JP2523951B2 - Microphone device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microphone device that reduces noise, vibration, and wind noise near a microphone unit.

2. Description of the Related Art In recent years, a video-integrated camera has become more popular as a device that can easily record audio and video. Along with this, the functions of the video-integrated camera have been expanded, and the size and weight have been reduced.

Hereinafter, a typical example of a conventional video integrated camera will be described with reference to the drawings.

FIG. 5 is a diagram showing the appearance of a conventional video-integrated camera. In order to avoid the influence of noise and vibration generated by the main body, the microphone unit 1 is installed at a position apart from the main body 2 by fixing the unit via a vibration damping material such as rubber.
Furthermore, a windshield is provided to reduce wind noise.

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention However, when the video-integrated camera is further downsized, the above-described configuration of the video-integrated camera has practical and design problems. On the other hand, when the microphone unit 4 is embedded in the video-integrated camera body 3 as shown in FIG.
Is directly affected by the vibration and noise generated by the body. Therefore, there is a problem that the SN ratio at the time of sound pickup is lowered, and the sound pickup quality is significantly deteriorated. Possible methods to deal with the problem of the reduction of the SN ratio are a method using superdirectivity and a method for removing noise by using signal processing technology, but it is difficult from the viewpoint of space limitation and cost.

For the above reasons, the microphone device which is satisfactory in terms of performance, design and cost has not been developed yet.

It is an object of the present invention to provide a microphone device that uses an omnidirectional microphone and a unidirectional microphone to reduce noise, vibration, and wind noise in the vicinity of the microphone unit and can collect sound with a good SN ratio.

Means for Solving the Problems In order to achieve the above object, a microphone device of the present invention comprises an omnidirectional microphone unit and a bidirectional microphone unit, a main axis of which is directed toward a video-integrated camera body, and both microphone units are parallel or The main axes of both units are arranged in a straight line, and after the output signal of the bidirectional microphone unit is passed through the equalizer, subtraction is performed when both units have the same polarity, and addition is performed when the units have different polarities. . However, the polarity of the microphone unit is determined by the positive / negative of the output voltage generated when a positive sound pressure is applied from the front of the unit.

In addition, the omnidirectional microphone unit and the bidirectional microphone unit are arranged so that the main axes thereof face the video-integrated camera body in the opposite direction, and both microphone units are arranged in parallel or the main axes of both units are aligned. After the output signal of the bidirectional microphone unit is passed through the equalizer, addition is performed when both units have the same polarity, and subtraction is performed when the units have different polarities.

In addition, the omnidirectional microphone unit and the bidirectional microphone unit are oriented such that the omnidirectional microphone has its main axis directed toward the video-integrated camera body, and the bidirectional microphone has its main axis directed reversely with respect to the video-integrated camera body. After arranging both microphone units in parallel or with the main axes of both units aligned on a straight line and passing the output signal of the bidirectional microphone unit through the equalizer,
When both units have the same polarity, they are added, and when they have different polarities, they are subtracted.

In addition, the omnidirectional microphone unit and the bidirectional microphone unit are oriented with the main axis of the omnidirectional microphone in the opposite direction to the video integrated camera body, and the bidirectional microphone has its main axis directed to the video integrated camera body. When the two microphone units are placed in parallel or the main axes of both units are aligned, and the output signals of the bidirectional microphone units are passed through the equalizer, subtraction is performed when both units have the same polarity. When the polarities are different from each other, they are added.

In addition, in each of the above-mentioned configurations, when the omnidirectional microphone and the bidirectional microphone are vibrated, both units are fixed so as to vibrate integrally.

Effect The present invention can reduce noise, vibration, and wind noise in the vicinity of the microphone unit by the above configuration, and can collect sound with a good SN ratio.

The microphone device of the present invention uses one unit each of an omnidirectional microphone and a bidirectional microphone as a pair. When a microphone is used in the vicinity of a point sound source, the wavefront of the sound wave becomes a spherical wave, and the sound pressure gradient becomes larger than when the wavefront becomes a plane wave far from the sound source, so the 0 ° and 180 ° of the bidirectional microphone are used. The sound pressure sensitivity in the degree direction can be raised mainly in the low frequency range. Due to this proximity effect, the frequency characteristics of the bidirectional microphone in the state of high sensitivity are matched with the frequency characteristics of the omnidirectional microphone by using the equalizer. Then, in order to cancel the signals from the noise sources of the two units, 2
By adding or subtracting the output signals of two units, distant sound sources have directional characteristics similar to omnidirectional in the low frequency range and unidirectional in the high frequency range, and units close to each other have directional characteristics. It is possible to realize a microphone device having low sensitivity in the main axis direction.

