JPH09247787A - Sound field control system - Google Patents

Abstract

(57) [Abstract] [Problem] By obtaining information such as howling margin and frequency characteristics necessary for designing a sound field control system by measurement and automatically optimizing the system configuration,
(EN) Provided is an excellent sound field control system in which howling is unlikely to occur and deterioration in tone color is small. SOLUTION: A signal from a signal generator 114 is emitted as an acoustic signal from a speaker 116 via an acoustic adjuster 105. The acoustic signal is input from the microphone 102 and recorded in the recorder 113. The controller 112 calculates a transfer function based on the information of the recorder 113. The speaker 116 and the microphone 1 while switching the switch 109 and the switch 110.
The transfer function including the feedback system is measured for each of the 02 combinations. The controller 112 sends the value to be set to the mixing setting device 118, and the mixing setting 117 is performed in the mixer 104.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sound field control system using electroacoustic equipment.

[0002]

2. Description of the Related Art Conventionally, a sound field control system using electroacoustic equipment is described in JP-A-60-248099. FIG. 4 is a block diagram showing a configuration of a sound field control system according to a conventional example. In FIG. 4, 201 is a sound field, and a plurality of microphones 202 and a plurality of speakers 20 are included.
9 are arranged. The output of the microphone 202 is the amplifier 20.
3 is input to the mixer 204. The output of the mixer 204 is input to the acoustic adjustment device 205, subjected to processing such as changing frequency characteristics and addition of reverberation sound, input to the howling detection device 206, and further to howling suppression device 207.
Is input to The output of the howling suppressor 207 is input to the amplifier 208 and further to the speaker 209.

Next, the operation of the conventional example having the above configuration will be described. In the sound field 201, the acoustic signal is a microphone 202
To enter. The output of the microphone 202 is input to the mixer 204 via the amplifier 203. In the mixer 204, the input signals are amplified, mixed, and output. The output from the mixer 204 is input to the acoustic adjustment device 205, and undergoes processing such as changing frequency characteristics and adding reverberant sound. Further, howling detection apparatus 206 checks whether or not howling is occurring, and when howling occurs, howling suppressing apparatus 207 attenuates the signal at the frequency at which howling is occurring. The output of the howling suppression device 207 is input to the amplifier 208, and the speaker 20
The sound signal is emitted from 9 to the sound field 201.

In this way, even in the conventional sound field control system, the sound field can be controlled and the characteristics of the sound field can be changed. Further, even when howling occurs, howling can be suppressed for the time being.

[0005]

However, in the above-mentioned conventional sound field control system, the configuration of the system determined by the combination of the microphone and the speaker is determined at the time of designing, so at the time of adjustment, the combination of a plurality of microphones and speakers is combined. Of these, we do not know how likely each combination is to howling. Therefore, even if only one set of the combination of the microphone and the speaker is likely to generate howling, it is necessary to reduce the gain of the entire system or reduce the amplification factor of a specific frequency throughout the system. For this reason,
Depending on the configuration of the system, there is a problem that the sound field control effect is not sufficiently obtained, or the effect is sufficient but the timbre is deteriorated due to the lack of energy of a specific frequency.

The present invention solves such a conventional problem, and can provide information such as howling margin and frequency characteristics necessary for system design, or automatically optimize the system configuration. Therefore, it is an object of the present invention to provide an excellent sound field control system capable of suppressing howling.

[0007]

A sound field control system according to the present invention comprises means for measuring a transfer function between each microphone and each speaker, and howling margin and frequency necessary for system design using the measured transfer function. A means for calculating information such as characteristics for each combination of a microphone and a speaker, a means for outputting such information to provide to an operator,
Alternatively, it is characterized by being provided with means for automatically changing the mixing setting and the amplification factor using these information. According to the present invention, it is possible to realize a sound field control system capable of suppressing the occurrence of howling by artificially or automatically optimizing the system configuration.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A sound field control system according to claim 1 of the present invention is a means for calculating the state of the system by using a transfer function of a measured or predicted sound field, and howling and deterioration of timbre. It is characterized by having means for automatically changing the system settings when it is predicted that
It has an effect of reducing howling and deterioration of tone color.

