JP2011217066A - Sound signal output control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology to output an input sound signal without clipping.SOLUTION: A microphone detection unit 103 detects a number of microphones in an operation state based on signal levels of respective sound signals of a microphone 10a, a microphone 10b, and a microphone 10c, and outputs the detected number of microphones to a compressor control unit 104. If a voice signal mixing respective sound signals output from the microphone 10a, the microphone 10b, and the microphone 10c is input, the compressor 106 compares the signal level of the voice signal with a predetermined threshold value based on compression control information according to the number of the microphones instructed from the compressor control unit 104, carries out compression processing to the voice signal exceeding the threshold value following a compression mode determined by the number of microphones, and outputs it.

Description

  The present invention relates to a sound signal output control device.

  The compressor performs signal compression processing so as not to reach the maximum signal level when a sound signal exceeding a predetermined signal level is input, and is also used in a karaoke apparatus or the like. Patent Document 1 below discloses a karaoke apparatus having a recording function for mixing the output signals of audio data and audio data having different output levels by reducing the gain so as to match the lower output level.

JP 2004-295934 A

By the way, when the input signal exceeds the threshold set in the compressor, the compressor performs the compression process, so that the waveform of the audio signal is distorted. Since there is a desire to output the audio signal from the microphone in the karaoke apparatus with as little distortion as possible, it is preferable not to perform compression processing by the compressor. On the other hand, as the number of microphones used increases, the signal level of the audio signal mixed with the input signal from each microphone increases, and there is a problem that clipping occurs unless the compression processing by the compressor is applied.
The present invention provides a technique for outputting an input sound signal without clipping.

  According to a first aspect of the present invention, there is provided a sound signal output control device comprising: detection means for detecting the number of microphones in an operating state based on a signal level of a sound signal input from each microphone; Storage means for storing compression control information that predetermines a compression mode for the sound signal in accordance with the number; and the compression control information corresponding to the number of microphones in the operating state detected by the detection means. When the signal level of the audio signal mixed with all the sound signals output from the microphone in the operating state detected by the detection means exceeds a predetermined threshold, the audio signal is compressed according to the read compression control information. Compression means for outputting, and output means for outputting the audio signal compressed by the compression means.

  According to a second aspect of the present invention, there is provided the sound signal output control device, wherein in the sound signal output control device, the frequency component of the sound signal compressed by the compression means is analyzed to generate a howling. Corresponding to howling detection means for detecting, attenuation amount storage means for storing the attenuation amount of the audio signal according to the number of microphones in the operating state, and the number of microphones in the operating state detected by the detecting means Howling suppression means for reading an attenuation amount from the attenuation amount storage means and attenuating a frequency component causing howling detected by the howling detection means according to the read attenuation amount, and the output means includes the howling suppression means The audio signal that has been subjected to the attenuation process according to is output.

  In the sound signal output control device according to claim 3 of the present invention, in the sound signal output control device, the threshold value is a threshold value determined in advance according to the number of microphones in the operating state, and the compression The control information includes a first time from when the audio signal exceeds the threshold to compression, a second time from when the audio signal again falls below the threshold to stop compression, and a compression ratio. The compression means is based on the compression control information according to the number of microphones detected by the detection means, and after the first time has elapsed since the time when the audio signal exceeded the threshold, The audio signal is compressed according to the compression ratio, and the compression of the audio signal is stopped when the second time elapses from the time when the audio signal becomes equal to or less than the threshold value.

  According to the configuration of the first aspect, the sound signal input from the microphone can be output without clipping.

  According to the structure of Claim 2, howling of the sound signal input from the microphone can be suppressed.

  According to the structure of Claim 3, the compression process according to the number of microphones can be appropriately performed with respect to the sound signal input from the microphone.

It is a block diagram showing the structure of the karaoke apparatus which concerns on embodiment. It is a figure explaining the structure of the audio | voice signal processing part which concerns on embodiment. (A) is a figure which shows the structure and data example of compression control information which concern on embodiment. (B) is a figure which shows the structure and example of data of howling control information which concern on embodiment. (A) And (b) is the figure which illustrated the signal level waveform of the audio | voice signal which concerns on embodiment. It is a figure explaining howling suppression processing in an embodiment. (A)-(c) is the figure which illustrated the waveform of each microphone signal concerning an embodiment. It is the figure which illustrated the waveform of the audio signal which mixed each microphone signal concerning an embodiment.

