JP2020183963A - Processing device - Google Patents

Abstract

To provide a processing device capable of preferably detecting a sound flow radiated into an acoustic space.SOLUTION: A processing device (1) comprises: sound detection means (110) for detecting sounds from a sound source (300) at least at 2 points (210, 220); and calculation means (120) configured to perform a calculation concerning propagation direction in which the sounds propagate from the sound source on the basis of the time (T0, T1) when the sounds are detected at least at the 2 points. With the processing device the sound flow radiated into an acoustic space can be easily and intuitively comprehended.SELECTED DRAWING: Figure 6

Description

The present invention relates to, for example, an arithmetic unit and an arithmetic method for performing an arithmetic for visually grasping the flow of sound radiated in an acoustic space, and a technical field of a computer program and a recording medium.

As a means of knowing the localization direction of sound, a technique of visually grasping the flow of sound radiated in an acoustic space is known. For example, Patent Documents 1 and 2 disclose a technique of calculating the radiant energy direction from sound pressure and particle velocity at a plurality of detection points.

Japanese Unexamined Patent Publication No. 2005-236636 Patent No. 5181865

However, in the techniques described in Patent Documents 1 and 2 described above, high sensitivity is required for a device such as a microphone that detects sound. Therefore, in order to detect the flow of sound, it is premised that a dedicated tool is used, for example, which causes technical problems such as an increase in cost.

Examples of the problems to be solved by the present invention include the above. An object of the present invention is to provide an arithmetic unit and an arithmetic method capable of suitably detecting a flow of sound radiated in an acoustic space, and a computer program and a recording medium.

The arithmetic unit that solves the above problems propagates the sound from the sound source based on the sound detecting means that detects the sound from the sound source at at least two places and the time that the sound is detected at each of the at least two places. It is provided with an arithmetic means for executing an arithmetic related to the propagation direction.

The calculation method for solving the above problems is that the sound propagates from the sound source based on a sound detection step of detecting the sound from the sound source at at least two places and the time when the sound is detected at each of the at least two places. It includes a calculation process for executing operations related to the propagation direction.

A computer program that solves the above problems propagates the sound from the sound source based on a sound detection step of detecting the sound from the sound source at at least two places and the time when the sound is detected at each of the at least two places. Have the computer perform an arithmetic process that executes operations related to the propagation direction.

The computer program described above is recorded as a recording medium for solving the above problems.

It is the schematic which shows the whole structure of the arithmetic unit which concerns on 1st Example. It is a conceptual diagram (the 1) which shows the positional relationship of the sound source which concerns on 1st Example, a reference microphone and a peripheral microphone. It is a graph (the 1) which shows the signal detected by the reference microphone and the peripheral microphone which concerns on 1st Example. FIG. 2 is a conceptual diagram (No. 2) showing a positional relationship between a sound source, a reference microphone, and peripheral microphones according to the first embodiment. It is a graph (No. 2) which shows the signal detected by the reference microphone and the peripheral microphone which concerns on 1st Example. It is a conceptual diagram which shows the positional relationship of the sound source which concerns on 2nd Example, the reference microphone and the peripheral microphone. It is a graph which shows the signal detected by the reference microphone and the peripheral microphone which concerns on 2nd Example. It is a conceptual diagram which shows the time difference vector calculated corresponding to each peripheral microphone. It is a conceptual diagram which shows the composition of the time difference vector calculated corresponding to each peripheral microphone. It is a top view which shows the display example in the display part. It is a conceptual diagram which shows the convolution operation which concerns on 3rd Example. It is a conceptual diagram which shows the calculation method of the average value which concerns on 4th Example.

<1>
The arithmetic unit according to the present embodiment propagates the sound from the sound source based on the sound detecting means for detecting the sound from the sound source at at least two places and the time when the sound is detected at each of the at least two places. It is provided with an arithmetic means for executing an arithmetic related to the propagation direction.

