JP2013167555A - Acoustic measuring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To represent a two-dimensional distribution of sound pressure as an image for only a sound component generated by vibration on the surface of a measuring object included in a sound emitted from the measuring object.SOLUTION: A two-dimensional distribution (d) of correlation between sound pressure and vibration is calculated from a two-dimensional distribution of sound pressure (a) and a two-dimensional distribution of vibration on the surface of a measuring object (b). Among images in which a sound pressure distribution is represented as an image, an image in which drawing density of an area where correlation having less than a predetermined value is detected is the minimum density is created; and an image (f) obtained by overlapping the created image on a camera photographic image (c) is created and displayed as a sound pressure distribution image.

Description

  The present invention relates to an acoustic measurement device that measures a two-dimensional distribution of sound.

As an acoustic measurement device that measures a two-dimensional distribution of sound, an acoustic measurement device that measures a two-dimensional distribution of sound pressure measured using a microphone array and visualizes the two-dimensional distribution of sound pressure is known. (For example, Patent Document 1).
A laser Doppler vibrometer that measures a two-dimensional distribution of vibration by scanning a laser is also known (for example, Patent Document 2).

Japanese Patent Laid-Open No. 06-113387 Japanese Unexamined Patent Publication No. 2004-17001

Sound emitted from an object having an internal structure includes a sound component generated by vibration of the surface of the object and a sound component leaked outside by air vibration generated inside the object. There is.
In such a case, since the two-dimensional distribution of sound pressure measured by the above technique represents the sound pressure distribution of the entire sound emitted from the object, the sound generated by the vibration of the surface of the object The sound pressure distribution and the sound pressure distribution of the sound generated inside the object and leaking outside due to air vibration cannot be discriminated and grasped.

In this case, the location of the sound source of the sound generated from the object cannot be specified only from the two-dimensional distribution of the measured sound pressure. This is an effective sound / vibration measure. May be an obstacle to the implementation.
Therefore, according to the present invention, a sound emitted from an object includes a sound component generated by vibration of the surface of the object and a sound component generated inside the object and leaked to the outside by air vibration. In this case, it is an object to make it possible to measure a two-dimensional distribution for each component of sound.

  In order to achieve the above object, the present invention provides an acoustic measurement device for measuring a two-dimensional distribution of sound, a sound distribution calculating means for calculating a two-dimensional distribution of sound generated from the measurement object, and a surface of the measurement object. Vibration distribution calculating means for calculating the two-dimensional distribution of vibration, correlation distribution calculating means for calculating the two-dimensional distribution of the correlation between sound and vibration, and sound pressure distribution imaging means.

Here, the sound pressure distribution imaging means represents a two-dimensional distribution only for a sound for which a correlation of a predetermined level or more with the vibration is calculated based on the two-dimensional distribution of the sound and the two-dimensional distribution of the correlation. An image is generated.
According to such an acoustic device, it is possible to extract only the sound that is surely caused by the vibration of the surface of the measurement object and calculate the two-dimensional distribution.
Here, the sound pressure distribution imaging means described above represents an image representing a two-dimensional distribution of values obtained by weighting the sound by the strength of the correlation based on the two-dimensional distribution of the sound and the two-dimensional distribution of the correlation. It may be generated.
By doing in this way, only the sound component resulting from the vibration of the surface of the measuring object can be extracted, and its two-dimensional distribution can be calculated.
Alternatively, the sound pressure distribution imaging means described above can obtain a two-dimensional distribution only for a sound for which a correlation of less than a predetermined level with the vibration is calculated based on the two-dimensional distribution of the sound and the two-dimensional distribution of the correlation. An image to represent may be generated.
By doing so, it is possible to extract only the sound originating from the sound source inside the measurement object and calculate its two-dimensional distribution.
Alternatively, the sound pressure distribution imaging means generates an image representing a two-dimensional distribution of values obtained by weighting the sound by the weakness of the correlation based on the two-dimensional distribution of the sound and the two-dimensional distribution of the correlation. It is good also as what to do.
By doing so, it is possible to extract only the sound component caused by the sound source inside the measurement object and calculate its two-dimensional distribution.
The above acoustic measurement apparatus may further include a correlation distribution imaging unit that generates an image representing the two-dimensional distribution of the correlation.
In the acoustic measurement apparatus, it is preferable to use sound and vibration coherence as the correlation between the sound and vibration.