  The sound signal output control device according to the present embodiment will be described with reference to an example in which the sound signal output control device is incorporated into a karaoke device, but may be used together with a musical sound generation device other than a karaoke device. Hereinafter, details of the karaoke apparatus according to the present embodiment will be described.

(Constitution)
FIG. 1 is a block diagram showing the configuration of the karaoke apparatus according to the present embodiment. In the karaoke apparatus 1, three microphones 10 a, 10 b, and 10 c are connected to a microphone connection terminal, and a control unit 11, an operation unit 12, a storage unit 13, a sound source unit 14, a display unit 15, and an audio signal processing unit 16. It is comprised including. In the present embodiment, an example in which three microphones 10a, 10b, and 10c are connected will be described. However, the number of connected microphones is not limited thereto.

  The microphone 10 is, for example, a loudspeaker such as a condenser microphone, and sends a sound signal obtained by collecting a singing sound emitted by a singer to the sound signal processing unit 16. The microphones 10a, 10b, and 10c used in the present embodiment are respectively provided with on / off switches sa, sb, and sc that turn on and off the output of audio signals. In this case, when the on / off switches sa, sb, and sc are on, an audio signal corresponding to the collected sound is output to the output line. When the on / off switches sa, sb, and sc are off, the output line is shorted so that no audio signal is output. It has become. Hereinafter, in the present embodiment, a state in which the on / off switch is on is referred to as an operating state, and the microphones 10a, 10b, and 10c are referred to as a microphone 10 when not distinguished from each other.

  The control unit 11 includes a CPU, a RAM, and a ROM memory, and controls each unit connected to the control unit 11 by executing a control program stored in the ROM using the RAM as a working area. .

  The operation unit 12 is an operation unit that accepts an operation from a user by wire or wirelessly. Consists of a main volume control knob that accepts an operation to adjust the total volume level of the singing sound and each audio signal of the music, and includes controls such as operation buttons for instructing music selection and music playback Is done. The operation unit 12 sends an operation signal indicating the content operated by the user to the control unit 11.

  The storage unit 13 is configured by a nonvolatile storage medium, and stores audio signal processing control information 130 that is referred to during signal processing of the audio signal processing unit 16 in addition to music data such as MIDI and lyrics data. ing. The audio signal processing control information 130 includes compression control information and howling control information, which will be described later in detail.

  The sound source unit 14 reproduces the instructed music data under the control of the control unit 11 to generate a musical tone signal, and sends it to the audio signal processing unit 16. The display unit 15 is configured by a liquid crystal display or the like, and displays the lyric data of the instructed music and the operation content received by the operation unit 12 under the control of the control unit 11.

The audio signal processing unit 16 is an example of a sound signal output control device according to the present invention. The audio signal processing unit 16 performs predetermined signal processing on the sound signal input from the microphone 10 under the control of the control unit 11. To output. Details of the audio signal processing unit 16 will be described below.
The audio signal processing unit 16 includes a preamplifier 101, an A / D conversion unit 102, a microphone detection unit 103, a compressor control unit 104, a compressor 106, a howling suppression control unit 105, a howling suppression unit 107, a mixer 108, and a D / A conversion unit 109. , An amplifier 110, and a speaker 111. In the present embodiment, the microphone detection unit 103, the compressor control unit 104, the compressor 106, the howling suppression control unit 105, the howling suppression unit 107, and the mixer 108 are realized by a DSP (Digital Signal Processor).

  The preamplifier 101 amplifies each output signal (hereinafter referred to as a microphone signal) from the microphone 10 according to the microphone volume set by the microphone volume control knob, and supplies the amplified microphone signal to the A / D converter 102. Send it out. The A / D conversion unit 102 performs A / D conversion on the microphone signals of the microphones 10 output from the preamplifier 101, and outputs the microphone signals of the microphones 10 subjected to A / D conversion to the microphone detection unit 103. An audio signal obtained by mixing each microphone signal of the microphone 10 subjected to the / D conversion is sent to the compressor 106.

  The microphone detection unit 103 is based on the microphone signal of each microphone 10 output from the A / D conversion unit 102 and the microphone detection threshold (Vm) for determining whether the microphone 10 is in an operating state. The number of microphones in the operating state is detected, and the detected number of microphones is sent to the compressor control unit 104 and the howling suppression control unit 105.

Based on the number of microphones output from the microphone detection unit 103, the compressor control unit 104 reads out compression control information corresponding to the number of microphones in the operating state from the storage unit 13 and sends it to the compressor 106.
The compressor 106 is a compression unit according to the present invention, and a process of compressing the audio signal based on the signal level of the audio signal output from the A / D conversion unit 102 and the compression control information output from the compressor control unit 104. I do.