The sound field control system according to the second aspect of the present invention calculates the system state for each combination of the microphone and the speaker using the transfer function of the sound field measured or predicted for each combination of the microphone and the speaker. It is characterized by having means and means for automatically changing the system setting when howling or deterioration of tone is predicted, and has an effect of reducing howling or deterioration of tone. .

A sound field control system according to a third aspect of the present invention is means for calculating a feedback amount for each combination of a microphone and a speaker by using a transfer function of a sound field measured or predicted for each combination of a microphone and a speaker. And a means for changing the amplification factor of the combination of the microphone and the speaker to be smaller than the current value when the amount of feedback exceeds the threshold, the effect of reducing howling and deterioration of tone color. Have.

A sound field control system according to a fourth aspect of the present invention is a means for calculating a frequency characteristic for each combination of a microphone and a speaker by using a transfer function of a sound field measured or predicted for each combination of a microphone and a speaker. And a means for correcting the frequency of the combination of the microphone and the speaker when there is a peak or dip in the frequency characteristic that exceeds the threshold, the effect of reducing howling and deterioration of the tone color. Have.

A sound field control system according to a fifth aspect of the present invention calculates a system state for each combination of a microphone and a speaker by using a transfer function of a sound field measured or predicted for each combination of a microphone and a speaker. It is characterized by comprising means and means for outputting in order to provide the calculated system status to the operator, and by the operator recognizing the system status adjusting howling and timbre. It has the effect of reducing deterioration.

According to a sixth aspect of the present invention, the sound field control system according to the first aspect is characterized in that the sound field control system is provided with means for measuring a transfer function of the sound field, and the state of the system can be known. Have an effect.

A sound field control system according to a seventh aspect of the present invention is the sound field control system according to any one of the second to fifth aspects, further comprising means for measuring a transfer function between the microphones for each combination of the microphones. It is characterized in that it has an effect of being able to know the state of the system for each combination of a microphone and a speaker.

A sound field control system according to an eighth aspect of the present invention is the sound field control system according to the seventh aspect, wherein an individual microphone and speaker combination is automatically selected from a plurality of microphone groups and a plurality of speaker groups. It is characterized by including means, and has an effect that the system state can be automatically known for each combination of a microphone and a speaker.

A sound field control system according to a ninth aspect of the present invention is the sound field control system according to any one of the first to third aspects, in which the transfer function of the electroacoustic equipment is measured or predicted in advance for each device and used as information. It is characterized in that it is provided with a means for holding it, and has the effect of reducing the amount of calculation required to calculate the state of the system.

A sound field control system according to a tenth aspect of the present invention is the sound field control system according to any one of the first to third aspects, in which the transfer function of the electroacoustic equipment is measured or predicted in advance for each device. It is characterized by having means for holding information on delay time and frequency characteristics for each
This has the effect of reducing the amount of calculation required to calculate the system state.

Embodiments of a sound field control system according to the present invention will be described below with reference to the drawings.

(Embodiment 1) FIG. 1 is a block diagram showing a configuration of a sound field control system according to Embodiment 1 of the present invention. In FIG. 1, 101 is a sound field, in which a plurality of microphones 102 and a plurality of speakers 116 are arranged. The output of the microphone 102 is an amplifier 103 and a switch 107.
Is input to the mixer 104 via. The output of the mixer 104 is input to the acoustic adjuster 105 via the switch 108, subjected to processing such as frequency characteristic change and reverberation addition, input to the amplifier 106, and further input to the speaker 116. Further, 107, 108, 109 and 110 are switches, which are controlled by the controller 111. The controller 112 controls the recorder 113, the signal generator 114, and the mixing setter 118. The mixing setting device 118 controls the mixing setting 117 in the mixer 104.