  As described above, according to the present invention, the sound component generated by the vibration of the surface of the object and the sound generated inside the object and leaked outside by the air vibration are added to the sound emitted from the object. When a component is included, a two-dimensional distribution for each component of sound can be measured.

It is a block diagram which shows the structure of the acoustic measuring device which concerns on embodiment of this invention. It is a figure which shows the state of the measurement of the acoustic measuring device which concerns on embodiment of this invention. It is a figure which shows the operation example of the acoustic measuring device which concerns on embodiment of this invention.

Hereinafter, embodiments of the present invention will be described.
In FIG. 1, the structure of the acoustic measuring device which concerns on this embodiment is shown.
As shown in the figure, the acoustic measurement device includes a camera 1, a microphone array 2, a vibration meter 3, an audio signal FET 4, a vibration signal FET 5, a sound pressure distribution calculation unit 6, a correlation calculation unit 7, a sound pressure distribution image generation unit 8, and a display device. 9, a control device 10, and an operation unit 11.
Here, FIG. 2 a shows the arrangement of the camera 1, the microphone array 2, and the vibrometer 3 when measuring the sound pressure distribution.
The camera 1, the microphone array 2, and the vibrometer 3 at the time of measurement observe the measurement object 100 in the Z direction on the assumption that an XYZ coordinate system is set as shown in the figure.
That is, the camera 1 images the measurement object 100 in the Z direction. The microphone array 2 collects sounds coming from the Z direction with a plurality of microphones arranged in the XY directions. The vibrometer 3 is a vibrometer that measures the vibration of the surface of the measurement object 100 at a plurality of points different in the XY directions, such as a laser scanning laser Doppler vibrometer.

Returning to FIG. 1, the audio signal FET 4 calculates the power spectrum of the sound collected by each microphone of the microphone array 2. Further, the sound pressure distribution calculation unit 6 calculates the sound pressure distribution from the power spectrum of each microphone by a beam former method or the like.
Here, in this embodiment, as shown in FIG. 2b, a plurality of blocks obtained by dividing a two-dimensional space in which an image photographed by the camera 1 is defined into a plurality of vertical and horizontal directions are set. For each block, the distribution calculation unit 6 calculates the power spectrum of the sound coming from the direction reflected in the block and sets this as the sound pressure distribution.

On the other hand, the vibrometer 3 is set for each block so as to measure the vibration of a point located on the surface of the measurement object 100 in the direction reflected in the block.
The vibration signal FET5 calculates a power spectrum of vibration measured by the vibrometer 3 for each block, and uses this as a vibration distribution.
Next, the correlation calculation unit 7 calculates, for each block, the correlation between the sound distributed in the block and the vibration distributed in the block at each frequency.
Here, as this correlation, for example, coherence Coh (f) represented by the following equation (1) can be used.

Here, f is the frequency, GAA (f) is the vibration power spectrum, GBB (f) is the sound power spectrum, and GBA (f) is the vibration-sound cross spectrum.
Here, the coherence Coh (f) takes a value from 0 to 1, and when Coh (f) = 1, it represents that all the sounds are caused by vibration with respect to the frequency f, and Coh (f) = When it is 0, it represents that all the sounds are not caused by vibration with respect to the frequency f. In addition, when 0 <Coh (f) <1, the frequency f indicates that the sound is caused by vibration and represents a certain ratio.

