JP7038307B2 - Microphone - Google Patents

Description

The present invention relates to a microphone.

Generally, as a countermeasure against static electricity, the housing is made of metal so that static electricity is transmitted only to the surface of the housing to prevent intrusion into the housing, and the creepage distance from the housing of electronic components is secured. A technique is used to prevent static electricity from being applied directly to electronic components. However, such a method increases the mass and outer diameter shape of the product, and impairs the features and appeal of the product.

In the microphone module, a hole called a sound hole is made in the housing so that sound can be transmitted smoothly and efficiently to acoustic elements such as ECM (Electret Condenser Microphone) and MEMS (Micro Electro Mechanical Systems) microphones. There is. Since nothing is usually installed between the sound hole and the acoustic element, there is a problem that static electricity applied from the sound hole invades the inside of the microphone module.

Conventionally, as an example of measures against static electricity in this type of microphone module, there are those described in Patent Document 1 and Patent Document 2. In the microphone structure described in Patent Document 1, the center of the signal side electrode terminal and the ground side electrode terminal of the microphone is arranged so as to be offset from the center of the sound collecting hole of the housing. In the microphone device described in Patent Document 2, a conductive net made of a conductive material is provided between the sound collecting hole and the voice input surface of the microphone to close the sound collecting hole and inside and outside the housing. I try to block it.

Japanese Unexamined Patent Publication No. 10-098790 Japanese Unexamined Patent Publication No. 2005-086231

The microphone structure described in Patent Document 1 has a problem that the sensitivity of the microphone module is lowered and the frequency characteristics are affected. Further, in the microphone device described in Patent Document 2, the cost of the conductive net itself and the work cost for incorporating the conductive net itself are required, which raises the product price. Further, as in Patent Document 1, there is a problem that the influence on the acoustic performance is not completely eliminated.

The present invention has been made in view of the above circumstances, and provides a microphone capable of preventing the function from being lost due to static electricity with a simple circuit configuration without worrying about a decrease in sensitivity or an influence on frequency characteristics. With the goal.

The microphone of the present invention has a signal side electrode terminal and a ground side electrode terminal, and has a microphone element that converts sound into an electric signal and outputs it, and directional control and frequency characteristic control for the output signal of the microphone element. A digital signal processor that performs various signal processing including noise suppression, level adjustment, and output format conversion, a regulator that converts the power supply voltage into a voltage suitable for driving the microphone element and the digital signal processor, and at least the microphone element. A microphone including a housing for accommodating the digital signal processor and the regulator, and a capacitor having a positive terminal and a negative terminal. The housing includes a sound from the outside to the microphone element. A sound hole for guiding is formed, and the microphone element is arranged so that the center of the signal side electrode terminal and the ground side electrode terminal substantially coincides with the center of the sound hole of the housing, and the capacitor is provided. In the housing, in the vicinity of the sound hole, the height was higher than that of the peripheral chip component, the positive side terminal was connected to the primary side of the regulator, and the negative side terminal was connected to the ground.

According to the above configuration, a sound hole for guiding external sound to the microphone element is formed in the housing, and the center of the signal side electrode terminal and the ground side electrode terminal of the microphone element is the sound hole of the housing. Place the capacitor in the housing so that it roughly coincides with the center, place a capacitor with a height higher than the peripheral chip components near the sound hole of the housing, and connect the positive electrode side terminal of the capacitor to the primary side of the regulator. However, since the negative electrode side terminal is connected to the ground, it is possible to prevent the function from being lost due to static electricity with a simple circuit configuration without worrying about a decrease in sensitivity or an influence on frequency characteristics.

In the above configuration, the microphone element and the digital signal processor are mounted on one side of the printed circuit board, the capacitor is mounted on the other side of the printed circuit board, and the microphone element is mounted on the printed circuit board. A through hole is formed in a portion where the printed circuit board is mounted, and the printed circuit board is arranged so that the other surface side of the printed circuit board faces the sound hole side of the housing.

According to the above configuration, the static electricity discharged toward the sound hole formed in the housing can be induced in the capacitor, the positive electrode side terminal of the capacitor is connected to the primary side of the regulator, and the negative electrode side terminal is connected. Since it is connected to the ground, the secondary side of the regulator will not be hit by lightning. Therefore, the microphone element and the digital signal processor on the secondary side of the regulator will not be hit by lightning, and the function of the microphone will not be lost.

