JP2019020277A - Audio calibrator - Google Patents

Abstract

To provide a portable type and relatively small sized audio calibrator for suppressing a calibration error due to vibrations of camera shake of a user, wind, and temporary environmental noises.SOLUTION: A reference sound signal generation part 4 generates a reference sound signal for sound calibration by a predetermined reference frequency. A speaker 1 emits a reference sound for sound calibration based on the reference sound signal. A reference microphone 3 generates a microphone detection signal corresponding to the reference sound. A filter part 8 extracts a reference frequency component from the microphone detection signal. An effective value processing part 9 comprises a square arithmetic part 9a for raising the first detecting signal to the second power at the subsequent stage of the filter part 8 and a low-pass filter 9b of the predetermined time constant and generates a second detection signal. A reference sound signal generation part 4 adjusts a level of the reference sound signal at a predetermined second time interval based on the second detection signal level.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an acoustic calibrator.

  In order to manage the accuracy of an acoustic measuring instrument such as a sound level meter that uses a microphone, acoustic calibration of the microphone is performed. An acoustic calibrator is used for such acoustic calibration. For example, at the time of acoustic calibration, the microphone of the acoustic measuring device is arranged in the coupler, and the acoustic calibrator emits a reference sound having a predetermined sound pressure in the coupler for acoustic calibration.

  Some acoustic calibrators perform sound pressure control according to atmospheric pressure (see, for example, Patent Document 1).

  Another acoustic calibrator includes a reference microphone in a coupler, and performs sound pressure feedback control based on the output of the reference microphone (see, for example, Patent Document 2).

  Yet another acoustic calibrator emits a reference sound in the coupler with the generated sound pressure signal and is generated from the sound pressure measured by the gauge pressure sensor using FFT (Fast Fourier Transformation) or DFT (Discrete Fourier Transformation) The frequency level of the sound pressure signal is extracted, and sound pressure feedback control is performed (see, for example, Patent Document 3). Thereby, the self-noise of the sensor is suppressed.

JP 2001-349773 A JP 2008-256433 A JP 2014-240761 A

  In the feedback control type acoustic calibrator, when the vibration of the user's hand shake or temporary environmental noise is received by the reference microphone, the sound pressure of the reference sound fluctuates greatly, and the acoustic calibration of the acoustic measuring instrument is performed. May not be performed accurately.

  In addition, when the sound pressure level having the same frequency as that of the reference sound is extracted using FFT or DFT as in the above-described acoustic calibrator, frequency components other than the frequency of the reference sound are removed. However, since a large-scale operation is required for FFT or DFT with effective accuracy, and power consumption is also increased, it is not practical for a portable and relatively small acoustic measuring instrument.

  The present invention has been made in view of the above problems, and is a portable and relatively compact device that suppresses calibration errors of an acoustic measuring instrument caused by vibrations of the user's hand shake, wind, and temporary environmental noise. The purpose is to obtain an acoustic calibrator.

  An acoustic calibrator according to the present invention includes a reference sound signal generation unit that generates a reference sound signal for sound calibration at a predetermined reference frequency, a speaker that emits a reference sound for sound calibration based on the reference sound signal, and a reference sound. A reference microphone that generates a corresponding microphone detection signal, a filter unit that extracts a reference frequency component from the microphone detection signal to generate a first detection signal, and a first detection signal that is squared after the filter unit 2 An effective value processing unit that includes a multiplication operation unit and a low-pass filter having a predetermined time constant and generates a second detection signal. The reference sound signal generation unit adjusts the level of the reference sound signal at predetermined time intervals based on the level of the second detection signal.

  According to the present invention, it is possible to obtain a portable and relatively small acoustic calibrator that suppresses calibration errors of the acoustic measuring instrument caused by vibrations of the user's hand shake, wind, and temporary environmental noise.

FIG. 1 is a block diagram showing a configuration of an acoustic calibrator according to an embodiment of the present invention. FIG. 2 is a flowchart for explaining the operation of the acoustic calibrator shown in FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a block diagram showing a configuration of an acoustic calibrator according to an embodiment of the present invention.

  The acoustic calibrator shown in FIG. 1 emits a reference sound with a predetermined reference sound pressure at a predetermined reference frequency for the purpose of acoustic calibration of an acoustic measuring instrument such as a sound level meter. 1 includes a speaker 1, a coupler 2, a reference microphone 3, a reference sound signal generation unit 4, a digital / analog converter (hereinafter referred to as DAC) 5, a preamplifier 6, and an analog / digital converter (hereinafter referred to as ADC). ) 7, a filter unit 8 and an effective value processing unit 9.

  The speaker 1 emits a reference sound for acoustic calibration into the coupler 2 based on a reference sound signal having a predetermined reference frequency. The coupler 2 has a shape in which the microphone 101 of the acoustic measuring device can be inserted and removed, and forms an internal space. At the time of acoustic calibration of the acoustic measuring instrument, the acoustic measuring instrument receives and measures the reference sound emitted from the speaker 1 in the inner space of the coupler 2 with the microphone 101, and calibrates so that the measured sound pressure level becomes the reference value. .