Next, the operation of the sound field control system of the first embodiment having the above configuration will be described. The acoustic signal of the sound field 101 is recorded by the microphone 102, amplified by the amplifier 103, and input to the switch 107.

When performing sound field control, the switch 1 is used.
07 is set by the controller 111 so that the signal from the amplifier 103 is input to the mixer 104. Mixer 10
In 4, the input signals are amplified, mixed, and input to the switch 108. When performing sound field control, the switch 108 is set so that the output from the mixer 104 is input to the acoustic adjuster 105 in conjunction with the switch 107. The acoustic adjuster 105 changes the frequency characteristic and adds reverberation sound. The output of the acoustic modulator 105 is the amplifier 106.
Is amplified in the sound field 101 and is emitted as an acoustic signal from the speaker 116 in the sound field 101.

On the other hand, when the measurement is performed, the switch 107 is set by the controller 111 so that the signal from the amplifier 103 is input to the switch 109. The signal generator 114 produces a signal used to measure the transfer function. The generated signal is input to the switch 108 via the switch 110. The switch 108 works in conjunction with the switch 107 when the measurement is performed.
The output from 0 is set to input to the acoustic modulator 105. The acoustic adjuster 105 changes the frequency characteristic and adds reverberation sound. The output of the acoustic adjuster 105 is amplified by the amplifier 106 and emitted as an acoustic signal from the speaker 116 in the sound field 101.

The acoustic signal emitted from the speaker 116 reaches the microphone 102 directly or after being reflected by a wall or the like. The arriving signal is amplified by the amplifier 103 and is recorded by the recorder 113 via the switch 107 and the switch 109. The controller 112 calculates the transfer function based on the information of the recorder 113. The method of measuring the transfer function is preferably a method using a known M-sequence signal, but a known method of repeatedly radiating rectangular pulses or a known method of using a sweep signal may be used. The controller 112 measures the transfer function for each combination of the speaker 116 and the microphone 102 while switching the switch 109 and the switch 110. Further, a transfer function including a feedback system is calculated for each combination of the speaker 116 and the microphone 102. Next, the controller 112 sends the value to be set to the mixing setter 118. The value set in the mixing setter 118 is the amplification factor of each input signal, the mixing ratio of the input signals, the amplification factor of each output signal, the frequency characteristic of each input signal, or the frequency characteristic of each output signal. One or more. Also, the mixing setting device 11
As a method of calculating the value set to 8, the feedback gain is calculated for each combination of the speaker 116 and the microphone 102, and when the feedback amount exceeds the threshold value, the amplification factor of the combination of the speaker 116 and the microphone 102 is calculated. For example, there is a method of reducing only the above, a method of calculating the frequency characteristic for each combination of the speaker 116 and the microphone 102, and correcting the frequency if the frequency characteristic has a peak or a dip exceeding the threshold value. The mixing setting device 118 executes the mixing setting 117 in the mixer 104 as described above.

As described above, according to the first embodiment, a means for measuring the transfer function between each microphone and each speaker is added to the sound field control system, and it is necessary for system design by using the measured or predicted transfer function. Realize a sound field control system that is difficult to howl by calculating information such as howling margin and frequency characteristics for each combination of microphone and speaker, and automatically changing the mixing setting and amplification factor using this information. be able to.

(Second Embodiment) FIG. 2 is a block diagram showing a configuration of a sound field control system according to a second embodiment of the present invention. In FIG. 2, reference numeral 301 denotes a sound field, in which a plurality of microphones 302 and a plurality of speakers 316 are arranged. The output of the microphone 302 is the amplifier 303 and the switch 307.
Is input to the mixer 304 via. The output of the mixer 304 is input to the acoustic adjuster 305 via the switch 308, subjected to processing such as changing frequency characteristics and addition of reverberation sound, input to the amplifier 306, and further input to the speaker 316. Further, 307, 308, 309 and 310 are switches, which are controlled by the controller 311. The controller 312 includes a recorder 313, a signal generator 314, and a display unit 3.
Control 15.