The microphone of the present invention has a signal side electrode terminal and a ground side electrode terminal, and has a microphone element that converts sound into an electric signal and outputs it, and directional control and frequency characteristic control for the output signal of the microphone element. A digital signal processor that performs various signal processing including noise suppression, level adjustment, and output format conversion, a regulator that converts the power supply voltage into a voltage suitable for driving the microphone element and the digital signal processor, and at least the microphone element. A microphone including a housing for accommodating the digital signal processor and the regulator, and a Zener diode. The housing is formed with sound holes for guiding sound from the outside to the microphone element. The microphone element is arranged so that the center of the signal side electrode terminal and the ground side electrode terminal substantially coincides with the center of the sound hole of the housing, and the Zener diode is arranged in the housing. In the vicinity of the sound hole, the height was higher than that of the peripheral chip component, the cathode terminal was connected to the primary side of the regulator, and the anode terminal was connected to the ground.

According to the above configuration, a sound hole for guiding external sound to the microphone element is formed in the housing, and the center of the signal side electrode terminal and the ground side electrode terminal of the microphone element is the sound hole of the housing. Place the Zener diode in the housing so that it coincides with the center, and place the Zener diode whose height is higher than the peripheral chip components near the sound hole of the housing, and connect the cathode terminal of the Zener diode to the primary side of the regulator. However, since the anode terminal is connected to the ground, it is possible to prevent the function from being lost due to static electricity with a simple circuit configuration without worrying about the decrease in sensitivity and the influence on the frequency characteristics.

In the above configuration, the microphone element and the digital signal processor are mounted on one side of the printed circuit board, the Zener diode is mounted on the other side of the printed circuit board, and the microphone is mounted on the printed circuit board. Through holes that penetrate both sides of the printed circuit board are formed in the portion where the element is mounted, and the printed circuit board is arranged with the other surface side facing the sound hole side of the housing.

According to the above configuration, the static electricity discharged toward the sound hole formed in the housing can be induced in the Zener diode, the cathode of the Zener diode is connected to the primary side of the regulator, and the anode is grounded. Since it is connected, the secondary side of the regulator will not be hit by lightning. Therefore, the microphone element and the digital signal processor on the secondary side of the regulator will not be hit by lightning, and the function of the microphone will not be lost.

The microphone of the present invention has a signal side electrode terminal and a ground side electrode terminal, and has a microphone element that converts sound into an electric signal and outputs the microphone, and directivity control and frequency characteristic control for the output signal of the microphone element. A digital signal processor that performs various signal processing including noise suppression, level adjustment, and output format conversion, a regulator that converts the power supply voltage into a voltage suitable for driving the microphone element and the digital signal processor, and at least the microphone element. A microphone including a housing for accommodating the digital signal processor and the regulator, and a varistor. The housing is formed with sound holes for guiding sound from the outside to the microphone element. The microphone element is arranged so that the center of the signal side electrode terminal and the ground side electrode terminal substantially coincides with the center of the sound hole of the housing, and the varistor is arranged in the housing so that the sound hole is substantially aligned with the center of the sound hole. In the vicinity of, the height was higher than the peripheral chip components and was connected between the primary side of the regulator and the ground.

According to the above configuration, a sound hole for guiding external sound to the microphone element is formed in the housing, and the center of the signal side electrode terminal and the ground side electrode terminal of the microphone element is the sound hole of the housing. A varistor whose height is higher than that of the peripheral chip components is placed in the vicinity of the sound hole of the housing so as to be substantially aligned with the center, and the varistor is placed between the primary side of the regulator and the ground. Since it is connected, it is possible to prevent the function from being lost due to static electricity with a simple circuit configuration without worrying about the decrease in sensitivity and the influence on the frequency characteristics.

In the above configuration, the microphone element and the digital signal processor are mounted on one surface side of the printed circuit board, the varistor is mounted on the other surface side of the printed circuit board, and the microphone element is mounted on the printed circuit board. A through hole is formed in a portion where the printed circuit board is mounted, and the printed circuit board is arranged so that the other surface side of the printed circuit board faces the sound hole side of the housing.

According to the above configuration, the static electricity discharged toward the sound hole formed in the housing can be induced in the varistor, and the varistor is connected between the primary side of the regulator and the ground. The secondary side of the regulator will not be hit by lightning. Therefore, the microphone element and the digital signal processor on the secondary side of the regulator will not be hit by lightning, and the function of the microphone will not be lost.