  The reference microphone 3 receives the reference sound from the speaker 1 in the inner space of the coupler 2 and generates a microphone detection signal corresponding to the reference sound.

  The reference sound signal generation unit 4 generates a reference sound signal for sound calibration at a predetermined reference frequency. For example, the reference sound signal generation unit 4 generates a reference sound signal having a reference sound pressure of 94 dBspl at a reference frequency of 1 kHz. Here, the reference sound signal is a single-frequency sine wave signal.

  The DAC 5 converts a reference sound signal as a digital signal into an analog signal and outputs the analog signal to the speaker 1 through an amplifier (not shown).

  The preamplifier 6 is an analog circuit that performs impedance conversion and filtering on the microphone detection signal generated by the reference microphone 3.

  The ADC 7 converts the microphone detection signal as an analog signal into a digital signal and outputs the digital signal to the filter unit 8.

  The filter unit 8 is a digital filter, and extracts the above-described reference frequency component to generate a first detection signal.

  For example, in this embodiment, the filter unit 8 has a high-pass filter 8a that attenuates a low-frequency component of the microphone detection signal at a cutoff frequency lower than the above-described reference frequency, and a band that passes the component of the reference frequency in the microphone detection signal. The high-pass filter 8a and the band-pass filter 8b are connected in a column. In FIG. 1, the bandpass filter 8b is a subsequent stage of the highpass filter 8a, but the highpass filter 8a may be a subsequent stage of the bandpass filter 8b.

  For example, when the reference frequency is 1 kHz, the cut-off frequency of the high-pass filter 8a is set to 470 Hz, which is used for removing noise components caused by hand vibration or wind noise. The pass band of the band pass filter 8b includes 1 kHz.

  The effective value processing unit 9 squares the first detection signal by the square calculation unit 9a after the filter unit 8, extracts the energy component (DC component) by the low-pass filter 9b having a predetermined time constant, Two detection signals are generated. Here, square root processing (not shown) in normal effective value processing is omitted, but square root processing may be provided.

  For example, when a user accidentally generates a vibration, a vibration of about several tens to several hundreds of ms is applied in many cases. If the amplitude of the sine wave of the reference sound is changed without waiting for convergence of such sudden noise (temporary noise caused by hand vibration, wind, temporary environmental noise, etc.), an error in the generated sound pressure level will occur. Connected. The predetermined time interval for adjusting the level of the reference sound signal based on the level of the second detection signal is preferably adjusted in a range from 256 milliseconds (ms) to 1000 milliseconds (ms). Here, by setting the predetermined time interval to 256 ms, it is possible to reduce the influence caused by the fluctuation of the sound pressure level at which sudden noise occurs.

  The time constant of the low-pass filter 9b is set to a time equal to or less than half of the predetermined time interval, and is, for example, 128 ms. This time interval is determined according to the response time of the effective value processing, the convergence time of sudden noise, and the like.

  Then, the reference sound signal generation unit 4 adjusts the level of the reference sound signal for each predetermined time interval based on the level of the second detection signal generated by the effective value processing unit 9, and the speaker 1 The output sound pressure is set to the reference sound pressure.

  In this embodiment, the DAC 5, ADC 7, and filter unit 8 are each part of an audio codec IC (Integrated Circuit) 11. The reference sound signal generation unit 4 and the effective value processing unit 9 are realized by a processor 12 such as a low power consumption microcomputer for an embedded system. The preamplifier 6, the audio codec IC 11, and the processor 12 operate using a built-in battery (primary battery or secondary battery) (not shown) as a power source. By using the filter unit 8 and the effective value processing unit 9 as described above, it is possible to suppress the influence of sudden noise with signal processing with a smaller amount of calculation compared to FFT, DFT, and the like. Further, the processor 12 with low power consumption can be adopted, and the influence of sudden noise can be suppressed in a portable and small acoustic calibrator.

  Next, the operation of the acoustic calibrator will be described. FIG. 2 is a flowchart for explaining the operation of the acoustic calibrator shown in FIG.

  For example, the microphone 101 of the acoustic measuring device is directed upward, inserted into the acoustic calibrator, and the microphone 101 of the acoustic measuring device is disposed in the inner space of the coupler 2. When acoustic calibration is started in a state where the microphone 101 of the acoustic measuring device is disposed in the inner space of the coupler 2, the reference sound signal generation unit 4 first sets the output sound pressure level as a predetermined initial value ( Step S1), generation of a reference sound signal having a reference frequency is started (Step S2).

  The reference sound signal is supplied to the speaker 1 via the DAC 5 or the like, and the reference sound is emitted from the speaker 1 into the coupler 2. When the reference sound is received by the reference microphone 3, the reference microphone 3 outputs a microphone detection signal. The microphone detection signal is output to the filter unit 8 via the preamplifier 6 and the ADC 7. In the filter unit 8, the high-pass filter 8a attenuates the frequency component below the cutoff frequency in the microphone detection signal, and the band-pass filter 8b attenuates the frequency component other than the reference frequency in the microphone detection signal. Is generated.