Next, the operation of the sound field control system of the second embodiment having the above configuration will be described. The acoustic signal of the sound field 301 is recorded by the microphone 302, amplified by the amplifier 303, and input to the switch 307.

When performing sound field control, the switch 3 is used.
07 is set by the controller 311 so that the signal from the amplifier 303 is input to the mixer 304. Mixer 30
In 4, the input signal is amplified, mixed, and input to the switch 308. The switch 308 is set so that the output from the mixer 304 is input to the acoustic adjuster 305 in conjunction with the switch 307 when performing sound field control. The acoustic adjuster 305 changes frequency characteristics and adds reverberant sound. The output of the sound conditioner 305 is the amplifier 306.
Is amplified by and is emitted as an acoustic signal from the speaker 316 in the sound field 301.

On the other hand, when the measurement is performed, the switch 307 is set by the controller 311 so that the signal from the amplifier 303 is input to the switch 309. The signal generator 314 generates a signal used to measure the transfer function. The generated signal is input to the switch 308 via the switch 310. The switch 308 works in conjunction with the switch 307 to perform the switch 31 when performing the measurement.
The output from 0 is set to input to the acoustic modulator 305. The acoustic adjuster 305 changes frequency characteristics and adds reverberant sound. The output of the acoustic adjuster 305 is amplified by the amplifier 306 and is emitted as an acoustic signal from the speaker 316 in the sound field 301.

The acoustic signal emitted from the speaker 316 reaches the microphone 302 directly or after being reflected by a wall or the like. The arrived signal is amplified by the amplifier 303, and is recorded by the recorder 313 via the switch 307 and the switch 309. The controller 312 calculates a transfer function based on the information of the recorder 313. The method of measuring the transfer function is preferably a method using a known M-sequence signal, but a known method of repeatedly radiating rectangular pulses or a known method of using a sweep signal may be used. The controller 312 measures the transfer function for each of the combinations of the speaker 316 and the microphone 302 while switching the switch 309 and the switch 310. Furthermore, a transfer function including a feedback system is calculated for each combination of the speaker 316 and the microphone 302. Next, the information necessary for constructing the sound field control system for each combination of the speaker 316 and the microphone 302 is displayed on the display device 315, and this information is provided to the operator. The information necessary for constructing the sound field control system is, for example, the frequency characteristic and the feedback gain. Based on this information, the operator constructs an optimal sound field control system. For example,
Of the combinations of the microphone 302 and the speaker 316, if there is one with a particularly small howling margin, only the amplification factor of the combination can be reduced. Also,
If the combination of the microphone 302 and the speaker 316 has a particularly bad frequency characteristic, the mixer 304 can correct only the frequency characteristic of the combination.

As described above, according to the second embodiment, a means for measuring the transfer function between each microphone and each speaker is added to the sound field control system, and howling necessary for system design is used by using the measured transfer function. Calculate information such as margin and frequency characteristics for each combination of microphone and speaker,
By providing the information to the operator, it is possible to realize a sound field control system in which howling is unlikely to occur.

Instead of displaying the information necessary for constructing the system on the display device, the information may be printed on paper or the like by a printing device or recorded on a recording medium such as a floppy disk.

(Embodiment 3) FIG. 3 is a block diagram showing a configuration of a sound field control system according to Embodiment 3 of the present invention. In FIG. 3, reference numeral 401 denotes a sound field, in which a plurality of microphones 402 and a plurality of speakers 416 are arranged. The output of the microphone 402 is an amplifier 403 and a switch 407.
Is input to the mixer 404 via. The output of the mixer 404 is input to the acoustic adjuster 405, subjected to processing such as frequency characteristic change and addition of reverberation sound, input to the amplifier 406 via the switch 408, and further input to the speaker 416. Further, 407, 408, 409 and 410 are switches, which are controlled by the controller 411. The controller 412 is a recorder 4 connected to the information compressor 413.
19 and the signal generator 414 and the mixing setting device 418 are controlled. Further, the controller 412 can use the information of the recorder 420. The information in the recorder 420 is the transfer function of the acoustic adjuster 405 that has been measured in advance, or information obtained by compressing the information. The mixing setting device 418 controls the mixing setting 417 in the mixer 404.