According to the present invention, it is possible to prevent the loss of functions due to static electricity with a simple circuit configuration without worrying about a decrease in sensitivity or an influence on frequency characteristics.

The figure which shows the schematic structure of the microphone which concerns on 1st Embodiment of this invention. A perspective view showing an example of a capacitor mounting state in the microphone according to the first embodiment. A perspective view showing the capacitor mounting surface side of the printed circuit board of the microphone according to the first embodiment. A perspective view showing the microphone element mounting surface side of the printed circuit board of the microphone according to the first embodiment. The figure which shows the schematic structure of the microphone which concerns on 2nd Embodiment of this invention. The figure which shows the schematic structure of the microphone which concerns on 3rd Embodiment of this invention.

Hereinafter, preferred embodiments for carrying out the present invention will be described in detail with reference to the drawings.

(First Embodiment)
FIG. 1 is a diagram showing a schematic configuration of a microphone according to a first embodiment of the present invention. In the figure, the microphone 100 according to the first embodiment includes a housing 101, a regulator 103, two microphone elements 104A and 104B, a DSP (Digital Signal Processor) 105, an amplifier 106, and a capacitor. It has 107, a power supply terminal 108, a microphone output terminal 109, and a ground (GND) terminal 110.

The housing 101 accommodates a regulator 103, microphone elements 104A, 104B, DSP 105, amplifier 106, capacitor 107, power supply terminal 108, microphone output terminal 109, ground terminal 110, and the like. The housing 101 is formed with sound holes 102A and 102B for guiding sound from the outside to the microphone elements 104A and 104B. A power supply voltage is applied to the power supply terminal 108, and the regulator 103 converts the power supply voltage applied to the power supply terminal 108 into a voltage suitable for driving the microphone elements 104A and 104B and the DSP 105. Here, the voltage suitable for driving the microphone elements 104A, 104B and DSP105 is, for example, 3.3V, 1.8V, or the like.

The microphone elements 104A and 104B each have a signal side electrode terminal and a ground side electrode terminal (both are not shown), and convert sound into an electric signal and output the sound. The microphone elements 104A and 104B are arranged in the housing 101 so that the centers of the signal side electrode terminals and the ground side electrode terminals substantially coincide with the centers of the sound holes 102A and 102B of the housing 101. The output formats of the microphone elements 104A and 104B may be analog or digital. The DSP 105 performs various signal processing including directivity control, frequency characteristic control, noise suppression, level adjustment, and output format conversion for the output signals of the microphone elements 104A and 104B, respectively. The amplifier 106 amplifies and outputs the analog output of the DSP 105 to a desired level. The microphone output terminal 109 outputs the output of the DSP 105 amplified by the amplifier 106 to the outside.

The capacitor 107 has a polarity and is used as a countermeasure against static electricity. The height of the capacitor 107 is higher than that of the peripheral chip components in the vicinity of the sound holes 102A and 102B in the housing 101, the positive electrode side terminal of the capacitor 107 is connected to the primary side (input side) of the regulator 103, and the negative electrode side is connected. The side terminal is connected to the ground. Here, the fact that the height of the capacitor 107 is higher than that of the peripheral chip components means that the capacitor 107 itself may be higher, or the mounting portion of the capacitor 107 on the printed circuit board may be raised. It is desirable to use a capacitor 107 that is taller than the height of the peripheral chip components, as it is costly. In the microphone 100 according to the first embodiment, a capacitor 107 higher than the height of peripheral chip components is used.

Here, with reference to FIG. 1, the mechanism of failure of the microphone due to the application of static electricity will be described. When there is no static electricity countermeasure capacitor 107, the static electricity discharged toward the sound hole 102A (or 102B) is discharged to an arbitrary place in the housing 101. At that time, when static electricity hits the line on the secondary side of the regulator 103, the microphone elements 104A, 104B and DSP105 are connected to the line on the secondary side (output side) of the regulator 103. Depending on the application level, a short-circuit defect may occur between the power supply of the microphone elements 104A and 104B and the ground, or between the power supply of the DSP 105 and the ground, and the function of the microphone 100 may be lost.

Next, the effect of the capacitor 107 against static electricity will be described. FIG. 2 is a diagram showing an example of a mounting state of the capacitor 107 of the microphone 100 according to the first embodiment. FIG. 3 is a perspective view showing the capacitor mounting surface side (the other surface side) of the printed circuit board 115 of the microphone 100. Further, FIG. 4 is a perspective view showing the microphone element mounting surface side (one surface side) of the printed circuit board 115 of the microphone 100. As shown in FIG. 3, peripheral chip components (reference numerals are omitted) are mounted on the other surface side of the printed circuit board 115 in addition to the capacitor 107. Further, as shown in FIG. 4, on one surface side of the printed circuit board 115, components on the secondary side line of the regulator 103 such as microphone elements 104A, 104B, DSP105, etc. are mounted including the regulator 103. There is.

