KR900008561B1 - Variable directional mike using for omnidirectional mikes - Google Patents

Abstract

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Description

Variable Directed Circuit Using Omnidirectional Microphone

1 is a characteristic diagram showing the directivity and omni-directional of the microphone.

2 is a circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

M ₁ , M ₂ : Microphone B _1- B ₄ : Buffer

DT: Detector VR1: Variable resistor

3, 4: adder 5, 6: subtractor

10: center sound detector 15: ambient sound detector

S: Center Sound N: Ambient Sound

The present invention provides a video camera or a VTR integrated video camera, by using two omni-directional microphones, an omni-directional microphone which can catch all the captured images and removes the non-imaged sounds by varying the directivity proportional to the angle of view. It relates to the circuit used.

There is a wide-angle shooting method for capturing a subject and its surroundings in a video camera, and a telephoto shooting method for capturing only a subject. I was able to catch all the notes that would be.

In other words, when shooting wide-angle shooting, it is possible to capture the sound only when using the omnidirectional microphone. In this case, the directional microphone cannot catch all the recorded sound. Only the microphone can be used to catch the sound that is being shot, and the omnidirectional microphone will catch the unrecorded sound.

Therefore, in the related art, it is inconvenient to replace the microphone when using the omnidirectional microphone and the directional microphone according to the wide angle and the telephoto photographing state, so that only the captured sound can be captured.

In view of the above, the present invention uses two omni-directional microphones to separate the central sound and the ambient sound, and is linked to the angle of view so that the amount of ambient sound added to the center sound is adjusted so that the omni-directional microphone has a directivity according to the angle of view. The present invention will be described in detail with reference to the accompanying drawings in order to provide a variable directing circuit using an omnidirectional microphone that can be provided with characteristics.

1 is a characteristic diagram showing the directivity and omnidirectionalness of a microphone. The omnidirectional microphone is a sound collected when the microphone 1 is omnidirectional, and the collected sound becomes a telephoto when the microphone 1 is directional. It is suitable for wide angle shooting of wide screen and directional microphone is suitable for telephoto shooting of limited screen.

In other words, if you use a directional microphone in wide-angle shooting, you can only catch a limited sound, and you can't catch ambient sounds.If you use an omni-directional microphone in telephoto shooting, you can only catch a limited sound and catch all the surrounding sounds. .

Therefore, the directional microphone is suitable for telephoto shooting and the omnidirectional microphone is suitable for wide-angle photography.

Therefore, in the related art, only the directional microphone and the omnidirectional microphone can be replaced depending on the angle of view, so that the captured sound can be captured.

In view of the above, the present invention uses the two omnidirectional microphones to configure a circuit as shown in FIG. 2 so as to catch all the photographed sounds regardless of the angle of view.

The center is connected to the amplification buffer (B ₁ ), (B ₂ ) to the omnidirectional microphone (M ₁ ), (M ₂ ) to which the (S) and the ambient sound (N) is applied, respectively, the buffer (B ₁ ), A subtractor 5 and an adder 3 are connected to the output side of B ₂ so as to be connected to the subtractor 6 through the buffer B3 from one side of the output side of the subtractor 5 to the adder 3. The center sound detector 10 is configured such that the output of the subtractor 6 to which the output of the power is applied is fed back to the buffer B ₃ through the detector DT. The peripheral sound detector 15 is configured to connect the variable resistor VR1 linked to the zoom of the video camera through the buffer B ₄ from the output side of the subtractor 5 to the other side. The ambient sound of 15 is applied to the adder 4 and synthesized with the center sound of the center sound detector 10 to be output as an audio signal A0.

Omni-directional microphones (M ₁₎ in the present invention constructed in this manner, (M ₂₎ respectively, the center sound (S) and around the negative (N) when the input to the input to the non-directional microphones _{(M 1), (M 2} ) beeps After the amplification in the buffer (B ₁ ), (B ₂ ), respectively, the following beeps are output to the Norwood points (A) and (B), respectively.

The point A is the sound A = S + aN and the sound of the B point is B = S + bN, where a and b are coefficients that change according to the distance and angle of the surrounding sound (N).

Then, the signal sound output to the Norwood points A and B is applied to the subtractor 5 and the adder 3, respectively, and then applied to the center sound detector 10 and the ambient sound detector 15 after being added and subtracted. do.

