JPH05184000A - Automatic sound field corrector for audio system - Google Patents

Abstract

PURPOSE:To automatically correct the sound field characteristics by the normal reproduction of the music source without special test signals. CONSTITUTION:The signal level by bands of a speaker reproduction sound caught by a microphone 18 and an audio source signal to be outputted from audio equipment are detected by a first circuit 20 detecting signal levels by bands and a second circuit 80 detecting signal levels by bands. Based on the detected output, a microcomputer 150 finds the average detection level at the constant time during the same period at the microphone and at the audio source for each band. The relative reference between the microphone frequency characteristic curve and the audio source frequency characteristic curve is calculated based on the average detection level by bands at the microphone and at the audio source. The sound field correction for a sound field correction circuit 12 is controlled to cancel the relative difference between the microphone frequency characteristic curve and the audio source frequency characteristic curve.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic sound field compensator for an audio system, and in particular in a car audio system, a home audio system, etc., an audio source signal output from a CD player, radio, tape deck, etc. The present invention relates to an automatic sound field correction device for an audio system, which is capable of automatically correcting the sound field characteristic that faithfully reproduces the source.

[0002]

2. Description of the Related Art In an audio system, it is ideal to reproduce sound faithfully to the source, but in general, the frequency characteristic of the speaker and the frequency characteristic of the sound reproduction space are not flat, so that the audio source device outputs the sound. If the audio source signal is simply amplified by the amplifier and the sound is input to the speaker, the sound faithful to the source cannot be heard, and some kind of sound field correction must be performed.

Therefore, conventionally, a sound field correction circuit such as a graphic equalizer is provided between the audio source device and the amplifier to reproduce a special test signal such as pink noise, impulse noise, and test tone. , The speaker playback sound is picked up by the microphone, and the frequency characteristics of the microphone output are analyzed (in the case of impulse noise,
(Including Fourier transform such as FFT), and the sound field correction circuit performs the sound field correction to obtain a flat sound reproduction characteristic.

At this time, the sound field correction is often performed manually by the user, but a microcomputer is used to analyze the frequency characteristics of the microphone output, calculate an optimum correction amount, and a sound field correction circuit based on the calculation result. There is also a system that automatically obtains a flat sound reproduction characteristic by performing sound field correction control for. Note that once the sound field characteristics have been corrected so that a flat sound reproduction characteristic can be obtained, and then the type of speaker is changed or the speaker arrangement is changed, the sound field correction is performed again.

[0005]

However, in the above-described conventional sound field characteristic correction method, a test recording medium in which special test signals such as pink noise, impulse noise, and test tone are recorded is prepared, and the test is performed. The recording medium for use must be set in the audio system for reproduction, and there is a problem that the user hears an unpleasant sound by reproducing these test signals. In addition, when the sound field correction is performed manually, it is troublesome.

From the above, an object of the present invention is to provide an automatic sound field correction device for an audio system capable of automatically correcting sound field characteristics by reproducing a normal music source without using a special test signal. Is to provide.

[0007]

According to one aspect of the present invention, in the audio system including an audio source device, a sound field correction circuit, an amplifier and a speaker, a microphone for picking up a speaker reproduction sound and a band of the microphone output are provided. First band-specific signal level detecting means for detecting different signal level, second band-specific signal level detecting means for detecting band-specific signal level of audio source signal output from audio source device, and first band-specific signal level From the detection output of the detection means and the detection output of the signal level detection means for each second band, an average detection level for a predetermined fixed time in the same period on the microphone side and the audio source side is obtained for each band, and the obtained microphone is obtained. Side frequency characteristic curve and audio source side frequency characteristic curve And a sound field correction control means for performing sound field correction control for the sound field correction circuit so as to cancel the relative difference between the microphone side frequency characteristic curve and the audio source side frequency characteristic curve. It is achieved by