Further, as shown in FIG. 3, the printed circuit board 115 is formed with two through holes 116A and 116B penetrating both sides of the printed circuit board 115 in a portion where the microphone elements 104A and 104B are mounted. That is, a through hole 116A is formed in a portion where the microphone element 104A is mounted, and a through hole 116B is formed in a portion where the microphone element 104B is mounted. The two through holes 116A and 116B are formed so as to be at the same positions as the sound holes 102A and 102B formed in the housing 101 when the printed circuit board 115 is attached to the housing 101. The capacitor 107 is located substantially in the center between the through holes 116A and 116B of the printed circuit board 115 (that is, substantially the center of the sound holes 102A and 102B of the housing 101). Further, as described above, the height of the capacitor 107 is higher than the height of the peripheral chip components. Specifically, the height of the passive component and the IC (Integrated Circuit) component is 0.23 to 0.8 mm, while the height of the capacitor 107 is 1.25 mm.

Since the height of the capacitor 107 is higher than the height of the peripheral chip components (passive components and IC described above), the static electricity discharged toward the sound hole 102A (or 102B) is induced in the capacitor 107. Since the positive electrode side terminal of the capacitor 107 is connected to the primary side of the regulator 103 and the negative electrode side terminal is connected to the ground, the secondary side of the regulator 103 is caused by the static electricity discharged toward the sound hole 102A (or 102B). There is no lightning strike. Therefore, the microphone elements 104A, 104B and DSP105 on the secondary side line of the regulator 103 will not be hit by lightning, and the function of the microphone 100 will not be lost.

As described above, according to the microphone 100 according to the first embodiment, the sound holes 102A and 102B for guiding the sound from the outside to the microphone elements 104A and 104B are formed in the housing 101, and the microphone elements 104A and 104B are provided. A capacitor 107 is arranged in the housing 101 so that the center of the signal side electrode terminal and the ground side electrode terminal substantially coincides with the center of the sound holes 102A and 102B of the housing 101, and the height is higher than that of the peripheral chip component. Since it is arranged near the sound holes 102A and 102B of the housing 101, the positive electrode side terminal of the capacitor 107 is connected to the primary side of the regulator 103, and the negative electrode side terminal is connected to the ground, the sensitivity is lowered and the frequency characteristics are affected. With a simple circuit configuration, it is possible to prevent the loss of functions due to static electricity without worrying about the effects of.

(Second Embodiment)
Next, the microphone according to the second embodiment of the present invention will be described with reference to the drawings. FIG. 5 is a diagram showing a schematic configuration of a microphone 200 according to a second embodiment of the present invention. In the figure, the same components as those in FIG. 1 are designated by the same reference numerals, and the description thereof will be omitted. As shown in FIG. 5, the microphone 200 according to the second embodiment has a Zener diode 120 as a component for static electricity countermeasures. As is well known, the Zener diode 120 is a device for obtaining a constant voltage, but since the breakdown voltage does not change even if the applied voltage is increased, it can be used as a component for static electricity countermeasures.

The mounting of the microphone elements 104A, 104B, DSP105, the regulator 103, and the like on the printed circuit board 115 is the same as that of the microphone 100 according to the first embodiment. Further, the Zener diode 120 is mounted on the other surface side of the printed circuit board 115 like the capacitor 107.

The Zener diode 120 is arranged substantially in the center of the sound holes 102A and 102B, and the height is higher than the height of the peripheral chip component. The cathode terminal of the Zener diode 120 is connected to the primary side of the regulator 103, and the anode terminal is connected to the ground. Here, the fact that the height of the Zener diode 120 is higher than that of the peripheral chip components means that the Zener diode 120 itself may be high, or the mounting portion of the Zener diode 120 on the printed circuit board may be raised. It is desirable to use a Zener diode 120 that is taller than the height of the peripheral chip components, as it is costly to process. In the microphone 200 according to the second embodiment, the Zener diode 120, which is higher than the height of the peripheral chip component, is used.