Further, as described above, since the microphone device according to the present invention has a non-directional directional characteristic in the low frequency range, it is possible to realize a microphone device that is not easily affected by wind noise.

Furthermore, by fixing the omnidirectional microphone unit and the bidirectional microphone unit so as to vibrate integrally, it is possible to remove the influence of the signal applied to the microphone unit.

Embodiment Hereinafter, a microphone device according to an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 shows the configuration of a microphone device according to an embodiment of the present invention. In the figure, 11 is a video-integrated camera body, 12 is an omnidirectional microphone unit, 13 is a bidirectional microphone unit, and 14 is An equalizer, 15 indicates a subtractor, and the omnidirectional microphone unit 12 and the bidirectional microphone unit 13 are arranged in parallel with each other with their main axes directed toward the video-integrated camera body 11, as shown in FIG. These have the same polarity.

The output of the bidirectional microphone unit 13 is input to the equalizer 14 so that the output signal when the sound source of the bidirectional microphone unit 13 is close to the frequency characteristic of the omnidirectional unit 12.

FIG. 2 shows the frequency characteristics of the bidirectional microphone unit 13 after passing through the equalizer when there are sound sources at a distance of 1 m and a distance of 2 cm from the bidirectional microphone unit 13. In the diagram of FIG. 2, the solid line and the broken line respectively represent the sensitivities in the directions of 0 degree and 180 degrees with respect to the main axis of the microphone unit. Equalizer 14 from the output signal of omnidirectional unit 12
Is subtracted to obtain the output of the microphone device of this embodiment.

FIG. 3 shows the frequency characteristic when there is a sound source at a distance of 1 m from the microphone device of this embodiment, and FIG. 4 shows the frequency characteristic when there is a sound source near the microphone device of this embodiment. The solid and broken lines in FIGS. 3 and 4 represent the sensitivities in the 0 ° and 180 ° directions with respect to the front of the video-integrated camera, respectively.
As shown in FIG. 4, according to the microphone device of the present embodiment, unidirectionality is provided for sound sources located close to each other. Therefore, it is possible to reduce the influence of noise generated by the video-integrated camera body.

As described above, according to the microphone device of the present embodiment, it is possible to reduce noise near the microphone unit and wind noise, and it is possible to collect sound with a good SN ratio.

In this embodiment, the omnidirectional microphone unit and the bidirectional microphone unit having the same polarity are used, but the omnidirectional microphone unit and the bidirectional microphone unit having different polarities are used as the main axes. 1 is also arranged in parallel to the video-integrated camera body, and the output signal of the bidirectional microphone unit is added to the signal passed through the equalizer and the output signal of the omnidirectional microphone unit is added, as shown in FIG. The characteristics similar to those of the microphone device having the configuration can be obtained, noise near the microphone unit and wind noise can be reduced, and sound collection with a good SN ratio can be realized.

In addition, the omnidirectional microphone unit and the bidirectional microphone unit of the same polarity are arranged parallel to each other with their main axes facing away from the video-integrated camera body, and the output signal of the bidirectional microphone unit is equalized. A configuration in which the output signal of the omnidirectional microphone unit is added to the passed signal, but the omnidirectional microphone unit and the bidirectional microphone unit having mutually different polarities, the main axes of which are opposite to those of the video-integrated camera body. The microphone device of the configuration shown in FIG. 1 is also arranged in parallel with the microphone device configured to subtract the output signal of the bidirectional microphone unit from the output signal of the omnidirectional microphone unit from the output signal of the equalizer. The same characteristics as the device can be obtained, and noise and wind noise near the microphone unit can be obtained. It is possible to reduce, it can be collected sound SN ratio.

In addition, the omnidirectional microphone unit and the bidirectional microphone unit of the same polarity, the omnidirectional microphone unit, its main axis is directed to the video integrated camera body,
The bi-directional microphone has its main axis oriented parallel to the video-integrated camera body in the opposite direction, and adds the output signal of the bi-directional microphone unit to the signal passed through the equalizer and the output signal of the omni-directional microphone unit. The omnidirectional microphone unit and the bidirectional microphone unit having mutually different polarities, the omnidirectional microphone unit directs its main axis to the video integrated camera body, and the bidirectional microphone unit directs the main axis. According to the configuration in which the output signal of the bidirectional microphone unit is subtracted from the signal passed through the equalizer and the output signal of the omnidirectional microphone unit is subtracted, the output signal of the bidirectional microphone unit is arranged in parallel with the video integrated camera body in the opposite direction. It is possible to obtain the same characteristics as the microphone device having the configuration shown in
Noise near the microphone unit and wind noise can be reduced, and sound with a good SN ratio can be collected.