According to another aspect of the present invention, in an audio system including an audio source device, a sound field correction circuit, an amplifier and a speaker, a microphone for picking up a speaker reproduction sound and a band for detecting a signal level for each band. From the detection output of the signal level detection means, the microphone output and the time-division input means for time-divisionally inputting the audio source signal output from the audio source device to the band-by-band signal level detection means, and the detection output of the band-by-band signal level detection means, For each band, calculate the average detection level for a certain fixed time in the same period on the microphone side and the audio source side, and from the obtained average detection level for each band on the microphone side and audio source side to the microphone side frequency characteristic curve. A means for calculating the relative difference of the frequency characteristic curve on the audio source side, and an A sound field correction control means for sound field correction control for sound field correction circuit so as to cancel the relative difference in Iososu side frequency characteristic curve is achieved by a provided.

[0009]

According to one aspect of the present invention, the band-by-band signal level of the speaker reproduction sound picked up by the microphone and the band-by-band signal level of the audio source signal output from the audio device are individually detected, and for each band, Obtain the average detection level for a certain fixed time in the same period on the microphone side and the audio source side, and from the obtained average detection level for each band of the microphone side and audio source side, the microphone side frequency characteristic curve and audio source side frequency characteristic The sound field correction control is performed on the sound field correction circuit so that the relative difference between the curves is calculated and the relative difference between the microphone side frequency characteristic curve and the audio source side frequency characteristic curve is canceled. As a result, the sound field characteristic can be corrected using the normal music source signal without using a special test signal, so that a test recording medium can be prepared or the test recording medium can be set in the system. There is no need to do this, and since normal music is heard during sound field correction, there is no discomfort. Further, since the sound field correction is automatically performed, it is not necessary to manually correct the sound field. In addition, there is a delay time of about several ms between the audio source signal output from the audio source device and the microphone output of the audio source signal via the sound field correction circuit, the amplifier, the speaker, and the microphone. When performing sound field correction by comparing the detection levels of the microphone output and the audio source signal at the same time, the microphone output must be corrected in advance (the amount of correction varies depending on the frequency), but for each band, The average detection level of the microphone side and the audio source side for the same fixed period is calculated so that the error due to the delay does not occur, so the microphone output correction is unnecessary and the configuration is simple. ..

According to another aspect of the present invention, the signal level for each band of the speaker reproduction sound picked up by the microphone and the signal level for each band of the audio source signal output from the audio device are detected in a time division manner, and each is detected. For each band, find the average detection level for a certain fixed time in the same period on the microphone side and the audio source side, and from the obtained average detection level for each band on the microphone side and audio source side, measure the microphone side frequency characteristic curve and audio. The sound field correction control is performed on the sound field correction circuit so that the relative difference between the source side frequency characteristic curve is calculated and the relative difference between the microphone side frequency characteristic curve and the audio source side frequency characteristic curve is canceled. Thereby, it is possible to detect the signal level for each band with respect to the microphone output and the audio source signal by using one signal level for each band signal detection unit, and to simplify the configuration.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is an overall configuration diagram of a car audio system according to an embodiment of the present invention. In the figure, 10 is a head unit (audio source device) such as a CD player, radio, or tape deck, and 12 is a sound field correction circuit (graphic equalizer) that corrects a sound field for an audio source signal output from the head unit.
In the present embodiment, as an example, it is assumed that the audio field can be corrected by equally dividing the audio band into nine bands on the frequency axis (logarithmic axis). The center frequency points of the nine bands are 64Hz, 125Hz, 250Hz, 500Hz, 1kHz, 2kHz and 4k, respectively.
Hz, 8kHz, 16kHz. The sound field correction circuit 12 performs sound field correction under the sound field correction control of a microcomputer described later. Reference numeral 14 is an amplifier that amplifies the audio source signal that has passed through the sound field correction circuit, and 16 is a speaker driven by the amplifier.