  Then, the first detection signal is output to the subsequent effective value processing unit 9 through a predetermined interface. In the effective value processing unit 9, the first detection signal is squared by the square calculation unit 9a and a DC component is extracted by the low-pass filter 9b to generate a second signal for effective value conversion.

  The reference sound signal generation unit 4 monitors whether or not a measurement time corresponding to a predetermined time interval has elapsed after setting the output sound pressure level (step S3), and when the measurement time has elapsed, the reference sound signal generation unit 4 adjusts the level of the reference sound signal based on the level of the second detection signal that has passed through the low-pass filter 9b so that the output sound pressure of the speaker 1 becomes the reference sound pressure (step S4). That is, the reference sound signal generation unit 4 adjusts the level of the reference sound signal so that the level of the second detection signal becomes a value corresponding to the reference sound pressure. The reference sound signal generator 4 continues to generate and output the reference sound signal at that level, and the reference sound is emitted from the speaker 1 at the adjusted output sound pressure level (step S2).

  Thereafter, the output sound pressure level of the reference sound is adjusted every time the measurement time elapses. Even if there is an influence due to sudden noise, since the output sound pressure level of the reference sound is adjusted based on the level of the second detection signal at that time, the next measurement time, No sudden noise effects remain.

  In this way, the reference sound is continuously generated in the coupler 2, and the acoustic measuring device receives the reference sound and performs calibration. Thereby, the acoustic calibration of the acoustic measuring device is performed while suppressing the influence of sudden noise.

  As described above, according to the above-described embodiment, the reference sound signal generation unit 4 generates a reference sound signal for sound calibration at a predetermined reference frequency, and the speaker 1 is used for sound calibration based on the reference sound signal. A reference sound is emitted. The reference microphone 3 generates a microphone detection signal corresponding to the reference sound. The filter unit 8 extracts a reference frequency component from the microphone detection signal to generate a first detection signal, and the effective value processing unit 9 squares the first detection signal after the filter unit 8. The second detection signal is generated by the unit 9a and the low-pass filter 9b having a predetermined time constant. The reference sound signal generation unit 4 adjusts the level of the reference sound signal at predetermined time intervals based on the level of the second detection signal.

  As a result, even for portable and relatively small acoustic calibrators, calibration of acoustic measuring instruments caused by vibrations and winds of the user's hand in the feedback control of the output sound pressure level, temporary environmental noise, etc. Errors are suppressed.

  Various changes and modifications to the above-described embodiment will be apparent to those skilled in the art. Such changes and modifications may be made without departing from the spirit and scope of the subject matter and without diminishing its intended advantages. That is, such changes and modifications are intended to be included within the scope of the claims.

  For example, in the above embodiment, the preamplifier 6 may include an analog low-pass filter having a cutoff frequency equal to or lower than the reference frequency. For example, this cut-off frequency is set to 300 Hz when the reference frequency is 1 kHz.

  In the above embodiment, the reference sound signal generation unit 4 may further adjust the level of the reference sound signal according to the environmental temperature or the atmospheric pressure using a temperature sensor or an atmospheric pressure sensor.

  The present invention is applicable, for example, to an acoustic calibrator for a sound level meter.

DESCRIPTION OF SYMBOLS 1 Speaker 2 Coupler 3 Reference microphone 4 Reference sound signal production | generation part 8 Filter part 8a High pass filter 8b Band pass filter 9 Effective value process part 9a Square calculation part 9b Low pass filter 11 Audio codec IC

Claims (4)

A reference sound signal generation unit that generates a reference sound signal for acoustic calibration at a predetermined reference frequency;
A speaker that emits a reference sound for sound calibration based on the reference sound signal;
A reference microphone for generating a microphone detection signal corresponding to the reference sound;
A filter unit that extracts a component of the reference frequency from the microphone detection signal and generates a first detection signal;
And an effective value processing unit that generates a second detection signal including a square calculation unit that squares the first detection signal and a low-pass filter having a predetermined time constant, after the filter unit.
The reference sound signal generation unit adjusts the level of the reference sound signal at predetermined time intervals based on the level of the second detection signal;
An acoustic calibrator characterized by   The acoustic calibrator according to claim 1, wherein the predetermined time constant is a time equal to or less than half of the predetermined time interval.   The acoustic calibrator according to claim 1 or 2, wherein the predetermined time interval is any time from 256 milliseconds to 1000 milliseconds. The filter unit is a part of an audio codec IC and passes a high-pass filter that attenuates a low-frequency component of the microphone detection signal at a cutoff frequency lower than the reference frequency, and a component of the reference frequency in the microphone detection signal A band pass filter
The high pass filter and the band pass filter are connected in a column;
The acoustic calibrator according to any one of claims 1 to 3, wherein:

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