According to the arithmetic unit of the present embodiment, during its operation, a sound radiated from a sound source such as a speaker is detected by the sound detecting means. The sound detecting means according to the present embodiment is configured to be able to detect sound at at least two places. Specifically, for example, it is configured so that signals indicating sounds obtained from two or more sound detectors (for example, a microphone or the like) arranged at different positions can be acquired.

The sound detected by the sound detecting means is used for the calculation in the calculation means. The calculation means according to the present embodiment executes a calculation related to the propagation direction in which the sound propagates from the sound source, based on the time when the sound is detected at at least two places. The "calculation related to the propagation direction" here means not only the calculation of data that directly indicates the sound propagation direction, but also the data including the sound propagation direction and the sound pressure and phase at the detection position. The purpose is to include operations such as. In the calculation means, for example, the sound radiated from the sound source is propagated in what direction based on the difference between the time when the sound is detected in one place and the time when the sound is detected in the other place. Is calculated.

According to the above configuration, the propagation direction can be calculated by using the time when the sound is detected at different points (in other words, the propagation direction is calculated if the time when the sound is detected at each place can be accurately known. Therefore, the sound detector is not required to have higher sensitivity than the case where the propagation direction is detected by using, for example, sound pressure or particle velocity. Therefore, the sound propagation direction can be accurately known by a simple process without using an expensive sound detector.

As described above, according to the arithmetic unit according to the present embodiment, it is possible to suitably detect the flow of sound radiated in the acoustic space.

<2>
In one aspect of the arithmetic unit according to the present embodiment, the sound detecting means detects the sound at a reference position and at least one peripheral position located in the vicinity of the reference position, and the arithmetic means determines the sound. Based on the time difference between the reference position and the peripheral position where the sound is detected, the calculation related to the propagation direction at the reference position is executed.

According to this aspect, the sound detecting means detects the sound at the reference position and at least one peripheral position. When the sound is detected at the reference position and the peripheral position, the calculation means calculates the time difference between the time when the sound is detected at the reference position and the time when the sound is detected at the peripheral position. Then, the calculation means further executes a calculation related to the sound propagation direction at the reference position based on the calculated time difference.

According to the above-described configuration, the sound propagation direction at the reference position can be detected based on the difference in the detection time between the reference position and the peripheral position. When two or more peripheral positions are set, the time difference from the time when the sound is detected at the reference position is calculated for each peripheral position. In this case, for example, the time difference vectors for each peripheral position may be combined and used. By increasing the number of peripheral positions, it becomes possible to detect the propagation direction more accurately.

<3>
In the embodiment of detecting sound at the reference position and the peripheral position as described above, the sound detecting means includes the reference position, the first peripheral position and the second peripheral position which are peripheral positions on the same plane as the reference position, and the second peripheral position. Sound is detected at the third peripheral position, which is a peripheral position that is not on the same plane, and the calculation means uses the reference position, the first peripheral position, the second peripheral position, and the third peripheral position. Based on the time difference in which the sound is detected, the calculation related to the propagation direction in three dimensions at the reference position may be performed.

In this case, the sound detecting means detects the sound at the reference position and the first, second, and third peripheral positions. The first peripheral position and the second peripheral position are peripheral positions located on the same plane as the reference position. On the other hand, the third peripheral position is a peripheral position that is not located on the same plane as the plane on which the first and second peripheral positions are located. The peripheral position may be set to other than the first, second, and third peripheral positions, and the time when the sound is detected at the other peripheral positions can be used for the calculation described later.

When the sound is detected at the reference position, the first, second and third peripheral positions, the calculation means detects the time when the sound is detected at the reference position and the sound at the first, second and third peripheral positions. The time difference from the set time is calculated. Then, the calculation means further executes a calculation related to the sound propagation direction at the reference position based on the calculated time difference. Here, particularly in this embodiment, as described above, the first and second peripheral positions are the peripheral positions located on the same plane as the reference position, and the third peripheral position is the first and second peripheral positions. It is set as a peripheral position that is not located on the same plane as the plane. Therefore, the calculation means can calculate the time difference in at least three different directions, and as a result, can execute the calculation in relation to the sound propagation direction in three dimensions.