  Here, the compression control information will be described. FIG. 3A is a diagram illustrating a configuration and data example of the compression control information. In this figure, the number of microphones indicates the number of microphones 10 in the operating state. The attack time (ΔT1) indicates the time from when the audio signal input to the compressor 106 exceeds the threshold value (Vth) until the compression process is started, and the release time (ΔT2) is the audio signal again below the threshold value. It shows the time from the start to the end of the compression process. The ratio is a compression ratio for compressing the audio signal according to the number of microphones. The threshold value (Vth) is a signal level to be compressed, and is set to a value smaller than the maximum signal level (Vmax) in the compressor 106.

  For example, when the audio signal having the waveform 30 shown in FIG. 4A is output from the A / D converter 102, when this audio signal is input to the compressor 106, as shown in FIG. The audio signal compression process is started in accordance with the ratio corresponding to the number of microphones from the time when the attack time ΔT1 corresponding to the number of microphones has elapsed since t1 when the threshold Vth corresponding to the number of microphones was exceeded. Then, the compression process is stopped when the release time ΔT2 corresponding to the number of microphones has elapsed from t2 when the signal level of the audio signal becomes equal to or lower than the threshold value Vth again. By this compression processing, the waveform 30 is compressed as a waveform 31.

In the present embodiment, in the compression control information shown in FIG. 3A, the attack time and release time are set shorter as the number of microphones increases (T31 <T21 <T11 <...), (T12). <T22 <T32 ...). The ratio is set to a larger value as the number of microphones increases (R1 <R2 <R3...), And the threshold is set to increase as the number of microphones increases (Vth1 <Vth2 <Vth3...). .
That is, as the number of microphones increases, the signal level of the audio signal input from each microphone 10 increases. Therefore, the threshold is set higher as the number of microphones increases, and the ratio is set so as not to clip at the maximum signal level of the compressor 106. Is set large, the attack time and the release time are set short, and high compression processing is performed on the audio signal exceeding the threshold. In addition, when the number of microphones is small, the signal level of the audio signal input from the microphone 10 is lower than when the number of microphones is large. Therefore, the threshold is set smaller than when the number of microphones is large, and the attack time and release time are The length is set longer than that when the number of microphones is large, and low compression processing is performed on a signal exceeding the threshold. In this way, by defining a dynamic range of an appropriate volume according to the number of microphones and dynamically changing the threshold value, and performing compression processing according to the number of microphones, any microphone number is appropriate. Since the signal level of the audio signal can be automatically adjusted so as to be in the dynamic range, the volume can be easily heard by the user.

  Returning to FIG. 2, the description will be continued. The howling suppression control unit 105 reads out howling control information indicating the attenuation condition according to the number of microphones output from the microphone detection unit 103 from the storage unit 13 and instructs the howling suppression unit 107 to perform the instruction. Here, howling control information will be described. FIG. 3B is a diagram illustrating a configuration and data example of howling control information. In this figure, the number of microphones indicates the number of microphones in an operating state, as in the compression control information described above, and the gain corresponding to each number of microphones is the frequency at which howling occurs (hereinafter referred to as the howling frequency). Is the amount of attenuation for the component. In this embodiment, as the number of microphones increases, the signal level of the audio signal mixed with each microphone signal increases and the amplitude level of the howling frequency increases. Therefore, the attenuation amount increases as the number of microphones increases. (G1 <G2 <G3...).

  The howling suppression unit 107 performs frequency analysis processing using fast Fourier transform on the audio signal output from the compressor 106, and howling suppression control unit 105 converts the audio signal of the howling frequency component exceeding a predetermined amplitude level. Attenuation processing is performed using a notch filter in accordance with the attenuation amount based on the howling control information instructed from. Specifically, as a result of frequency analysis of the input audio signal in the howling suppression unit 107, for example, when a frequency spectrum as shown in FIG. 5 is obtained, the frequency exceeding a predetermined amplitude level Ath. It is detected that howling occurs at f1. The howling suppression unit 107 uses the howling frequency f1 as a center frequency, determines a Q value based on the amplitude level of the howling frequency f1, and uses a notch filter with the gain of howling control information instructed from the howling suppression control unit 105 as an attenuation amount. The howling frequency f1 component is attenuated.