Reference numeral 18 is a microphone for picking up a reproduced sound from a speaker, 20 is a first band-specific signal level detection circuit for detecting the band-specific signal level of the microphone output, and 22 to 38 are BPFs for dividing the microphone output into nine bands. , 42 to 58 are each B
Direct current detection circuit for individually direct current detecting PF output, 62-
Reference numeral 78 is a smoothing circuit for individually smoothing the output of each DC detection circuit. The center frequencies of the passbands of the BPFs 22 to 38 are 64 Hz, 125 Hz, 250 Hz, 500 Hz, 1 kHz, 2 kHz, 4 kH, which are the same as the center frequency points of the sound field correction circuit.
z, 8kHz, 16kHz, and smoothing circuits 62-7
8 outputs the detection level signal for each band of the microphone output.

Reference numeral 80 is a second band-specific signal level detection circuit for detecting the band-specific signal level of the audio source signal output from the head unit. Reference numerals 82-98 are BPFs for dividing the audio source signal into nine bands, 102-. 1
Reference numeral 18 is a direct current detection circuit that individually performs direct current detection of the output of each BPF, and 120 to 138 are smoothing circuits that individually smooth the output of each direct current detection circuit. The BPFs 82 to 98 have the same band pass characteristics as the BPFs 22 to 38 on the microphone side, and the center frequencies of the pass bands are 64 Hz and 125 Hz, respectively.
Hz, 250Hz, 500Hz, 1kHz, 2kHz, 4kHz, 8kHz, 16kHz
Accordingly, the smoothing circuits 122 to 138 output band-specific detection level signals of the audio source signal.

Reference numeral 140 denotes a first multiplexer for switching and outputting each detection output of the first band-specific signal level detection circuit in a time division manner, and reference numeral 142 for outputting each output of the second band-specific signal level detection circuit in a time division manner. Second multiplexer,
144 is a first A / D converter for A / D converting the output of the first multiplexer, and 146 is A / D conversion of the output of the second multiplexer.
A second A / D device for D conversion, 148 is an automatic correction instruction key for instructing automatic sound field correction, and 150 is a predetermined automatic sound field correction process when the automatic correction instruction key is pressed to instruct automatic sound field correction. It is a microcomputer that does. The microcomputer 150 includes a first multiplexer and a second multiplexer.
Synchronous switching control of the multiplexer, microphone output from the first A / D converter and second A / D converter, and detection level data for each band related to the audio source signal are input, and the microphone side and the audio source side are input for each band. The average detection level for a certain fixed time in the same period is calculated, and the relative difference between the microphone side frequency characteristic curve and the audio source side frequency characteristic curve is calculated from the obtained average detection level for each band of the microphone side and audio source side. The sound field correction control is performed on the sound field correction circuit so as to cancel the relative difference between the microphone side frequency characteristic curve and the audio source side frequency characteristic curve.

FIG. 2 is a flow chart showing an automatic sound field correction process by the microcomputer 150, and FIGS. 3 and 4 are explanatory views of the automatic sound field correction operation. Hereinafter, description will be given with reference to these drawings. It should be noted that the sound field correction circuit 12 is capable of performing sound field correction (gain adjustment) in steps of 1 dB within a range of ± 15 dB in each band here, and the RAM 152 of the microcomputer 150 (see FIG. 1) in advance. ), The band-specific gain data G _{1 to} G ₉ currently set in the sound field correction circuit 12 are registered (G _i).
Is the gain of the divided band counted from the low frequency side on the frequency axis, G ₁ is the gain of the band whose center frequency is 64 Hz, and G ₂ is
Gain in the 125Hz band, G ₃ in the 250Hz band,
..., G ₉ is the gain in the band of 16 kHz. (See the equalizer curve EQC in FIG. 4).

Now, when the car audio system shown in FIG. 1 is in a normal performance state, the normal audio source signal output from the head unit 10 is the sound field correction circuit 1.
After the sound field is corrected in 2 (however, the sound field correction is not applied when the frequency characteristic is set to flat in the sound field correction circuit), is amplified by the amplifier 14 and then input to the speaker 16, Sound is reproduced from 16.