<4>
In the embodiment in which the sound is detected at the reference position and the peripheral position as described above, the calculation means is based on the time difference between the first peak or the maximum value of the signal indicating the sound detected at each of the reference position and the peripheral position. Then, the calculation related to the propagation direction at the reference position may be executed.

In this case, the sound detection time at the reference position and the peripheral position is compared by the first peak (that is, the peak detected first after the detection is started) or the maximum value. Therefore, even when a plurality of peaks are present in the signal indicating the detected sound, the difference in detection time can be calculated accurately.

<5>
In the embodiment in which the sound is detected at the reference position and the peripheral position as described above, the calculation means applies a sine wave corresponding to a desired frequency to the signal indicating the sound detected at each of the reference position and the peripheral position. A convolution calculation may be performed to perform a calculation related to the propagation direction of a sound having the desired frequency at the reference position.

In this case, by convolving the sine wave corresponding to the desired frequency in advance, the calculation related to the propagation direction of the sound having the desired frequency becomes easy. Specifically, among the sounds detected by the sound detecting means by the convolution calculation, the peak of the signal corresponding to the sound having a desired frequency appears remarkably. Therefore, for example, it becomes easy to calculate the propagation direction using the difference in peak positions.

<6>
In the embodiment in which the sine wave convolution calculation corresponding to the desired frequency is executed as described above, the calculation means is based on the average value of the time difference in which the sound is detected at the reference position and the peripheral position for a predetermined period. An operation related to the propagation direction at the reference position may be performed.

In this case, the time difference in detecting the sound is calculated a plurality of times in a predetermined period (that is, using a plurality of peaks). Then, the calculation related to the propagation direction is executed based on the average value of the plurality of time differences. In this way, when one first peak or maximum value is used for the time difference, the transient propagation direction of the sound radiated into the space can be calculated, whereas the stationary sound radiated into the space is stationary. Sound propagation direction can be calculated.

<7>
In another aspect of the arithmetic unit according to the present embodiment, the arithmetic means measures the sound pressure of the sound detected at each of the at least two locations in addition to the time when the sound is detected at each of the at least two locations. Based on this, the operation related to the propagation direction is executed.

According to this aspect, in addition to the time difference in which the sound is detected, the sound pressure (amplitude) of the detected sound is used in the calculation. Therefore, it is possible to know the loudness of the sound in addition to the propagation direction of the sound, and the information regarding the propagation direction can be calculated as the information including the propagation direction and the loudness of the sound. Therefore, for example, when visualizing information regarding the propagation direction, more appropriate display becomes possible.

<8>
In another aspect of the arithmetic unit according to the present embodiment, the display means for displaying the propagation direction is further provided according to the calculation result by the arithmetic means.

According to this aspect, it is possible to visually grasp the propagation direction calculated by the calculation means.

<9>
In the embodiment further including the display means as described above, the display means may display the propagation direction as a vector.

In this case, since the propagation direction is displayed as a vector, it is possible to grasp the sound flow more intuitively.

<10>
In the calculation method according to the present embodiment, the sound propagates from the sound source based on the sound detection step of detecting the sound from the sound source at at least two places and the time when the sound is detected at each of the at least two places. It includes a calculation process for executing operations related to the propagation direction.

According to the calculation method according to the present embodiment, it is possible to suitably detect the flow of sound radiated in the acoustic space, similarly to the above-mentioned calculation device.

In the calculation method according to the present embodiment, it is possible to adopt various aspects similar to the various aspects in the arithmetic unit according to the above-described embodiment.

<11>
In the computer program according to the present embodiment, the sound propagates from the sound source based on the sound detection step of detecting the sound from the sound source at at least two places and the time when the sound is detected at each of the at least two places. Have the computer perform an arithmetic process that executes operations related to the propagation direction.

According to the computer program according to the present embodiment, it is possible to suitably detect the flow of sound radiated in the acoustic space, similarly to the arithmetic unit and the arithmetic method described above.

