KR101147997B1 - Apparatus for measuring performance of microphone - Google Patents

Abstract

PURPOSE: An apparatus for measuring the performance of a microphone is provided to check the state of a microphone by measuring the directivity and sensitivity of a microphone using a simple method under certain conditions. CONSTITUTION: A microphone(100) is installed in a starting point of a semicircular frame(300). A sound source part(200) is installed in the circumference of the semicircular frame. An analyzer analyzes an acoustic sound measured from the microphone. The sound source part is mounted on a sliding drive part(250) which is used for increasing a distance from the microphone and the sound source part. A support supports while separating the semicircular frame from the surface. The sound source part is movable in the circumference of the semicircular frame.

Description

Apparatus for Measuring Performance of Microphone

The present invention relates to an apparatus for measuring the performance of a microphone, and more particularly, to an apparatus for measuring the performance of a microphone so that the state of the microphone can be checked by simply measuring the directivity and sensitivity of the microphone characteristics under a constant condition at all times. .

Microphones are widely used sensors for collecting sound or noise signals. On the other hand, since the microphone receives a sound or noise signal mainly by detecting the pressure and sound pressure of the sound signal transmitted through the outside air and converting it into an electric signal, an area where the reliability of the received signal is guaranteed according to the characteristics of the sensor It has the potential to be limited or distorted.

In general, the specifications of a microphone are expressed by characteristic values such as the direction angle, the center frequency, the frequency range, and the sensitivity (mV / Pa). Even if a microphone manufactured with the same specification is manufactured according to the manufacturing process or the same process, Will cause a difference.

Therefore, in general, a user of a microphone uses the microphone by calibrating the microphone by applying characteristic values such as a direction angle and a sensitivity of each microphone provided by the manufacturer to the peripheral device.

However, even after this correction, the microphone's response to the same sound source is slightly different. This is because the characteristic values of the microphones provided by the manufacturers are obtained through standardized measurement methods and devices, and when interlocked with other devices in actuality, other unexpected signals may be received depending on the characteristics of the peripheral device and the connection state. This is because the characteristics may change due to self-deterioration due to long-term use of the microphone.

Therefore, the user should check the state of the microphone and obtain basic information for correction by measuring the directivity and sensitivity, which are the most basic elements of the microphone characteristics, and especially when a plurality of microphones are used simultaneously to receive an acoustic signal, It is necessary to measure the characteristics of the microphone and correct it to have the same characteristics through relative comparison.

Accordingly, an object of the present invention is to provide an apparatus for measuring the performance of a microphone so that the state of the microphone can be checked by measuring the directivity and sensitivity among the characteristics of the microphone by a simple method under a constant condition at all times.

Apparatus for measuring the performance of the microphone according to the present invention for achieving the above object, the semi-circular frame 300, the microphone 100 is installed in the position of the origin; A sound source unit 200 installed at a circumference of the semi-circular frame 300; And an analyzer 500 for analyzing the sound measured from the microphone 100.

Preferably, the sound source unit 200 is mounted to the sliding drive unit 250 used to increase or decrease the distance from the microphone to the sound source unit 200.

In addition, the semi-circular frame 300 further includes a support 400 for supporting the isolation from the ground.

In addition, the sound source unit 200 is characterized in that the movable on the circumference of the semi-circular frame (300).

According to the present invention, it is possible to check the state of the microphone by measuring the directivity and sensitivity of the characteristics of the microphone by a simple method under constant conditions at all times.

In addition, according to the present invention, a plurality of the same microphone can be measured under the same conditions to enable the correction between the microphone to receive a reliable sound signal.

1 is a view showing the structure of an apparatus for measuring the performance of a microphone according to an embodiment of the present invention; and
2 is a view showing the structure of a microphone performance measurement apparatus according to another embodiment of the present invention.

Hereinafter, with reference to the drawings will be described the present invention in more detail. It should be noted that the same elements in the figures are represented by the same numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

1 is a view showing a schematic structure of a performance measuring apparatus of a microphone according to an embodiment of the present invention. Referring to FIG. 1, an apparatus for measuring the performance of the microphone 100 according to an exemplary embodiment of the present invention includes a semicircular frame 300 and a sliding driver 250.

Semi-circular frame 300 having a constant radius "r" is a microphone to be measured at the position of the origin as shown in Figure 1, the sound source 200 is installed at any position of the circumference of the semi-circular frame 300 .

More specifically, the sliding drive unit 250 is installed in combination with the circumference of the semi-circular frame 300, the sound source unit 200 is provided in the sliding drive unit 250. The sliding drive unit 250 in FIG. 1 is installed to be movable on the circumference of the semi-circular frame 300 so that the opposing angle of the sound source unit 200 with respect to the microphone 100 varies from 0 ° to 180 °.

To this end, in the practice of the present invention it will be preferable that the sliding drive unit 250 and the semi-circular frame 300 is installed in a rail structure. That is, it may be desirable to make the sliding movement in the state in which the protrusion of the sliding drive unit 250 is coupled along the circumferential groove 350 installed on the circumference of the semi-circular frame 300.