At this time, the reproduced sound from the speaker 16 is
Signal level detection circuit 2 for each band picked up by the microphone 18
With 0, the signal level is detected for each of the 9 bands equally divided on the frequency axis, and the detection level signal for each band is output. Also, with respect to the audio source signal output from the head unit 10, the signal level is detected by the second band-specific signal level detection circuit 80 in each of the nine bands equally divided on the frequency axis, similarly to the microphone side,
The detection level signal for each band is output.

In this state, when the user wants to cancel the influence of the frequency characteristic of the speaker 16 or the frequency characteristic of the vehicle interior sound reproduction space and listen to music with a flat characteristic faithful to the source, the automatic correction instruction key 98 is pressed. Then, the microcomputer 150 is instructed to perform automatic sound field correction. Upon receiving this instruction, the microcomputer 150 instructs the first multiplexer 140 and the second multiplexer 142 to
Switching control is started, and synchronous switching is performed at high speed (steps 101 and 102 in FIG. 2). And first, the first A
The detection level data for each band on the microphone side output from the / D converter 144 is monitored, and if the data in a certain band exceeds a predetermined reference level (steps 103 and 104),
First multiplexer 140 and second multiplexer 142
Switching control is stopped (step 105), and the first A /
From the D converter 144 and the second A / D converter 146, the detection level data for each band on the microphone side and the audio source side of the band in question is output for a predetermined number of samples (several hundred ms) for the same period.
After inputting only for a predetermined fixed time), the microphone side and the audio source side are separately added, and then divided by the predetermined number of samples to obtain an average detection level (step 10).
6) The microphone side and the audio source side are associated with the band and registered in the RAM 152 (step 10).
7).

When the above process is completed for one band, the switching control of the first multiplexer 140 and the second multiplexer 142 is restarted (step 108,
102), the detection level data for each band on the microphone side output from the first A / D converter 144 is monitored except for the band that has been processed previously, and the data of a certain band exceeds a predetermined reference level. If so (steps 103 and 104), the switching control of the first multiplexer 140 and the second multiplexer 142 is stopped (step 105), and the first A / D converter 144 and the second A / D converter 146 are connected to the microphone side of the band. Input the detection level data for each band on the audio source side for a specified number of samples, add them separately for the microphone side and audio source side, and divide by the specified number of samples to obtain the average detection level. It is registered in the RAM 152 in association with the band separately for the audio source side (steps 106 and 107).

The same processing is performed thereafter without the unprocessed band.
Run until When processing of all bands is completed (step
108, at this time, the first multiplexer 140 and the second multiplexer 140
The switching of the multiplexer 142 remains stopped.
), For example, with the microphone side registered in RAM 152
The average detection level for each band on the audio source side is in dB
Then, when it becomes as shown by the solid line in Fig. 3 (each band on the microphone side)
ML for average detection level by region₁~ ML₉, Audio saw
The average detection level for each band on the monitor side is AL₁~ AL ₉Indicated by
Of each band separately for the microphone side and the audio source side.
Microphone side frequency characteristic curve MC that connects average detection levels
And the relative difference between the audio source side frequency characteristic curve AC
Ask.

There are various methods for obtaining the relative difference.
Here, AL ₁ ~ so that the average detection level (AL ₅ ) on the audio source side in the fifth band (center frequency 1 kHz) matches the average detection level ML ₅ on the microphone side.
The corrected average detection levels AL ₁ ′ to AL ₉ ′ obtained by correcting all AL ₉ by α and α = ML ₅ −AL ₅ shown in the following equations are obtained, and then the amount of adjustment of the gain is g as a relative difference for each band.
_i , g _i = AL _i ′ −ML _i (i = 1 to 9) is calculated (step 109, see FIG. 3). However, g ₅ =
It is 0.