At this time, the beep which is subtracted from the subtractor 5 and shown at the nowood point C is C = AB = (ab) N and the beep which is added at the adder 3 and appears at the nowood point D is D = A + B = (a + b) N + 2S.

And the signal sound of the Norwood point (D) is applied to the subtractor 6 of the center sound detection unit 10 and the signal sound of the Norwood point (C) is applied to the subtractor 6 after being amplified in the buffer (B ₃ ) The tones of the Norwood Points (C) and (D) are subtracted from each other and output to the Norwood Point (E).

At this time, the output of the nowood point (E) is fed back to the buffer (B ₃ ) so that the output is minimized by the detector (DT), so that at the nowood point (E), an E = 2S beep is output. S) is detected.

The center sound at the nowood point E finally detected by the center sound detector 10 is applied to the adder 4 to be added to the surrounding sound of the ambient sound detector 15.

On the other hand, the signal sound of the Norwood point (C) is applied to the buffer (B4) of the peripheral sound detector 15 is amplified and distributed by the variable resistor (VR ₁ ) linked to the zoom (ZOOM).

At this time, the variable resistor VR1 is mechanically linked to the zoom of the video camera so that the output of the buffer B ₄ is output as it is to the nod point F during wide-angle shooting, and the buffer B during telephoto shooting. The output of ₄ ) is not output at all to the nod point (F).

That is, the variable resistor VR ₁ is linked to zoom to output all of the output of the buffer B ₄ to the nod point F during wide-angle shooting, and to cut off the output of the buffer B ₄ during telephoto shooting. F) is not output.

At this time, the signal sound of the Norwood point C amplified in the buffer B ₄ is C = (ab) N, so the signal sound of the Norwood point C becomes an ambient sound.

Therefore, the signal sound applied to the adder 4 at the Norwood point F becomes the ambient sound, and the ambient sound becomes louder from the telephoto to the wide angle.

The adder 4 adds the center sound of the nowood point E and the ambient sound of the nowood point F to output the audio signal A ₀ to the nowood point G. The tone of G) becomes G = 2S + 2KN.

Here, K is a coefficient of 0≤K≤1 and is proportional to the angle of view.

That is, the final audio signal A ₀ is output as G = 2S + 2KN, and the center sound and the ambient sound are synthesized and output. However, the amount of the ambient sound is controlled by the variable resistor VR1 linked to the zoom. In the case of wide-angle shooting, the center sound and the surrounding sound are output in a synthesized state, and in this state, the peripheral sound is reduced toward the telephoto shooting, and only the center sound is output.

Therefore, two omni-directional microphones can be used to catch all the shots.

As described above, the present invention uses two omnidirectional microphones to separate the center sound and the surrounding sound and adjust the amount of the ambient sound added to the center sound according to the interlocking angle of view, thereby giving the directivity according to the field of view of the subject. The effect is that you can catch all the sounds that are going to be removed and remove all the unrecorded sounds.

In addition, it is possible to catch all of the sound taken by using two omni-directional microphones, so as to eliminate the inconvenience of using an omni-directional microphone for wide-angle shooting and a directional microphone for telephoto shooting as in the conventional case.

Claims (3)

2 omni-directional microphones (M _1), (M ₂₎ and a microphone unit, consisting of the microphone (M _1), amplifying means for respectively amplifying the signals (M ₂₎ and, for adding or subtracting the amplified signal A first sound adder 3 and a first subtractor 5, an ambient sound detector 15 for varying the output signal of the first subtractor 5 according to a distance, and an output and a first output of the first adder 5; A center sound detector 10 for subtracting the output of the first subtracter 3 and controlling the output thereof to a minimum; a second adder for adding the output of the center sound detector 10 and the output of the ambient sound detector 15; Variable directing circuit using an omnidirectional microphone composed of (4). The method of claim 1, wherein the output of the first subtractor (5) is subtracted from the output of the first adder (3) via an amplifier and the output is fed back to the detector (DT) so that the gain of the amplifier in the detector (DT) is obtained. A variable direct-circuit circuit using an omni-directional microphone equipped with a center sound detection unit 10, characterized in that to vary according to the output to minimize. The peripheral device of claim 1, wherein the zoom device of the video camera and the variable resistor VR ₁ are linked to each other to output all the outputs of the buffer B ₄ during wide-angle imaging, but to be blocked during telephoto imaging. A variable directivity circuit using an omnidirectional microphone provided with a sound detector (15).

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