  Returning to FIG. The mixer 108 outputs to the D / A converter 109 a sound signal obtained by mixing the sound signal output by the howling suppressor 107 with howling being suppressed and the musical sound signal generated by the sound source unit 14. The D / A conversion unit 109 performs D / A conversion processing on the audio signal output from the mixer 108 and outputs the result to the amplifier 110. Then, the amplifier 110 amplifies the audio signal output from the D / A conversion unit 109 according to the volume set by the microphone volume control knob and the volume set by the main volume control knob instructed from the control unit 11. The sound is output to the speaker 111 and emitted from the speaker 111.

(Operation example)
Next, the operation of the karaoke apparatus 1 according to the present embodiment will be described focusing on the operation of the audio signal processing unit 16. In the following description, a case where microphone signals having respective waveforms shown in FIGS. 6A to 6C are output from the microphone 10 will be described as an example. 6A shows the waveform of the microphone signal of the microphone 10a, FIG. 6B shows the waveform of the microphone signal of the microphone 10b, and FIG. 6C shows the waveform of the microphone signal of the microphone 10c. Is shown.
In this example, the on / off switches sa, sb, and sc of each microphone 10 are turned on from the time t1, and an operation state in which no sound from the singer is input to any microphone 10 from t1 to t2. It has become. Also, from t2 to t3, the voices of each singer are input to each of the three microphones 10, and from t3 to t4, the microphone 10c is on and no voice from the singer is input. Have been turned off later.
The microphone signals output from the microphone 10 a, the microphone 10 b, and the microphone 10 c are each amplified by the preamplifier 101 according to the volume level of the microphone set by the operation unit 12 and output to the A / D conversion unit 102. Each microphone signal input from the preamplifier 101 to the A / D converter 102 is A / D converted by the A / D converter 102 and output to the microphone detector 103. Also, the audio signal in which the microphone signals A / D converted by the A / D converter 102 are mixed is output to the compressor 106.

  The microphone detection unit 103 compares the signal level of each microphone signal output from the A / D conversion unit 102 with the microphone detection threshold value (Vm), and detects whether the fluctuation amount of the signal level is a certain value or more. The number of microphones in the operating state is output to the compressor control unit 104 and the howling suppression control unit 105. In this example, the fluctuation amount of the signal level of the microphone signal is a certain value or more, and the period during which the signal level of the microphone signal of each microphone 10 exceeds the microphone detection threshold Vm is t1 to t4. In this case, the number of microphones “3” is detected. Further, after t4, only the signal level of the microphone signals of the microphones 10a and 10b exceeds the threshold value Vm, and therefore the number of microphones “2” is detected.

  When the number of microphones “3” is output from the microphone detection unit 103, the compressor control unit 104 has an attack time “T31”, a release time “T32”, a ratio “R3”, a threshold “ Vth3 ”is read out from the storage unit 13 as compression control information and output to the compressor 106. When the microphone detection unit 103 outputs the number of microphones“ 2 ”, the attack time“ T21 ”corresponding to the number of microphones“ 2 ”is output. The release time “T22”, the ratio “R2”, and the threshold value “Vth2” are read from the storage unit 13 as compression control information and output to the compressor 106.

  Further, when the number of microphones “3” is output from the microphone detection unit 103, the howling suppression control unit 105 reads the gain “G3” corresponding to the number of microphones “3” from the storage unit 13 as howling control information. When the number of microphones “2” is input from the microphone detection unit 103 and output to the howling suppression unit 107, the gain “G2” corresponding to the number of microphones “2” is read from the storage unit 13 as howling control information and howling. The data is sent to the suppression unit 107.

When an audio signal in which each microphone signal is mixed is input in the A / D conversion unit 102, the compressor 106 performs compression processing on the input audio signal in accordance with the compression control information output from the compressor control unit 104. Do.
FIG. 7 is a diagram illustrating the waveform of the audio signal output from the A / D converter 102 by mixing the microphone signals shown in FIG. It is assumed that t1, t2, t3, and t4 in this figure correspond to t1, t2, t3, and t4 in FIG.

  When the audio signal at t1 to t4 in FIG. 7 is input, the compressor 106 receives the threshold value Vth3 and the signal of the audio signal based on the compression control information corresponding to the number of microphones “3” output from the compressor control unit 104. Compare the level. When the audio signal exceeds the threshold Vth3, the compressor 106 compresses the audio signal input at the compression ratio of the ratio “R3” when the attack time “T31” has elapsed from the time when the threshold Vth3 was exceeded. Process. Then, the compression process is stopped when the release time “T32” has elapsed from the time when the threshold value Vth3 again becomes lower than the threshold value Vth3, and the compressed audio signal is output to the howling suppression unit 107.