In addition, the omnidirectional microphone unit and the bidirectional microphone unit of the same polarity are oriented such that the omnidirectional microphone unit has its main axis reversed with respect to the video-integrated camera body, and the bidirectional microphone unit has its main axis video. Arranged in parallel toward the integrated camera body, the output signal of the bidirectional microphone unit is subtracted from the output signal of the omnidirectional microphone unit from the signal passed through the equalizer, or the omnidirectional microphone units having mutually different polarities. And the bidirectional microphone unit, the omnidirectional microphone has its main axis oriented reversely with respect to the video-integrated camera body, and the bidirectional microphone has its main axis oriented parallel to the video-integrated camera body, The output signal of the bidirectional microphone unit is not converted from the signal passed through the equalizer. By arrangement for adding the output signal of the tropic microphone unit, it is possible to obtain a microphone unit and a similar characteristic of the configuration shown in FIG. 1,
Noise near the microphone unit and wind noise can be reduced, and sound with a good SN ratio can be collected.

In addition, the same characteristics as those of the microphone device having the configuration shown in FIG. 1 can be obtained by any of the above microphone devices in which the main axes of both the omnidirectional microphone unit and the bidirectional microphone unit are arranged in a straight line. Can
It is possible to reduce noise and wind noise in the vicinity of the microphone unit, and it is possible to collect sound with a good SN ratio.

Further, by fixing both units so as to integrally vibrate, even if vibration is applied to the omnidirectional microphone and the bidirectional microphone, the same characteristics as the microphone device having the configuration of FIG. 1 can be obtained. Therefore, it is possible to reduce noise near the microphone unit and wind noise, and also reduce vibration noise due to vibration applied to the microphone device, which enables sound collection with a good SN ratio.

EFFECTS OF THE INVENTION As described above, according to the present invention, the omnidirectional microphone unit and the bidirectional microphone unit are arranged such that the main axes of the microphone units face the video-integrated camera body and both microphone units are parallel or the main axes of both units are aligned. , And after passing the output signal of the bidirectional microphone unit through the equalizer, when both units have the same polarity, subtraction,
When the polarities are different from each other, it is possible to reduce noise and wind noise in the vicinity of the microphone unit by adding them, and it is possible to realize sound collection with a good SN ratio.

In addition, the omnidirectional microphone unit and the bidirectional microphone unit are arranged so that the main axes thereof face the video-integrated camera body in the opposite direction, and both microphone units are arranged in parallel or the main axes of both units are aligned. After passing the output signal of the bidirectional microphone unit through the equalizer, add noise when both units have the same polarity and subtract noise when the units have different polarities to reduce noise and wind noise near the microphone unit. It is possible to realize sound collection with a good SN ratio.

In addition, the omnidirectional microphone unit and the bidirectional microphone unit are oriented such that the omnidirectional microphone has its main axis directed toward the video-integrated camera body, and the bidirectional microphone has its main axis directed reversely with respect to the video-integrated camera body. After arranging both microphone units in parallel or with the main axes of both units aligned on a straight line and passing the output signal of the bidirectional microphone unit through the equalizer,
Noise and wind noise in the vicinity of the microphone unit can be reduced by adding them when both units have the same polarity and subtracting them when they have different polarities.
It is possible to realize sound collection with a good SN ratio.

In addition, the omnidirectional microphone unit and the bidirectional microphone unit are oriented with the main axis of the omnidirectional microphone in the opposite direction to the video integrated camera body, and the bidirectional microphone has its main axis directed to the video integrated camera body. When the two microphone units are placed in parallel or the main axes of both units are aligned, and the output signals of the bidirectional microphone units are passed through the equalizer, subtraction is performed when both units have the same polarity. By adding and constructing when the polarities are different from each other, it is possible to reduce noise and wind noise in the vicinity of the microphone unit, and it is possible to realize sound collection with a good SN ratio.