Since the height of the component of the Zener diode 120 is higher than the height of the peripheral chip component, the static electricity discharged toward the sound hole 102A (or 102B) is induced in the Zener diode 120. The cathode terminal of the Zener diode 120 is connected to the primary side of the regulator 103, and the anode terminal of the Zener diode 120 is connected to the ground.

By providing the Zener diode 120, the static electricity discharged toward the sound hole 102A (or 102B) does not receive lightning on the secondary side of the regulator 103. As a result, static electricity does not hit the microphone elements 104A, 104B and DSP105 on the secondary side line of the regulator 103, so that even if static electricity is discharged toward the sound hole 102A (or 102B), the microphone 200 The function will not be lost.

As described above, according to the microphone 200 according to the second embodiment, the sound holes 102A and 102B for guiding the sound from the outside to the microphone elements 104A and 104B are formed in the housing 101, and the microphone elements 104A and 104B are provided. , The Zener diode 120 is arranged in the housing 101 so that the center of the signal side electrode terminal and the ground side electrode terminal substantially coincides with the center of the sound holes 102A and 102B of the housing 101, and the height is higher than that of the peripheral chip component. Is arranged in the vicinity of the sound holes 102A and 102B of the housing 101, the cathode of the Zener diode 120 is connected to the primary side of the regulator 103, and the anode is connected to the ground. With a simple circuit configuration, it is possible to prevent the loss of functions due to static electricity without worrying about.

(Third Embodiment)
Next, the microphone according to the third embodiment of the present invention will be described with reference to the drawings. FIG. 6 is a diagram showing a configuration of a microphone 300 according to a third embodiment of the present invention. In the figure, the same components as those in FIG. 1 are designated by the same reference numerals, and the description thereof will be omitted. As shown in FIG. 6, the microphone 300 according to the third embodiment has a varistor 130 as a component for static electricity countermeasures. As is well known, the varistor can be used as a component for static electricity countermeasures due to the characteristic that the resistance value changes depending on the applied voltage and the current value increases at a value larger than the threshold voltage.

The mounting of the microphone elements 104A, 104B, DSP105, the regulator 103, and the like on the printed circuit board 115 is the same as that of the microphone 100 according to the first embodiment. Further, the varistor 130 is mounted on the other surface side of the printed circuit board 115 like the capacitor 107.

The varistor 130 is arranged substantially in the center of the sound holes 102A and 102B, and the height is higher than the height of the peripheral chip parts. The varistor 130 is connected between the primary side of the regulator 103 and the ground. Here, the fact that the height of the varistor 130 is higher than that of the peripheral chip components means that the varistor 130 itself may be high, or the mounting portion of the varistor 130 of the printed circuit board may be raised. Since the cost is high, it is desirable to use the varistor 130 which is higher than the height of the peripheral chip parts. In the microphone 300 according to the third embodiment, the varistor 130, which is higher than the height of the peripheral chip parts, is used.

Since the height of the component of the varistor 130 is higher than the height of the peripheral chip component, the static electricity discharged toward the sound hole 102A (or 102B) is guided to the varistor 130. The terminal of the varistor 130 is connected to the primary side of the regulator 103 and the ground, and the static electricity discharged toward the sound hole 102A (or 102B) does not receive lightning on the secondary side of the regulator 103. As a result, even if static electricity is discharged toward the sound hole 102A (or 102B) without being hit by lightning on the microphone elements 104A, 104B and DSP105 on the secondary side line of the regulator 103, the function of the microphone 300 can be obtained. It will not disappear.

As described above, according to the microphone 300 according to the third embodiment, the sound holes 102A and 102B for guiding the sound from the outside to the microphone elements 104A and 104B are formed in the housing 101, and the microphone elements 104A and 104B are provided. The varistor 130 is arranged in the housing 101 so that the center of the signal side electrode terminal and the ground side electrode terminal substantially coincides with the center of the sound holes 102A and 102B of the housing 101, and the height is higher than that of the peripheral chip component. Since it is arranged near the sound holes 102A and 102B of the housing 101 and the varistor 130 is connected between the primary side of the regulator 103 and the ground, there is no concern about a decrease in sensitivity or an influence on the frequency characteristics. A simple circuit configuration can prevent the function from being lost due to static electricity.

The present invention is not limited to the above embodiment, and can be variously modified and implemented without departing from the gist of the present invention.
For example, in the microphones 100, 200, and 300 according to the first to third embodiments, the output format of the microphone output terminal 109 is a monaural analog output, but a stereo analog output may be used, and there are more channels. May be. It is also possible to output as a digital format. In that case, a method of directly outputting to the microphone output terminal 109 without installing the amplifier 106, or using the amplifier 106 as a buffer for enhancing the drive capacity, etc., as appropriate. Can be replaced.