Next, the microcomputer 150 uses the obtained gain adjustment amounts g _{1 to} g ₉ to cancel the relative difference between the microphone side frequency characteristic curve (AC) and the audio source side frequency characteristic curve (MC). Performs sound field correction control for the sound field correction circuit. Specifically, using the preset sound field correction data G _i for each band in the sound field correction circuit 12 registered in advance in the RAM 152 of the microcomputer 150, G _i ′ = G _i + g _i (i = 1 to 1) 9) is performed, the G ₁ ′ to G ₉ ′ are rewritten and registered in the RAM as new set sound field correction data, and the new sound field correction data G ₁ ′ to G ₉ ′ for each band is set in the sound field. It outputs to the correction circuit 12 and changes the gain of each band of the sound field correction circuit 12 to G ₁ ′ to G ₉ ′, g ₁ to g for each band.
₉ is changed (step 110). As a result, the equalizer curve in the sound field correction circuit 12 becomes EQC 'in FIG. If the equalizer curve of the sound field correction circuit 12 before correction is flat and correct (G _{1 to} G ₉ are all 0), the gain of each band of the sound field correction circuit 12 is g _1. It becomes ~ g ₉ .

In this way, the microphone side frequency characteristic curve (MC) and the audio source side frequency characteristic curve (A
As a result of performing the sound field correction control so as to cancel out the relative difference of C), the user can obtain the flat frequency characteristics faithful to the source regardless of the set sound field correction characteristics in the sound field correction circuit 12 until then. You will be able to listen to music. If the speaker type is changed or the speaker arrangement is changed after the automatic sound field correction is once performed, the automatic correction instruction key may be pressed again to instruct the automatic sound field correction.

According to this embodiment, a signal obtained from an ordinary music source such as a music CD, a music tape, a music broadcast, etc. is used without using a special test signal such as pink noise, impulse noise, test tone signal, etc. Since the sound field can be corrected by using it, there is no need to prepare a test recording medium or set the test recording medium in the system, and normal music can be continuously heard during the sound field correction. So you don't feel any discomfort and you don't have to interrupt the music you were listening to. Further, when the automatic sound field correction is instructed by the automatic sound correction instruction key, the sound field correction is automatically performed by the microcomputer, so that it is not necessary to manually perform the sound field correction operation.

There is a delay time of about several ms between the audio source signal output from the head unit and the microphone output of the audio source signal via the sound field correction circuit, the amplifier, the speaker, and the microphone. However, when performing sound field correction based on the detection level of the microphone output and the audio source signal at the same time, it is necessary to correct the microphone output in advance, but for each band, the microphone side and the audio source side Since an average detection level for a predetermined constant time in the same period is obtained so that an error due to delay does not occur, it is not necessary to correct the microphone output, and the configuration is simple. Further, when the average detection level of a certain band is obtained, the calculation is started when the average reference level exceeds a certain reference level, so that the calculation error can be reduced.

In the above-described embodiment, the microcomputer performs only the automatic sound field correction process, but a sound field characteristic adjusting operation section is connected to the microcomputer so that any sound field characteristic can be set by manual operation. You may do it. As shown in FIG. 5, the spectrum analyzer 154 is connected to the microcomputer 150A, and the head unit 1 is connected to the input side of the second band-specific signal level detection circuit 80.
A changeover switch 156 for switching and inputting the output of 0 and the output of the sound field correction circuit 12 is added, and when performing automatic sound field correction processing, the changeover switch 156 is changed over to the output side of the head unit 10 and is exactly the same as above. While the automatic sound field correction processing is performed, when the automatic sound field correction processing is not performed, the changeover switch 156 is switched to the output side of the sound field correction circuit 12, and the switching control of the second multiplexer 142 is performed. Detection level data for each band may be input from the second A / D converter 146, and spectrum analyzer display control for the spectrum analyzer display 154 may be performed based on the detection level data.