In the computer program according to the present embodiment, it is possible to adopt various aspects similar to the various aspects in the arithmetic unit according to the above-described embodiment.

<12>
The computer program according to the present embodiment described above is recorded on the recording medium according to the present embodiment.

According to the recording medium according to the present embodiment, it is possible to suitably detect the flow of sound radiated in the acoustic space by executing the recorded computer program.

Hereinafter, examples of the present invention will be described in detail with reference to the drawings.

<First Example>
First, the configuration of the arithmetic unit 100 according to the first embodiment will be described with reference to FIG. Here, FIG. 1 is a schematic view showing the overall configuration of the arithmetic unit according to the first embodiment.

In FIG. 1, the arithmetic unit 100 according to the first embodiment is configured to include a sound detection unit 110 and an arithmetic unit 120 as main components.

The sound detection unit 110 is an example of the "sound detection means" of the present invention, and inputs a signal indicating the sound detected by the connected reference microphone 210 and the peripheral microphone 220. The reference microphone 210 and the peripheral microphone 220 are configured as, for example, a general microphone or the like, and detect the sound radiated from the sound source 300. The sound detection unit 110 includes an input signal (that is, a signal indicating the sound detected by the reference microphone 210 (hereinafter, appropriately referred to as a “reference microphone signal”) and a signal indicating the sound detected by the peripheral microphone 220 (hereinafter, hereinafter). , Appropriately referred to as “peripheral microphone signal”))) can be output to the calculation unit 120 directly or by performing various processes.

The calculation unit 120 is an example of the “calculation means” of the present invention, and includes a time difference calculation unit 121 and a propagation direction calculation unit 122. The time difference calculation unit 121 compares the reference microphone signal and the peripheral microphone signal input from the sound detection unit 110, calculates the time difference in which the sound is detected in the reference microphone 210 and the peripheral microphone 220, and causes the propagation direction calculation unit 122 to calculate the time difference. Output. The propagation direction calculation unit 122 calculates the propagation direction of the sound radiated from the sound source 300 based on the time difference calculated by the time difference calculation unit 121. The calculation unit 120 is configured to be able to output the calculated data indicating the sound propagation direction to the display unit 400.

The display unit 400 is an example of the "display means" of the present invention, and is configured as a display such as a liquid crystal monitor. The display unit 400 is capable of displaying the sound propagation direction calculated by the calculation unit 120 in a visually recognizable manner.

Next, the operation of the arithmetic unit 100 according to the first embodiment will be described with reference to FIGS. 2 to 5. Here, FIGS. 2 and 4 are conceptual diagrams showing the positional relationship between the sound source, the reference microphone, and the peripheral microphone according to the first embodiment, respectively. 3 and 5 are graphs showing signals detected by the reference microphone and the peripheral microphone according to the first embodiment, respectively.

As shown in FIG. 2, when viewed in the X direction with respect to the origin, the reference microphone 210 is arranged at a position closer to the origin than the peripheral microphone 220, and the sound from the sound source 300 arranged behind the origin Consider the case where is radiated in the positive direction of the X direction. In this case, it is considered that the sound radiated from the sound source 300 is first detected by the reference microphone 210 and then detected by the peripheral microphone 220.

Here, as shown in FIG. 3, it is assumed that the reference microphone signal and the peripheral microphone signal are detected by the sound detection unit 110 as shown in the figure. In this case, the time difference calculation unit 121 calculates the time difference between the microphones arranged far from the origin and the microphones arranged near the origin. Specifically, from the time T1 when the maximum value of the peripheral microphone signal arranged far from the origin is detected, to the time T0 when the maximum value of the reference microphone signal arranged near the origin is detected. Calculate the time difference. The time difference calculation unit 121 may calculate the time difference by comparing other peaks such as the first peak instead of the maximum value.

The time difference calculated from the signal of FIG. 3 is T1-T0> 0. As a result, the propagation direction of the sound at the reference position where the reference microphone 210 is arranged is calculated by the propagation direction calculation unit 122 as the propagation direction vector D1 shown in FIG. That is, the sound propagation direction is calculated as a positive direction when viewed in the X direction.