Next, the operation of the sound field control system of the third embodiment having the above configuration will be described. The acoustic signal of the sound field 401 is recorded by the microphone 402, amplified by the amplifier 403, and input to the switch 407.

When performing sound field control, the switch 4 is used.
07 is set by the controller 411 so that the signal from the amplifier 403 is input to the mixer 404. Mixer 40
In 4, the input signal is amplified, mixed, and input to the acoustic adjuster 405. The acoustic adjuster 405 changes frequency characteristics and adds reverberant sound. The output of the sound adjuster 405 is input to the switch 408. The switch 408 is set so that the output from the acoustic adjustor 405 is input to the amplifier 406 in cooperation with the switch 407 when performing sound field control. The acoustic adjuster 405 changes frequency characteristics and adds reverberant sound. The output of the switch 408 is amplified by the amplifier 406 and is emitted as an acoustic signal from the speaker 416 in the sound field 401.

On the other hand, when performing the measurement, the switch 407 is set by the controller 411 so that the signal from the amplifier 403 is input to the switch 409. The signal generator 414 generates a signal used to measure the transfer function. The generated signal is input to the switch 408 via the switch 410. The switch 408 works in conjunction with the switch 407 to perform the switch 41 when performing the measurement.
The output from 0 is set to enter amplifier 406. The output from the signal generator 414 is amplified by the amplifier 406 and emitted as an acoustic signal from the speaker 416 in the sound field 401. The acoustic signal radiated from the speaker 416 is reflected by a wall or the like directly or by being reflected by a wall or the like.
To reach. The arriving signal is amplified by the amplifier 403,
Information compressor 41 via switch 407 and switch 409
Enter 3 The information compressor 413 compresses the information amount of the transfer function to the extent necessary for optimizing the sound field control. The method may be a method of expressing information as an amplitude for each arbitrary frequency band on the frequency axis. Also, on the time axis, it is desirable to use a method by inverse convolution, a method of extracting a desired number of pulses in the order of the maximum amplitude value, or a method of detecting the maximum amplitude value and increasing the number of taps before and after it. It may be repeated until the number of taps is obtained. The output of the information compressor 413 is recorded in the recorder 419.

The controller 412 includes a recorder 419 and a recorder 4
The transfer function is calculated based on the information of 20. The information in the recorder 420 may be the transfer function of the acoustic adjuster 405 that has been measured in advance, or the information that has been compressed. The method of measuring the transfer function is preferably a method using a known M-sequence signal, but a known method of repeatedly radiating rectangular pulses or a known method of using a sweep signal may be used. The controller 412 measures the transfer function for each combination of the speaker 416 and the microphone 402 while switching the switch 409 and the switch 410. Further, a transfer function including a feedback system is calculated for each combination of the speaker 416 and the microphone 402. Next, the controller 412 sends the value to be set to the mixing setter 418. The value set in the mixing setter 418 includes the amplification factor of each input signal, the mixing ratio of the input signals, the amplification factor of each output signal, the frequency characteristic of each input signal, and the frequency characteristic of each output signal. One or more. In addition, the mixing setting device 41
As a method of calculating the value set to 8, the feedback gain is calculated for each combination of the speaker 416 and the microphone 402, and when the feedback gain exceeds the threshold value, the speaker 416 and the microphone 40 are combined.
The frequency characteristic is calculated for each of the method of reducing only the amplification factor of the combination of 2 and the combination of the speaker 416 and the microphone 402, and if there is a peak or a dip exceeding the threshold value in the frequency characteristic, the frequency is corrected. There are ways. As described above, the mixing setting device 418 causes the mixing setting 417 in the mixer 404.
Execute