Further, in the embodiment of FIG. 1, the band side signal level detection circuit, the multiplexer and the A / D converter are separately provided on the microphone side and the audio source side, but as shown in FIG. A multiplexer 16 that includes only one set of the detection circuit 158, the multiplexer 160, and the A / D converter 162, and that inputs the microphone output and the audio source signal to the input side of the band-specific signal level detection circuit 158 in a time division manner
4 and the automatic sound field correction is instructed, the microcomputer 150B starts the high-speed switching control of the multiplexer 164, and the multiplexer 164
The multiplexer 160 controls so that it switches to the next position each time the switching is completed, and when the multiplexer 164 is on the microphone side, A /
If the detection level data output from the D converter 162 exceeds a predetermined reference level, switching of the multiplexer 160 is stopped while switching of the multiplexer 164 is continued, and the microphone side in the same band and in the same period. The average detection level on the audio source side is calculated, and when processing is completed for one band, the multiplexer 16
Restart the switching of 0, for other unprocessed bandwidth,
The same process may be performed to obtain the average detection level for each band on the microphone side and the audio source side. With this, only one set of the signal level detection circuit for each band and the A / D converter is required, so that the configuration can be simplified.

In the embodiment of FIG. 1, the average detection level for each band is calculated by the microcomputer. However, as shown in FIG. 7, the first A / D converter 144 and the second A / D converter 144 are used.
The output of the A / D converter 146 is input to a DSP (digital signal processor) 166, the DSP 166 calculates the average detection level for each band on the microphone side and the audio source side, and outputs the result to the microcomputer 150C. If the microcomputer 150C performs sound field correction control based on the relative difference between the microphone side frequency characteristic curve and the audio source side frequency characteristic curve, the load on the microcomputer 150C can be significantly reduced. Even during the automatic sound field correction processing, other processing such as CD subcode information display can be executed without difficulty. DSP for calculating the average detection level for each band as shown in FIG.
When using, the sound field correction circuit itself can also be used by one DSP when it is realized by using the DSP.

Further, as shown in FIG. 8, the output of the microphone 18 is digitized by the first A / D converter 144 and the DSP 1
66A, and the output of the head unit 10 is also digitized by the second A / D converter 146 to be converted to the DSP 166.
By inputting to A and performing the filtering processing by the DSP 166A, the signal level for each band and the average signal level for each band are calculated for each band on the microphone side and the audio source side, and the result is calculated. Output to the microcomputer 150C, and the microcomputer 150
If the sound field correction control is performed based on the relative difference between the microphone side frequency characteristic curve and the audio source side frequency characteristic curve in C, the load on the microcomputer 150C can be significantly reduced, and at the same time the hardware configuration can be reduced. The band-level signal level detection circuit is also unnecessary.

Further, in the above-mentioned embodiments and modifications, the car audio system has been described as an example, but the present invention is not limited to this and can be similarly applied to a home audio system and the like. ..

[0031]

As described above, according to one aspect of the present invention, the signal level for each band of the speaker reproduction sound picked up by the microphone and the signal level for each band of the audio source signal output from the audio device are individually detected, and each band is detected. For each time, the average detection level of the microphone side and the audio source side during the same fixed period is calculated, and the microphone side frequency characteristic curve and the audio source are calculated from the obtained average detection level for each band of the microphone side and the audio source side. A special test was performed because the relative difference of the side frequency characteristic curve was calculated and the sound field correction control was performed to the sound field correction circuit so as to cancel the relative difference between the microphone side frequency characteristic curve and the audio source side frequency characteristic curve. Since a sound field characteristic can be corrected using a normal music source signal without using a signal, prepare a test recording medium. Ri, it is not necessary or to set the test for the recording medium to the system, also, in the sound field correction, discomfort does not occur because the normal music is heard. Further, since the sound field correction is automatically performed, it is not necessary to manually perform the sound field correction operation. In addition, there is a delay time of about several ms between the audio source signal output from the audio source device and the microphone output of the audio source signal via the sound field correction circuit, the amplifier, the speaker, and the microphone. When performing sound field correction based on the detection level of the microphone output and the audio source signal at the same time,
The microphone output must be corrected, but for each band, the average detection level of the microphone side and the audio source side for a certain fixed time in the same period is calculated to prevent an error due to delay. Since it does not require correction of the microphone output, the configuration is simple.