On the other hand, as shown in FIG. 4, when viewed in the X direction with respect to the origin, the reference microphone 210 is arranged at a position closer to the origin than the peripheral microphone 220, and is arranged farther from the origin than the peripheral microphone 220. Consider the case where the sound from the sound source 300 is radiated in the negative direction in the X direction. In this case, it is considered that the sound radiated from the sound source 300 is first detected by the peripheral microphone 220 and then detected by the reference microphone 210.

Here, as shown in FIG. 5, it is assumed that the reference microphone signal and the peripheral microphone signal are detected by the sound detection unit 110 as shown in the figure. In this case, the time difference calculation unit 121 detects the maximum value of the reference microphone signal arranged near the origin from the time T1 when the maximum value of the peripheral microphone signal arranged far from the origin is detected. The time difference of the time T0 is calculated. Then, the calculated time difference becomes T1-T0 <0. As a result, the sound propagation direction at the reference position where the reference microphone 210 is arranged is calculated by the propagation direction calculation unit 122 as the propagation direction vector D2 shown in FIG. That is, the sound propagation direction is calculated as a negative direction when viewed in the X direction.

As described above, according to the arithmetic unit 100 according to the first embodiment, the sound is sounded by utilizing the difference between the time when the sound is detected by the reference microphone 210 and the time when the sound is detected by the peripheral microphone 220. The propagation direction of can be calculated. In particular, in the arithmetic unit according to the first embodiment, it is sufficient that even the timing at which the sound is detected can be accurately detected, so that the propagation direction can be suitably known without using, for example, a high-sensitivity microphone.

<Second Example>
Next, the arithmetic unit according to the second embodiment will be described with reference to FIGS. 6 to 10. Here, FIG. 6 is a conceptual diagram showing the positional relationship between the sound source, the reference microphone, and the peripheral microphone according to the second embodiment. Further, FIG. 7 is a graph showing signals detected by the reference microphone and peripheral microphones according to the second embodiment, and FIG. 8 is a conceptual diagram showing a time difference vector calculated corresponding to each peripheral microphone. Further, FIG. 9 is a conceptual diagram showing the composition of time difference vectors calculated corresponding to each peripheral microphone, and FIG. 10 is a plan view showing a display example in the display unit.

The second embodiment is different from the first embodiment described above in a part of the configuration, and is substantially the same in other respects. Therefore, in the following, the parts different from the first embodiment already described will be described in detail, and the description of other overlapping parts will be omitted as appropriate.

As shown in FIG. 6, in the arithmetic unit 100 according to the second embodiment, a plurality of peripheral microphones 220 are arranged with respect to one reference microphone 210. Specifically, the first peripheral microphone 221 and the second peripheral microphone 222, the third peripheral microphone 223, and the fourth peripheral microphone 224 are arranged so as to surround the reference microphone 210. In this case, the sound radiated from the sound source 300 is first detected by the first peripheral microphone 221 and then by the reference microphone 210, then by the second peripheral microphone 222 and the third peripheral microphone 223, and finally. It is considered that the sound will be detected by the fourth peripheral microphone 224.

Here, as shown in FIG. 7, in the sound detection unit 110, the reference microphone signal and each peripheral microphone signal (specifically, the first peripheral microphone signal indicating the sound detected by the first peripheral microphone 221 and the second peripheral microphone). A second peripheral microphone signal indicating the sound detected by the microphone 222, a third peripheral microphone signal indicating the sound detected by the third peripheral microphone 223, and a fourth peripheral microphone indicating the sound detected by the fourth peripheral microphone 224. It is assumed that the signal) is detected as shown in the figure. Since the second peripheral microphone signal and the third peripheral microphone signal are detected as similar signals at substantially the same time, they are also shown in the figure.

