KR830001618B1 - Variable Directional Microphone Device - Google Patents

Abstract

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Description

Variable Directional Microphone Device

1 (a) and 1 (b) are partial front and side views of an embodiment of the variable-directional microphone according to the present invention applied to a television camera equipped with a zoom lens.

FIG. 2 is a layout view of a primary unidirectional microphone overlying the microphone portion shown in FIGS. 1 (a) and 1 (b).

3 is an individual four frequency characteristic diagram of the microphone shown in FIG.

4 is a circuit diagram for varying the mixing ratio of the output of the microphone shown in FIG.

5 is a principle diagram for explaining the directivity characteristics of the omnidirectional and primary directivity of the microphone shown in FIG.

FIG. 6 is a directed characteristic diagram of omnidirectional, primary and secondary unidirectional obtained actually by the circuit shown in FIG.

7 is a principle diagram for explaining the directivity characteristic of the secondary unidirectionality of the microphone shown in FIG.

FIG. 8 is a frequency characteristic diagram of the second order unidirectional obtained by the microphone shown in FIG. 2. FIG.

9 (a) and 9 (b) show partial front views in which an embodiment of the microphone of the present invention is applied to a television camera having a structure different from that shown in FIGS. 1 (a) and 1 (b), respectively. Side view.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a variable-directional microphone device, wherein a combination of three single directional microphones is provided, and the output from each microphone is mixed and the mixing ratio is varied so that the directivity can be varied widely and has a sufficient sense of distance. An object of the present invention is to provide a microphone capable of zooming in sound.

As a method of varying the directivity of a conventional microphone, there is an example in which two unidirectional microphones are connected to each other by connecting them to each other to mix outputs and vary the mixing ratio so that the directivity can be changed from omnidirectional to unidirectional or bidirectional. There was a drawback that the range of change was narrow and sound zooming with sufficient distance sense could not be obtained.

The present invention removes the above drawbacks, one embodiment of the present invention will be described below with reference to the drawings.

1 (a) and 1 (b) show partial front and side views respectively applied to a television camera having a zoom lens system as one embodiment of the variable-directional microphone according to the present invention. In the figure (1), a zoom lens system is attached to the camera main body (2), a distance ring (3) coaxially mounted thereon, a zoom ring (4) provided with gears on the circumference thereof, and a zoom ring operating lever ( 5) is attached, and by operating this, the zoom ring 4 is rotated so that the maximum distance of the zoom lens system 1 can be varied. (6) as a contribution on the coaxial axis of the zoom lens system (1)

Here, in the case of manual operation, by rotating the lever 5, in the case of automatic operation, the gears 6 and 10 are rotated by the rotation of the motor 7 so that the variable resistor section 9 The directivity of the microphone provided in the microphone section 12 is varied by displacing the volume described later in which is installed.

As shown in FIG. 2, the microphone unit 12 includes a microphone 12a having a primary sound pressure intensity unidirectional (hereinafter referred to as a primary unidirectional) with respect to the sound source 13 and a primary unidirectional microphone 12c. ) Is directed to the front side, and the primary unidirectional microphone 12b is installed to the rear side. The microphone 12a is installed on the same axis as the microphone 12c such that its diaphragm is 3 to 4 cm from the diaphragm of the microphone 12c and its diaphragm is in the same plane as the diaphragm of the microphone 12b. These primary unidirectional horses

In this case, when the subject is zoomed from a long distance, the directivity of the microphone unit 12 is accompanied by (1) nondirectional → (2) primary unidirectional → (3) secondary sound pressure hardness monodirectional (hereinafter referred to as “secondary monodirectional”). For the sake of simplicity, the description is divided into two steps. First, in the case of varying from (1) omni-directional to (2) primary single-directional, the sliding actuators of the volumes VR ₁ to VR ₅ are displaced from the position of ① to the position of ② with the operation of the lever 5. At this time, in the position of ① in front of the sound source (13)