  Further, when an audio signal after t4 in FIG. 7 is input to the compressor 106, based on the compression control information corresponding to the number of microphones “2” output from the compressor control unit 104, the threshold value Vth2 and the audio signal Compare the signal level. Then, if the audio signal exceeds the threshold value Vth2, the compressor 106 applies to the audio signal input at the compression ratio of “R2” when the attack time “T21” elapses from the time when the threshold value Vth2 is exceeded. To perform compression processing. Then, the compression process is stopped when the release time “T22” has elapsed from the time when the threshold value Vth2 again becomes lower than the threshold value Vth2, and the audio signal after the compression process is output to the howling suppression unit 107.

  With this processing, during the period from t1 to t4 when many peak waveforms with large signal levels appear when voices are input to the three microphones 10 in the operating state, before the maximum signal level is exceeded, an audio signal exceeding the threshold Vth3 is detected. Since the compression process is performed, the signal is output without being clipped at the maximum signal level. Also, after t4 when the number of microphones in operation is two and the peak waveform with low signal level increases, the signal level of the audio signal is lower than when there are three microphones, so the sound quality can be as low as possible by performing low compression processing. The output can be maintained.

  Subsequently, the howling suppression unit 107 performs frequency analysis processing on the audio signal input from the compressor 106 to detect a howling frequency, and sets a Q value based on the howling frequency and the amplitude level. The howling suppression unit 107 attenuates by a gain “G3” corresponding to the number of microphones “3” output from the howling suppression control unit 105 when howling is detected for the audio signal at t1 to t4 in FIG. And output to the mixer 108. When howling is detected for the audio signal after t4 in FIG. 7, the mixer 108 attenuates by a gain “G2” corresponding to the number of microphones “2” output from the howling suppression control unit 105. Output.

  In the above-described embodiment, when the signal level of the audio signal input to the compressor 106 exceeds a threshold value appropriately set according to the number of microphones, compression is performed according to the attack time, release time, and ratio according to the number of microphones. Processing can be performed. Therefore, the audio signal input in the compressor 106 is not clipped at the maximum signal level, and can be output so as not to have unnatural sound quality. In addition, the howling frequency component in the audio signal output from the compressor 106 can be attenuated and output by the howling suppression unit 107 using the attenuation amount appropriately set according to the number of microphones. It is possible to suppress howling from occurring due to the sound being picked up by each microphone 10 again.

<Modification>
Although the embodiments of the present invention have been described, the present invention is not limited to the above-described embodiments, and can be implemented in various other forms. For example, the above-described embodiment may be modified as follows to implement the present invention, or may be implemented in combination with each modification. Hereinafter, modifications of the embodiment according to the present invention will be described.

(1) In the above-described embodiment, the compression control information and the howling control information that are different depending on the number of microphones in the operating state are set in advance, but whether or not they are in the operating state and are used. Corresponding compression control information and howling control information may be set. That is, for example, when one of the three microphones in the operating state is not used because the signal level of the microphone signal is equal to or lower than a predetermined threshold, the number of microphones is set to 2.5 and two are used. If not, the number of microphones may be defined as 1.5, and compression control information and howling control information corresponding to the number of microphones may be set in advance. In order to determine whether or not the device is in an operating state, a predetermined threshold (> Vm) different from the microphone detection threshold (Vm) is set in advance for each number of microphones.

(2) In the embodiment described above, the howling suppression unit 107 attenuates the howling frequency component by the amount of attenuation corresponding to the number of microphones when detecting howling regardless of whether or not the compressor 106 has performed compression processing. However, when the compression process is performed by the compressor 106, the compression process is performed such that the amount of attenuation of the howling frequency component is attenuated by a predetermined amount compared to the case where the compression process is not performed. The amount of attenuation may be changed depending on whether or not it is. In this case, the information indicating whether or not the compression processing is performed by the compressor 106 may be notified to the howling suppression control unit 105 or the howling suppression unit 107.

(3) In the above-described embodiment, an attack time and a release time that are different depending on the number of microphones in the operating state have been set. However, only a different ratio may be set according to the number of microphones, or the number of microphones Only different attack times may be set in accordance with. Alternatively, only different release times may be set according to the number of microphones. Further, any two parameters of the ratio, attack time, and release time may be set to be different depending on the number of microphones. In the embodiment, a different threshold value is set according to the number of microphones. However, a predetermined fixed threshold value may be set.