The sound pressure distribution image generation unit 8 then displays the sound pressure distribution in the frequency band instructed to display the sound pressure distribution by the user via the operation unit 11 according to the control of the control device 10 in the display mode instructed by the user. A sound pressure distribution image is generated and displayed on the display device 9.
Here, for example, a normal display mode, an internal sound mask mode, a surface sound correlation mode, a surface sound mask mode, an internal sound correlation mode, a correlation value mode, and the like are provided as display modes.
Here, each block obtained from the sound pressure distribution calculated by the sound pressure distribution calculation unit 6 is imaged as power of the frequency band instructed to be displayed or a value obtained by converting the power into a decibel value as a drawing density of each block. Suppose that the image is that shown in FIG. As the power in the frequency band, the sum of the power of each frequency component in the frequency band indicated by the power spectrum is used.

  Further, it is assumed that the image shown in FIG. 3B is an image obtained by replacing each block obtained from the vibration distribution calculated by the vibration signal FET5 with the power of the frequency band instructed to be displayed by the drawing density of each block.

Further, it is assumed that an image taken by the camera 1 is as shown in FIG.
In addition, the coherence of each block in the frequency band instructed to be displayed, calculated by the correlation calculation unit 7 from the sound pressure distribution in FIG. 3a and the vibration distribution in FIG. 3b, is as shown in FIG. 3d. In addition, as the coherence of a frequency band, the average of the coherence of each frequency component in the frequency band is used.

In this case, when the normal display mode is instructed, the sound pressure distribution image generation unit 8 displays an image obtained by superimposing the image obtained by imaging the sound pressure distribution shown in FIG. 3a on the camera-captured image of FIG. The sound pressure distribution image is generated and displayed on the display device 9 as shown in FIG.
Next, when the internal sound mask mode is instructed, the sound pressure distribution image generation unit 8 has a coherence of less than a predetermined value (here, less than 0.8) in the image obtained by imaging the sound pressure distribution shown in FIG. 3) is generated as a sound pressure distribution image as shown in FIG. 3f, and an image obtained by superimposing the generated image on the camera photographed image of FIG. indicate.

  Next, when the surface sound correlation mode is instructed, the sound pressure distribution image generation unit 8 shows the drawing density of each block of the image obtained by imaging the sound pressure distribution shown in FIG. As shown in FIG. 3g, an image in which the value weighted with the calculated coherence intensity is used as the drawing density of the block is generated, and the generated image is superimposed on the camera-captured image of FIG. 3c. A sound pressure distribution image is generated and displayed on the display device 9.

Here, the drawing density of each block is weighted by the coherence intensity, for example, by multiplying the drawing density of the block by the coherence value of the block. That is, assuming that the drawing density of the i-th block on the sound pressure distribution shown in FIG. 3a is Di, and the coherence of the i-th block on the coherence distribution shown in FIG. Let WDi be WDi = Di × Ci.
Next, when the surface sound mask mode is instructed, the sound pressure distribution image generation unit 8 has a coherence of more than a predetermined value (here, more than 0.2) in the image obtained by imaging the sound pressure distribution shown in FIG. ) Is generated as a sound pressure distribution image as shown in FIG. 3h, and an image obtained by superimposing the generated image on the camera photographed image of FIG. indicate.

  Next, when the internal sound correlation mode is instructed, the sound pressure distribution image generation unit 8 shows the drawing density of each block of the image obtained by imaging the sound pressure distribution shown in FIG. As shown in FIG. 3i, an image in which the value weighted by the weakness of the coherence calculated as described above is used as the drawing density of the block is generated, and the generated image is superimposed on the camera photographed image of FIG. 3c. A sound pressure distribution image is generated and displayed on the display device 9. Here, the weighting by the weakness of the coherence of the drawing density of each block is performed, for example, by multiplying the drawing density by a value obtained by subtracting the coherence from 1. That is, assuming that the drawing density of the i-th block on the sound pressure distribution shown in FIG. 3a is Di, and the coherence of the i-th block on the coherence distribution shown in FIG. Is WDi, and WDi = Di × (1-Ci).