As shown in FIG. 8, the time difference calculation unit 121 first calculates the time difference in which the corresponding peaks of the reference microphone signal and each peripheral microphone signal are detected in each axial direction. Specifically, the time difference between the first peripheral microphone and the fourth peripheral microphone arranged in the X direction with respect to the reference microphone is calculated. For the time difference between the reference microphone signal and the first peripheral microphone signal, the difference between the reference microphone signal arranged far away from the X direction and the first peripheral microphone signal arranged in the vicinity is calculated. That is, T0-T1> 0. As a result, the time difference vector x1 in the relationship between the reference microphone 210 and the first peripheral microphone 221 is calculated as a vector in the positive direction in the X direction. In the case of the reference microphone signal and the fourth peripheral microphone signal, the difference between the reference microphone signal arranged in the vicinity from the fourth peripheral microphone signal arranged far from the X direction is calculated. That is, T0-T4 <0. As a result, the time difference vector x2 in the relationship between the reference microphone 210 and the fourth peripheral microphone 224 is calculated as a vector in the positive direction in the X direction. Next, the time difference between the second peripheral microphone and the third peripheral microphone arranged in the Y direction with respect to the reference microphone is calculated. For the time difference between the reference microphone signal and the second peripheral microphone signal, the difference between the reference microphone signal arranged far away from the Y direction and the second peripheral microphone signal arranged in the vicinity is calculated. That is, T0-T2 <0. As a result, the time difference vector y1 in the relationship between the reference microphone 210 and the second peripheral microphone 222 is calculated as a vector in the negative direction in the Y direction. For the time difference between the reference microphone signal and the third peripheral microphone signal, the difference between the third peripheral microphone signal arranged far away from the Y direction and the reference microphone signal arranged in the vicinity is calculated. That is, T3-T1> 0. As a result, the time difference vector y2 in the relationship between the reference microphone 210 and the third peripheral microphone 223 is calculated as a vector in the positive direction in the Y direction.

As shown in FIG. 9, the propagation direction calculation unit 122 synthesizes the time difference vectors x1, x2, y1 and y2 calculated for each of the peripheral microphones 220, respectively, and calculates the sound propagation direction vector D3 at the reference position. To do. Specifically, the propagation direction vector D3 is calculated using the following mathematical formula (1).

D3 = (x1 + x2) + j (y1 + y2) ... (1)
As a result of the synthesis, the propagation direction vector D3 is calculated as a vector in the positive direction in the X direction by canceling the components in the Y direction.

As shown in FIG. 10, the calculation of such a propagation direction vector is performed, for example, with a plurality of points as reference positions, and is calculated at each reference position. The plurality of propagation direction vectors calculated in this way are displayed on the display unit 400 in accordance with the corresponding reference positions. In the example shown in the figure, the propagation direction of the sound radiated from the sound source 300 on the right front side of the user 500 is displayed. In addition, the strength of the sound pressure is also indicated by the shade of each vector. Specifically, it can be seen that the darker the color, the stronger the sound pressure, and the farther from the sound source 300, the weaker the sound pressure. In this way, in addition to the sound propagation direction, other data such as sound pressure may also be displayed.

As described above, according to the arithmetic unit according to the second embodiment, it is possible to know the propagation direction on the two-dimensional plane by arranging the plurality of peripheral microphones 220. By the way, in the second embodiment, since the peripheral microphones are arranged on the same plane, the propagation direction in two dimensions is calculated. On the other hand, for example, if other peripheral microphones are arranged at positions that are not on the same plane, it is possible to calculate the propagation direction in three dimensions. Note that the three-dimensional propagation direction can be calculated in the same manner as the above method (that is, it can be calculated by calculating the time difference vector with each peripheral microphone signal and synthesizing them). Detailed description will be omitted.

<Third Example>
Next, the arithmetic unit according to the third embodiment will be described with reference to FIG. Here, FIG. 11 is a conceptual diagram showing a convolution operation according to the third embodiment.

In the third embodiment, only the calculation method of the propagation direction is different from that of the first embodiment described above, and the other points are almost the same. Therefore, in the following, the parts different from the first embodiment already described will be described in detail, and the description of other overlapping parts will be omitted as appropriate. In the third embodiment, the arrangement of the reference microphone 210 and the peripheral microphone 220 is the same as that shown in FIG.

