, for longer than 750 ms, than a response threshold. If the power of signal S generated by microphone  30  is greater at the test frequency, for longer than 750 ms, than a response threshold, then query  97  is followed by query  83 . Otherwise, query  95  is followed by query  93 .  
         [0115]    The feedback detection in accordance with the present invention is not limited to the example embodiments illustrated in FIGS. 7, 10, and  12 . Provision may be made, for example, for queries  52  and  63  to follow the “no” outputs of queries  50  and  61 , respectively. In addition, the binary decision logic of the example embodiments illustrated in FIGS. 7, 10, and  12  may be replaced with a fuzzy decision logic, thus fuzzy logic or neural networks.  
                                             LIST OF REFERENCE CHARACTERS                                    1   motor vehicle           2, 3   front seats           4, 5, 6   rear seats           7, 8, 9, 10, 11, 12,   loudspeakers           13, 14, 15, 16, 17,           18, 19, 20, 31           21, 22, 23, 24, 30   microphones           32   bandpass filter           33   decision logic           40, 41, 43, 44, 46, 81,   steps           84, 86, 87, 88, 89, 90           91, 92           41, 42, 45, 50, 51, 52,   queries           60, 61, 62, 63, 82, 83,           84, 85, 93, 95, 96, 97           f   frequency           f H0     test frequency           f H1     first harmonic of the test frequency           f H2     second harmonic of the test frequency           f H3     third harmonic of the test frequency           f H4     fourth harmonic of the test frequency           f H1/2     first subharmonic of the test               frequency           f n , f n+1 , f n+2 , f n+3 , f n+4 ,   frequency points           f n+5 , f n+6 , f n+7 , f n+8 , f 1 ,           f 2 , f 44 , f 88 , f 94 , f 95 ,           f 97 , f 98 , f 122 , f 192             fc   mid-frequency           fdist   the spacing between the test               frequency at which the power of the               signal generated by the microphone is               at its maximum, and a test frequency               having the greatest power, directly               next to the test frequency at which               the power of the signal generated by               the microphone is at its maximum           fkorr   correction frequency           Q   quality           P   power           Pmax   the power of the signal generated by               the microphone at the test frequency               at which the power of the signal               generated by the microphone is at its               maximum           Pmaxneigh   the power of the signal generated by               the microphone at which the test               frequency having the greatest power,               directly next to the test frequency               at which the power of the signal               generated by the microphone is at its               maximum           Pneighleft   the power of the signal generated by               the microphone at the test frequency               directly below the test frequency at               which the power of the signal               generated by the microphone is at its               maximum           Pneighright   the power of the signal generated by               the microphone at the test frequency               directly above the test frequency at               which the power of the signal               generated by the microphone is at its               maximum           S   signal           S′   filtered signal           sign   algebraic sign           V   amplification           Δ1   lower limiting value           Δ2   upper limiting value           Δf   spacing between two test frequencies