The present invention is useful for microphones.

100, 200, 300 Microphone 101 Housing 102A, 102B Sound hole 103 Regulator 104A, 104B Microphone element 105 DSP
106 Amplifier 107 Capacitor 108 Power terminal 109 Microphone output terminal 110 Ground terminal 115 Printed circuit board 116A, 116B Through hole 120 Zener diode 130 Varistor

Claims (6)

A microphone element that has a signal side electrode terminal and a ground side electrode terminal and converts sound into an electric signal and outputs it.
A digital signal processor that performs various signal processing including directivity control, frequency characteristic control, noise suppression, level adjustment, and output format conversion for the output signal of the microphone element.
A regulator that converts the power supply voltage into a voltage suitable for driving the microphone element and the digital signal processor, and
A housing that houses at least the microphone element, the digital signal processor, and the regulator.
Capacitors with positive and negative terminals,
It is a microphone equipped with
In the housing, a sound hole for guiding an external sound is formed in the microphone element, and in the microphone element, the center of the signal side electrode terminal and the ground side electrode terminal is the center of the housing. Arranged so as to substantially coincide with the center of the sound hole, the capacitor is located in the housing in the vicinity of the sound hole, is higher in height than the peripheral chip component, and the positive electrode side terminal is on the primary side of the regulator. It was connected and the negative electrode side terminal was connected to the ground.
Microphone. The microphone element and the digital signal processor are mounted on one side of the printed circuit board, the capacitor is mounted on the other side of the printed circuit board, and the microphone element is mounted on the printed circuit board. Through holes penetrating both sides of the printed circuit board are formed in the portion, and the printed circuit board is arranged so that the other side thereof faces the sound hole side of the housing.
The microphone according to claim 1. A microphone element that has a signal side electrode terminal and a ground side electrode terminal and converts sound into an electric signal and outputs it.
A digital signal processor that performs various signal processing including directivity control, frequency characteristic control, noise suppression, level adjustment, and output format conversion for the output signal of the microphone element.
A regulator that converts the power supply voltage into a voltage suitable for driving the microphone element and the digital signal processor, and
A housing that houses at least the microphone element, the digital signal processor, and the regulator.
With a Zener diode,
It is a microphone equipped with
In the housing, a sound hole for guiding an external sound is formed in the microphone element, and in the microphone element, the center of the signal side electrode terminal and the ground side electrode terminal is the center of the housing. Arranged so as to substantially coincide with the center of the sound hole, the Zener diode is higher than the peripheral chip component in the vicinity of the sound hole in the housing, and the cathode terminal is connected to the primary side of the regulator. And the anode terminal was connected to ground,
Microphone. The microphone element and the digital signal processor are mounted on one surface side of the printed circuit board, the Zener diode is mounted on the other surface side of the printed circuit board, and the microphone element is mounted on the printed circuit board. A through hole is formed in the portion of the printed circuit board so as to penetrate both sides of the printed circuit board.
The microphone according to claim 3. A microphone element that has a signal side electrode terminal and a ground side electrode terminal and converts sound into an electric signal and outputs it.
A digital signal processor that performs various signal processing including directivity control, frequency characteristic control, noise suppression, level adjustment, and output format conversion for the output signal of the microphone element.
A regulator that converts the power supply voltage into a voltage suitable for driving the microphone element and the digital signal processor, and
A housing that houses at least the microphone element, the digital signal processor, and the regulator.
With a barista,
It is a microphone equipped with
In the housing, a sound hole for guiding an external sound is formed in the microphone element, and in the microphone element, the center of the signal side electrode terminal and the ground side electrode terminal is the center of the housing. Arranged so as to substantially coincide with the center of the sound hole, the varistor is located in the housing in the vicinity of the sound hole, higher in height than the peripheral chip component, and between the primary side of the regulator and the ground. Connected,
Microphone. The microphone element and the digital signal processor are mounted on one surface side of the printed circuit board, the varistor is mounted on the other surface side of the printed circuit board, and the microphone element is mounted on the printed circuit board. Through holes penetrating both sides of the printed circuit board are formed in the portion, and the printed circuit board is arranged so that the other side thereof faces the sound hole side of the housing.
The microphone according to claim 5.

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