In addition, according to the arrangement as shown in FIG. 2, the directivity pattern of the microphone 12a is as shown in the curve (II) of the curve 12 in FIG. 5, and the directivity pattern of the microphone 12b in FIG. The directional pattern in the case where the output of the microphone 12a is mixed with the output of the microphone 12b by the circuit shown in Fig. 1 is as shown by the curve III. With respect to this directivity synthesis, the angle formed between the main axes of the microphones 12a and 12b and the sound source 13 is θ, and the mixing point just before the buffer amplifier 16 of the output taken out from the microphone 12a. When the ratio B / A of the gain A up to and the gain B from the microphone 12b to the mixing point of the output taken out is α, the directional pattern when the output of the microphone 12a of the output angle microphone 12b of the microphone 12a is synthesized. P is

In particular, in the case where the activators of the volumes VR ₁ to VR ₅ are in ① as described above, since they are the same as the gains in the respective systems as described above, α = P① is

Appears and becomes omnidirectional.

When the movers of the volumes VR ₁ to VR ₅ are displaced from the positions ① to ②, the gain of the amplifier 15b is attenuated as shown in IV in FIG. Directivity pattern

로 되고, 단일지향성(1차 단일지향성)으로 된다. 여기에 있어서, Ⅳ가 도시된 그래프의 우측눈금은, VR₁의 저항치변화를 나타낸 것으로, 저항치 R은 볼륨 VR₁의 접지측(이 경우에서는 ③측)으로부터 본 습동자의 저항치 R의 변화를 나타낸 것이다. 즉, 습동위치 ①에 있어서는, 저항치가 예로서, 20kΩ 0Ω이며, ②에 근접함에 따라 저항은 작게되고, ②의 위치에서는 이 경우 0Ω으로 된다.P② is P② =

To be unidirectional (primary unidirectional). In here, Ⅳ the right scale of the illustrated graph, illustrates the resistance changes in the VR _1, the resistance R is shown a change in the resistance value R of the wet follower from (in this case ③ side) side of the ground of the volume VR ₁ will be. That is, in the sliding position ①, the resistance value is, for example, 20 k? 0?, The resistance decreases as it approaches?, And in this case 0?

On the other hand, even if the mover moves from the position of ② to the position of ③, the resistance value for the swinger viewed from the ground side end of VR ₁ is configured to remain unchanged while keeping 0? On the other hand, in the range in which the movers of VR ₁ to VR ₅ are displaced from the positions ① to ②, the gain of the amplifier 17 does not attenuate as shown by V in FIG. 4, and the gain of the amplifier 18 is As shown in VI, it becomes zero. The signal from which the output from the microphone 12a and the output from the microphone 12b are combined is amplified by the amplifier 17 through the buffer amplifier 16, and has a gain as shown in FIG. In 19), the level is gradually amplified and taken out from the output terminal 20.

Here, the directional pattern actually obtained at the frequency 1 kH ₂ is shown in FIG. 6 in the range (non-directional → primary unidirectional) in which the movers of the volumes VR ₁ to VR ₅ are displaced from the positions ① to ②.

The curve VII of FIG. 6 is an omnidirectional pattern, which corresponds to curve III of FIG. 5, and the curve VII is a first-order monodirectional pattern, which corresponds to curve I of FIG. 5, with omnidirectional to primary unidirectional with zooming operation. Slowly the directivity becomes sharp.

Next, in the case of varying from the first single directionality of ② to the second single directionality of ③, the sliders of the volumes VR ₁ to VR ₅ are displaced from the position of ② to ③ with the operation of the lever 5. By this. The gain of the amplifier 15b becomes zero as shown by IV in FIG. 4, and the gain of the amplifier 15c increases as shown by X, so that only the output of the microphone 12a and the output of the microphone 12c are shown. Are mixed.