Through the structure as shown in FIG. 1, the user can freely change the opposing angle of the microphone 100 of the sound source unit 200.

That is, the relative angle with respect to the microphone 100 of the sound source unit 200 can be changed so that the directivity which is the reception degree of the microphone 100 according to the propagation angle of the sound with respect to the same sound can always be measured under a constant condition.

In addition, by maintaining the distance from the sound source unit 200 to the microphone 100 at " r ", the microphone 100 has a constant intensity of the sound signal from the sound source unit 200 selected according to the characteristics of the microphone 100. Will be delivered to

In order to measure the directivity angle and sensitivity of the microphone 100 to be measured, the center frequency, frequency range, intensity (dB), sound shape, and duration of the sound to be generated are first determined in consideration of the frequency domain and the maximum sensitivity of the microphone 100. After the sound source unit 200 generates the desired sound.

In order to measure the sensitivity of the microphone 100, the microphone 100 and the sound source unit 200 are arranged in a straight line, that is, the sound source unit (at a position where θ on the semi-circular frame 300 in FIG. 1 becomes 90 °). The analyzer 500 in FIG. 2 measures a signal (mV / Pa) in which a sound signal is converted into an electrical signal through the microphone 100 while the 200 is fixed, and measures the sensitivity of the microphone 100. ) Repeatedly monitors the sensitivity change of the microphone 100 by repeatedly performing the same measurement at regular intervals.

In addition, the analyzer 500 may detect a characteristic change of the microphone 100 by analyzing a change in frequency component of the acoustic signal received through the microphone 100.

Meanwhile, in order to measure the directivity of the microphone 100, the relative angle θ of the microphone 100 and the sound source unit 200 is measured at a predetermined interval from 0 ° to 180 ° to measure the intensity of the received sound signal for each angle. By measuring, the directivity which shows the sensitivity with respect to the acoustic propagation direction of the microphone 100 can be measured.

If the same microphone 100 is to be used at the same time, if the sensitivity and directivity measurement of each microphone 100 is required, the above-described sensitivity and directivity measurement for each microphone 100 is performed under the same conditions. The characteristics of each microphone 100 may be measured and compared with each other.

In addition, it is possible to correct for each microphone 100 based on the measurement results, it is possible to correct for obtaining the same reception sensitivity and directivity.

On the other hand, in the practice of the present invention, it is preferable that the user can adjust the distance between the sound source unit 200 and the microphone 100, for this purpose, the sliding drive unit 250 is a distance adjusting groove ( By moving the sound source unit 200 along the distance adjusting groove 255 in the state in which the sound source unit 200 is installed in the 255, to allow the user to adjust the distance to the microphone 100 of the sound source unit 200 Would be desirable.

Specifically, the user takes into consideration the characteristics of the sound generated from the sound source unit 200 so that the distance between the microphone 100 and the sound source unit 200 may be located in the free sound field range outside the near field. It would be desirable to adjust and fix it.

In this case, it is preferable to form a distance ruler in the distance adjusting groove 255 provided in the sliding driver 250 for easy distance adjustment of the user.

Through this process, the sound propagated between the microphone 100 and the sound source unit 200 may be constantly maintained, and the change of the acoustic signal due to disturbance such as reflection and attenuation may be eliminated or minimized. Repetitive and reproducible acoustic signals can be received.

In addition, referring to Figure 2, it can be seen that the semi-circular frame 300 in Figure 1 is installed to be isolated from the ground by the support (400). As such, the semi-circular frame 300 in which the sound source unit 200 and the microphone 100 are installed is installed to be isolated from the ground, so that the sound signal transmitted in a straight path to the microphone 100 among the sounds generated in the sound source unit 200. Only the microphone 100 can be prevented from receiving the sound reflected from the ground.

As such, the sound received through the microphone 100 is analyzed through the analyzer 500.

While the above has been shown and described with respect to preferred embodiments and applications of the present invention, the present invention is not limited to the specific embodiments and applications described above, the invention without departing from the gist of the invention claimed in the claims Various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

100: microphone, 200: sound source,
250: sliding drive, 255: distance adjusting groove,
300: semi-circular frame, 350: circumferential groove,
400: support, 500: analyzer.

Claims (4)

Semi-circular frame 300, the microphone 100 is installed at the origin position;
A sound source unit 200 installed at a circumference of the semi-circular frame 300; And
Analyzer 500 for analyzing the sound measured from the microphone 100
Performance measuring device of the microphone comprising a.
The method of claim 1,
The sound source unit 200 is a microphone performance measurement apparatus that is mounted to the sliding drive unit 250 used to increase or decrease the distance from the microphone to the sound source unit (200).
The method of claim 1,
Device for measuring the performance of the microphone further comprises a support (400) for supporting the semi-circular frame (300) isolated from the ground.
The method of claim 1,
The sound source unit 200 is a performance measurement device of the microphone that is movable on the circumference of the semi-circular frame (300).

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