As shown in FIG. 11, in the arithmetic unit 100 according to the third embodiment, the arithmetic unit 120 performs a sine wave convolution calculation corresponding to a desired frequency for each of the reference microphone signal and the peripheral microphone signal. By performing such a convolution calculation, a sound peak corresponding to a desired frequency appears prominently in each of the reference microphone signal and the peripheral microphone signal. Therefore, if the propagation direction is calculated using the reference microphone signal and the peripheral microphone signal after the convolution calculation, the propagation direction of the sound having a desired frequency can be known. Specifically, the propagation direction vector is calculated by using the time difference between the time T0 at which the peak of the reference microphone signal after the convolution calculation is detected and the time T1 at which the peak of the peripheral microphone signal is detected.

<Fourth Example>
Next, the arithmetic unit according to the fourth embodiment will be described with reference to FIG. Here, FIG. 12 is a conceptual diagram showing a method of calculating the average value according to the fourth embodiment.

The fourth embodiment is different from the fourth embodiment described above only in the calculation method of the propagation direction, and is almost the same in other points. Therefore, in the following, the parts different from the fourth embodiment already described will be described in detail, and the description of other overlapping parts will be omitted as appropriate. Also in the fourth embodiment, the arrangement of the reference microphone 210 and the peripheral microphone 220 is the same as that shown in FIG.

As shown in FIG. 12, in the arithmetic unit 100 according to the fourth embodiment, first, as in the third embodiment, the convolution calculation of the sine wave corresponding to the desired frequency is performed for each of the reference microphone signal and the peripheral microphone signal. Is done. As a result, the peak of the sound corresponding to the desired frequency appears prominently in each of the reference microphone signal and the peripheral microphone signal.

Subsequently, the average value of the time difference in a predetermined period is calculated using the reference microphone signal and the peripheral microphone signal after the convolution calculation. Specifically, first, a plurality of time differences are calculated for each period Δt corresponding to each peak. That is, the time difference T ₁ between the first peaks is calculated by the following mathematical formula (2) using the detection time T ₀₁ of the first peak of the reference microphone signal and the detection time T ₁₁ of the first peak of the peripheral microphones.

T ₁ = T _11- T ₀₁ ... (2)
Similarly, the time difference T ₂ between the second peaks is calculated by the following mathematical formula (3) using the detection time T ₀₂ of the second peak of the reference microphone signal and the detection time T ₁₂ of the first peak of the peripheral microphones. ..

T ₂ = T _12- T ₀₂ ... (3)
Then, the time difference T _n between the nth peaks is calculated by the following mathematical formula (4) using the detection time T _0n of the nth peak of the reference microphone signal and the detection time T _1n of the first peak of the peripheral microphone.

T _n = T _1n −T _0n ... (4)
When these are n pieces of time difference _T 1 through T _n calculated, the n average value _{T a} time difference _T 1 through T _n is calculated using the following equation (5).

T _a = (T ₁ + T ₂ + ... T _n-1 + T _n ) / n ... (5)
Using the average value T _a time difference calculated in this manner, as compared with the case of using only the time difference between one peak, it calculates the propagation direction of the steady sound of the sound emitted to the space ..

The present invention is not limited to the above-described embodiment, and can be appropriately modified within the scope of claims and within the scope not contrary to the gist or idea of the invention that can be read from the entire specification. Arithmetic methods, as well as computer programs and recording media, are also included in the technical scope of the present invention.

100 Arithmetic logic unit 110 Sound detection unit 120 Calculation unit 121 Time difference calculation unit 122 Propagation direction calculation unit 210 Reference microphone 220 Peripheral microphone 300 Sound source 400 Display unit 500 User

Claims (1)

Sound detection means that detects the sound from the sound source at at least two places,
An arithmetic unit including an arithmetic means for executing an arithmetic related to a propagation direction in which the sound propagates from the sound source based on the time when the sound is detected at each of the at least two locations.