According to another aspect of the present invention, the signal level by band of the speaker reproduction sound picked up by the microphone and the signal level by band of the audio source signal output from the audio device are detected in a time division manner, For each band, calculate the average detection level for a certain fixed time in the same period on the microphone side and the audio source side, and from the obtained average detection level for each band on the microphone side and audio source side to the microphone side frequency characteristic curve. Since the relative difference between the frequency characteristic curve of the audio source side is calculated and the sound field correction control is performed to the sound field correction circuit so as to cancel the relative difference between the frequency characteristic curve of the microphone side and the frequency characteristic curve of the audio source side, By using the signal level detection means for each band,
The signal level for each band of the microphone output and the audio source signal can be detected, and the configuration can be simplified.

[Brief description of drawings]

FIG. 1 is an overall configuration diagram of a car audio system according to an embodiment of the present invention.

FIG. 2 is a flowchart showing an automatic sound field correction process.

FIG. 3 is an explanatory diagram of an automatic sound field correction operation.

FIG. 4 is an explanatory diagram of an automatic sound field correction operation.

FIG. 5 is an overall configuration diagram showing a modified example of the present invention.

FIG. 6 is an overall configuration diagram showing another modification of the present invention.

FIG. 7 is an overall configuration diagram showing another modification of the present invention.

FIG. 8 is an overall configuration diagram showing another modification of the present invention.

[Explanation of symbols]

10 head unit 12 sound field correction circuit 14 amplifier 16 speaker 18 microphone 20 first band-specific signal level detection circuit 80 second band-based signal level detection circuit 140 first multiplexer 142 second multiplexer 148 automatic correction instruction key 150, 150A, 150B , 150C Microcomputer 158 Band-wise signal level detection circuit 164 Multiplexer 166, 166A DSP

Claims (2)

[Claims] 1. An audio source device, a sound field correction circuit,
In an audio system including an amplifier and a speaker, a microphone for picking up a speaker playback sound, a first band-based signal level detection means for detecting a band-based signal level of a microphone output, and a band for an audio source signal output from an audio source device From the detection output of the second band-specific signal level detecting means for detecting the signal level, the first band-specific signal level detecting means, and the second band-specific signal level detecting means, the microphone side and the audio source for each band Side, the average detection level for a certain fixed time in the same period is calculated, and the relative difference between the microphone side frequency characteristic curve and the audio source side frequency characteristic curve is calculated from the obtained average detection level for each band of the microphone side and audio source side. The means of calculation and the phase relationship between the microphone side frequency characteristic curve and the audio source side frequency characteristic curve Automatic sound field correcting apparatus of an audio system characterized by comprising a sound field correction control means for sound field correction control for sound field correction circuit so as to cancel the difference, the. 2. An audio source device, a sound field correction circuit,
In an audio system that includes an amplifier and a speaker, a microphone that picks up the speaker playback sound, a band-level signal level detection unit that detects the band-level signal level, and a microphone output and the audio source signal output from the audio source device are time-divided. From the detection output of the time-division input means input to the band-by-band signal level detection means and the detection output of the band-by-band signal level detection means, for each band, the average detection level for a predetermined fixed time in the same period on the microphone side and the audio source side And a method of calculating the relative difference between the microphone side frequency characteristic curve and the audio source side frequency characteristic curve from the obtained average detection level for each band of the microphone side and audio source side, and the microphone side frequency characteristic curve and the audio source side. The sound field to the sound field correction circuit so as to cancel the relative difference of the frequency characteristic curve. Automatic sound field correcting apparatus of an audio system for sound field correction control means for performing a positive control, characterized in that the provided.