  Then, when the correlation value mode is instructed, the sound pressure distribution image generation unit 8 generates and generates an image in which the drawing density corresponding to the coherence of each part lock shown in FIG. An image obtained by superimposing the image on the camera-captured image of FIG. 3c is generated as a sound pressure distribution image and displayed on the display device 9 as shown in FIG. 3j.

The embodiment of the present invention has been described above.
In the present embodiment, instead of the microphone array 2, a microphone with a variable directivity can be used.

  DESCRIPTION OF SYMBOLS 1 ... Camera, 2 ... Microphone array, 3 ... Vibrometer, 4 ... Sound signal FET, 5 ... Vibration signal FET, 6 ... Sound pressure distribution calculation part, 7 ... Correlation calculation part, 8 ... Sound pressure distribution image generation part, 9 ... Display device, 10... Control device, 11.

Claims (6)

An acoustic measurement device that measures a two-dimensional distribution of sound,
A sound distribution calculating means for calculating a two-dimensional distribution of sound generated from the measurement object;
A vibration distribution calculating means for calculating a two-dimensional distribution of vibrations on the surface of the measurement object;
A correlation distribution calculating means for calculating a two-dimensional distribution of the correlation between sound and vibration;
Sound pressure distribution imaging means for generating an image representing a two-dimensional distribution only for a sound for which a correlation of a predetermined level or more with the vibration is calculated based on the two-dimensional distribution of the sound and the two-dimensional distribution of the correlation; An acoustic measurement device comprising: An acoustic measurement device that measures a two-dimensional distribution of sound,
A sound distribution calculating means for calculating a two-dimensional distribution of sound generated from the measurement object;
A vibration distribution calculating means for calculating a two-dimensional distribution of vibrations on the surface of the measurement object;
A correlation distribution calculating means for calculating a two-dimensional distribution of the correlation between sound and vibration;
Sound pressure distribution imaging means for generating an image representing a two-dimensional distribution of values obtained by weighting the sound with the strength of the correlation based on the two-dimensional distribution of the sound and the two-dimensional distribution of the correlation. An acoustic measurement device. An acoustic measurement device that measures a two-dimensional distribution of sound,
A sound distribution calculating means for calculating a two-dimensional distribution of sound generated from the measurement object;
A vibration distribution calculating means for calculating a two-dimensional distribution of vibrations on the surface of the measurement object;
A correlation distribution calculating means for calculating a two-dimensional distribution of the correlation between sound and vibration;
Sound pressure distribution imaging means for generating an image representing a two-dimensional distribution only for a sound for which a correlation of less than a predetermined level with the vibration is calculated based on the two-dimensional distribution of the sound and the two-dimensional distribution of the correlation; An acoustic measurement device comprising: An acoustic measurement device that measures a two-dimensional distribution of sound,
A sound distribution calculating means for calculating a two-dimensional distribution of sound generated from the measurement object;
A vibration distribution calculating means for calculating a two-dimensional distribution of vibrations on the surface of the measurement object;
A correlation distribution calculating means for calculating a two-dimensional distribution of the correlation between sound and vibration;
Sound pressure distribution imaging means for generating an image representing a two-dimensional distribution of values obtained by weighting the sound with the weakness of the correlation based on the two-dimensional distribution of the sound and the two-dimensional distribution of the correlation. An acoustic measurement device. The acoustic measurement device according to claim 1, 2, 3 or 4,
An acoustic measurement apparatus comprising correlation distribution imaging means for generating an image representing the two-dimensional distribution of the correlation. The acoustic measurement device according to claim 1, 2, 3, 4 or 5,
A sound measurement apparatus using sound and vibration coherence as the correlation between the sound and vibration.