As described above, according to the third embodiment, means for measuring the transfer function between each microphone and each speaker is added to the sound field control system, and the measured transfer function and the acoustic control measured in advance are added. A sound field control system that uses feedback functions to calculate howling margins and frequency characteristics required for system design for each combination of microphone and speaker, and automatically optimizes the system configuration to prevent howling Can be realized. In addition, since the transfer function of the sound adjuster 405 which is measured in advance or the information compression thereof is held in the recorder 420, the amount of calculation required to calculate the system state can be reduced. Even in the case where the recorder 420 holds the information on the delay time and the frequency characteristic for each combination of each microphone and each speaker in advance, the amount of calculation required to calculate the system state can be reduced.

[0038]

As described above, according to the present invention, information such as howling margin and frequency characteristics necessary for system design can be provided, or howling can be generated by automatically optimizing the system configuration. The excellent effect of providing an excellent sound field control system capable of suppressing the noise can be obtained.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a sound field control system according to a first embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a sound field control system according to a second embodiment of the present invention.

FIG. 3 is a block diagram showing a configuration of a sound field control system according to a third embodiment of the present invention.

FIG. 4 is a block diagram showing a configuration of a sound field control system according to a conventional technique.

[Explanation of symbols]

 101, 301, 401 ... Sound field 102, 302, 402 ... Microphone 103, 303, 403 ... Amplifier 104, 304, 404 ... Mixer 105, 305, 405 ... Acoustic adjuster 106, 306, 406 ... Amplifier 111, 311, 411 ... Controller 112, 312, 412 ... Controller 113, 313, 419 ... Recorder 413 ... Information compressor 114, 314, 414 ... Signal generator 315 ... Display 116 , 316, 416 ... Speaker 117, 417 ... Mixer setting 118, 418 ... Mixing setting device 420 ... Recording device

Claims (10)

[Claims] 1. A means for calculating the state of a system using a transfer function of a measured or predicted sound field, and a means for automatically changing a system setting when howling or deterioration of a tone color is predicted. A sound field control system comprising: 2. A means for calculating a system state for each combination of a microphone and a speaker by using a transfer function of a sound field measured or predicted for each combination of a microphone and a speaker, and predicting howling and deterioration of timbre. And a means for automatically changing the setting of the system when the sound field control system is operated. 3. A means for calculating a feedback amount for each combination of a microphone and a speaker by using a transfer function of a sound field measured or predicted for each combination of a microphone and a speaker, and when the feedback amount exceeds a threshold value. A sound field control system comprising: means for changing the amplification factor of the combination of the microphone and the speaker to be smaller than the current one. 4. A means for calculating a frequency characteristic for each combination of a microphone and a speaker by using a transfer function of a sound field measured or predicted for each combination of a microphone and a speaker, and a peak or a dip that exceeds a threshold in the frequency characteristic. And a means for correcting the frequency of the combination of the microphone and the speaker when there is a sound field control system. 5. A means for calculating a system state for each combination of a microphone and a speaker by using a transfer function of a sound field measured or predicted for each combination of a microphone and a speaker, and an operator for calculating the calculated system state. And a means for outputting to provide to the sound field control system. 6. The sound field control system according to claim 1, further comprising means for measuring a transfer function of the sound field. 7. The sound field control system according to claim 2, further comprising means for measuring a transfer function between the speaker and the microphone for each combination of the microphone and the speaker. 8. The sound field control according to claim 7, further comprising means for automatically selecting an individual combination of a microphone and a speaker from the plurality of microphone groups and the plurality of speaker groups. system. 9. The sound according to claim 1, further comprising means for measuring or predicting a transfer function of the electro-acoustic equipment in advance for each device and holding the information as information. Field control system. 10. The apparatus according to claim 1, further comprising means for measuring or predicting a transfer function of the electroacoustic equipment in advance for each device and holding information on delay time and frequency characteristic for each device. The sound field control system according to any one of Items 3 to 3.