In addition, when vibration is applied to the omnidirectional microphone and the bidirectional microphone in each of the above microphone devices, both units are fixed so that they vibrate integrally, so that noise, wind noise, and vibration near the microphone unit are generated. It is possible to reduce the noise, and it is possible to realize sound collection with a good SN ratio.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a microphone device according to an embodiment of the present invention, FIG. 2 is a frequency characteristic diagram of a bidirectional microphone after passing through an equalizer, and FIG. 3 is a microphone device according to an embodiment of the present invention. FIG. 4 is a frequency characteristic diagram when there is a sound source at a distance of 1 m, FIG. 4 is a frequency characteristic diagram when there is a sound source in the vicinity of the microphone device in one embodiment of the present invention, and FIG. 5 is an appearance of a conventional video-integrated camera. Figure, 6th
The figure is an external view of a video-integrated camera having a microphone built in the main body. 11 …… Video integrated camera body, 12 …… Omnidirectional microphone unit, 13 …… Bidirectional microphone unit, 14 …… Equalizer, 15 …… Subtractor.

Claims (10)

(57) [Claims] 1. An omnidirectional microphone unit of the same polarity and a bidirectional microphone unit are arranged in parallel with their main axes facing the video-integrated camera body, and the output signal of the bidirectional microphone unit passes through an equalizer. The microphone device is configured such that this signal is subtracted from the output signal of the omnidirectional microphone unit and output. 2. An omnidirectional microphone unit and a bidirectional microphone unit having opposite polarities are arranged in parallel with each other with their main axes directed toward the video-integrated camera body, and an output signal of the bidirectional microphone unit is equalized. A microphone device configured to pass the signal, add the signal to an output signal of the omnidirectional microphone unit, and output the added signal. 3. An omnidirectional microphone unit of the same polarity and a bidirectional microphone unit are arranged parallel to each other with their main axes facing the video-integrated camera body in the opposite direction, and the output signal of the bidirectional microphone unit is arranged. Is passed through an equalizer, and this signal is added to the output signal of the omnidirectional microphone unit and output. 4. An omnidirectional microphone unit and a bidirectional microphone unit, which have mutually different polarities, are arranged parallel to each other with their main axes being oppositely directed to the video-integrated camera body, and the output of the bidirectional microphone unit. A microphone device configured to pass a signal through an equalizer, subtract the signal from the output signal of the omnidirectional microphone unit, and output the subtracted signal. 5. An omnidirectional microphone unit of the same polarity and a bidirectional microphone unit, wherein the omnidirectional microphone unit has its main axis oriented toward the video-integrated camera body, and the bidirectional microphone unit has its main axis oriented. The bidirectional microphone unit is arranged in parallel to the video-integrated camera body in the opposite direction, the output signal of the bidirectional microphone unit is passed through an equalizer, and this signal is added to the output signal of the omnidirectional microphone unit and output. A microphone device having the above structure. 6. An omnidirectional microphone unit and a bidirectional microphone unit having mutually different polarities, the omnidirectional microphone unit having its main axis oriented toward the video integrated camera body, and the bidirectional microphone unit having the main axis. Is arranged in parallel with the video-integrated camera body in the opposite direction, the output signal of the bidirectional microphone unit is passed through an equalizer, and this signal is subtracted from the output signal of the omnidirectional microphone unit and output. A microphone device characterized in that 7. An omnidirectional microphone unit and a bidirectional microphone unit having the same polarity, the omnidirectional microphone unit having its main axis oriented reversely with respect to the video-integrated camera body, and the bidirectional microphone unit. The unit is arranged with its main axis parallel to the video integrated camera body, the output signal of the bidirectional microphone unit is passed through an equalizer, and the output signal of the omnidirectional microphone unit is subtracted from this signal and output. A microphone device characterized in that 8. An omnidirectional microphone unit and a bidirectional microphone unit having mutually different polarities, wherein the omnidirectional microphone unit has its main axis oriented reversely with respect to the video-integrated camera body, and the bidirectional characteristic. The microphone unit has its main axis arranged parallel to the video integrated camera body, passes the output signal of the bidirectional microphone unit through an equalizer, and adds this signal to the output signal of the omnidirectional microphone unit. A microphone device characterized by being configured to output. 9. The omnidirectional microphone unit and the bidirectional microphone unit are arranged so that the main axes of both units are aligned on a straight line, according to any one of claims 1 to 8. The described microphone device. 10. The non-directional microphone and the bidirectional microphone are fixed so that both units integrally vibrate when vibration is applied to the both units. The microphone device according to 1.