(4) In the above-described embodiment, the compression control information and howling suppression information corresponding to the number of microphones is stored in the storage unit 13 in advance. However, the compression control information and howling suppression information are determined in advance. Only the reference values are stored, and the compression control information and howling suppression information using a predetermined arithmetic expression, such as adding or multiplying each reference value by the amount of change in the compression control information and howling suppression information according to the number of microphones. May be requested.

(5) In the above-described embodiment, the compression control information and howling suppression information corresponding to the number of microphones is stored in the storage unit 13, but in addition to the number of microphones, for example, the karaoke apparatus 1 is installed. You may make it memorize | store the compression control information and howling suppression information according to the acoustic transfer characteristic of the room which has been. In this case, the acoustic transmission characteristics for each room in which the karaoke apparatus 1 is provided are measured in advance, and the acoustic transmission characteristics corresponding to the room in which the karaoke apparatus 1 is provided and the compression control information and howling corresponding to the number of microphones. The suppression information is instructed to the compressor 106 and the howling suppression unit 107.

(6) In the above-described embodiment, when the howling suppression unit 107 detects that howling occurs in a plurality of different frequency components, if the plurality of howling frequencies are in the vicinity of a certain range, the plurality of howling frequencies. May be attenuated by one notch filter. For example, among the components of three different howling frequencies f1, f2, and f3 (f1 <f2 <f3), if the howling frequencies f1 and f2 are within a certain range, the Q value is reduced to include the howling frequencies f1 and f2. A frequency component is attenuated by a notch filter.

(7) In the above-described embodiment, the microphone 10 is configured not to transmit the operation signal indicating the operation of switching the on / off switch to the audio signal processing unit 16, but the operation signal for switching on / off is the audio signal processing unit 16. In the case of the microphone 10 having a configuration capable of outputting to the microphone, the microphone detection unit 103 may be configured to detect the number of microphones in the operating state based on an operation signal from the microphone 10. The microphone 10 may be a microphone that requires a power source provided with a switch for switching on and off the power source.

(8) In the above-described embodiment, the music data is stored in the storage unit 13. However, the karaoke device 1 is provided with a communication unit, and the music data is acquired from an external device connected via a communication line. The music data stored in a recording medium such as an optical disk may be acquired and played back.

DESCRIPTION OF SYMBOLS 1 ... Karaoke apparatus, 10 ... Microphone, 11 ... Control part, 12 ... Operation part, 13 ... Memory | storage part, 14 ... Sound source part, 15 ... Display part, 16. ..Audio signal processing unit, 101... Preamplifier, 102... A / D conversion unit, 103... Microphone detection unit, 104. ..Compressor, 107... Howling suppression section, 108... Mixer, 109... D / A conversion section, 110.

Claims (3)

Detection means for detecting the number of microphones in an operating state based on the signal level of the sound signal input from each microphone;
Storage means for storing compression control information that predetermines a compression mode for the sound signal according to the number of microphones in an operating state;
The compression control information corresponding to the number of microphones in the operation state detected by the detection unit is read from the storage unit, and a sound obtained by mixing all sound signals output from the microphones in the operation state detected by the detection unit Compression means for compressing the audio signal according to the read compression control information when the signal level of the signal exceeds a predetermined threshold;
An output means for outputting the audio signal compressed by the compression means. Howling detection means for analyzing the frequency component of the audio signal compressed by the compression means and detecting a frequency component causing howling;
Attenuation amount storage means for storing the attenuation amount of the audio signal in accordance with the number of microphones in an operating state;
Attenuation amount corresponding to the number of microphones in the operating state detected by the detection means is read from the attenuation amount storage means, and howling frequency components detected by the howling detection means are read according to the read attenuation amount. A howling suppression means for damping,
2. The sound signal output control apparatus according to claim 1, wherein the output means outputs the sound signal that has been subjected to attenuation processing by the howling suppression means. The threshold value is a predetermined threshold value according to the number of microphones in the operating state,
The compression control information includes a first time from when the audio signal exceeds the threshold to compression, a second time from when the audio signal again falls below the threshold to stop compression, Containing information indicating the percentage of
The compression means is based on the compression control information according to the number of microphones detected by the detection means, and after the first time has elapsed from the time when the audio signal exceeds the threshold, the compression ratio is determined according to the compression ratio. The sound signal according to claim 1 or 2, wherein the sound signal is compressed, and the compression of the sound signal is stopped when the second time has elapsed from the time when the sound signal becomes equal to or less than the threshold value. Output control device.

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