를 K, 마이크로폰(12a)의 진동판과 마이크로폰(12c)의 진동판과의 거리를 D로 하면, 마이크로폰(12a)의 출력으로부터 마이크로폰(12c)의 출력을 감산[마이크로폰 (12a)의 출력과 마이크로폰(12c)의 출력을 역상으로 합성]한 지향성 패턴 P는 P=A.e

-C.ejcwt+KD cosθ

로 된다. 상기식중 주파수를 파라미터로 하여 θ를 변수로 간주하면 상기식은The angle formed between the main side l of the microphones 12a and 12c and the sound source 13 is θ, and the gain to the above-described mixing point of the output taken out of the microphone 12a is A, the output of the output taken out of the microphone 12c. The gain to the mixing point is C, the ratio of the angular velocity hair W and the sound velocity V (wavelength constant)

If K is the distance between the diaphragm of the microphone 12a and the diaphragm of the microphone 12c as D, the output of the microphone 12c is subtracted from the output of the microphone 12a (the output of the microphone 12a and the microphone 12c). The directivity pattern P, which combines the output of

-C.ejcwt + KD cosθ

It becomes If θ is regarded as a variable with frequency as a parameter,

P ₃ = M (1 + cosθ) {1-cos (KD cosθ)}. M is an integer generated when the equation is modified.

In the above, when gains A and C are equal

3 정도 범위의 저향특성이 제7도에 도시한 바와같이 되고, 그의 주파수 특성은 제8도에 도시한 바와같이 된다. 이와같은 지향성을 2차 음압경도 단일지향성(2차 단일지향성)이라하는데, 무지향성 경우의 거리계수를 1로 한 경우, 1차단일 지향성의 경우의 거리계수는 1.73인 것에 대해 2차 단일지향성의 경우의 거리계수는 2.81로 되어 1차 단일지향성보다도 더욱 지향성이 예민하게 될 수 있다.In the above formula, KD

The resistance characteristic in the range of about 3 degrees becomes as shown in FIG. 7, and its frequency characteristic becomes as shown in FIG. Such directivity is called secondary sound pressure unidirectional (secondary monodirectional). When the distance coefficient in the non-directional direction is 1, the distance coefficient in the first-directional single direction is 1.73. In this case, the distance coefficient is 2.81, which makes the directivity more sensitive than the primary unidirectionality.

On the other hand, in the range in which the sliders of the volumes VR ₁ to VR ₅ are displaced from the positions ② to ③, the gain of the amplifier 17 increases as shown by V in FIG. 4, and the output of the microphone 12a is increased. The signal from which the output of the microphone 12c is synthesized is amplified in the amplifier 18 through the buffer amplifier 16, frequency compensated in the equalizing circuit 21 by a resistor and a capacitor, and the level is amplified more slowly in the amplifier 19. It is taken out from the output terminal 20. In this case, when mixing the output of the microphone 12a and the output of the microphone 12c, the ratio of these outputs is mixed.

Here, the directivity pattern actually obtained at the frequency 1 KHz is shown in FIG. 6 in the range (first-order single topography → second-order directivity) in which the movers of the volumes VR ₁ to VR ₅ are displaced from the positions ② to ③. In-motion curve XI is a second order unidirectional pattern, which gradually becomes sharper from first unidirectional to second unidirectional as the zooming operation.

α

1의 범위에 걸쳐 변화시켜 무지향성으로부터 1차 단일지향성을 얻고, 마이크로폰(12a)의 출력과 마이크로폰(12c)의 출력과의 혼합비 β를 0

β

1의 범위에 걸쳐 변화시켜 1차 단일지향성으로부터 2차단일지향성을 얻을 수가 있어, 종래의 것보다도 지향성 변화범위를 넓게취 할 수가 있고 화면의 줌잉에 수반하여 지향성을 무지향성으로부터 2차단일지향성까지 가변시키는 것에 의하여 충분한 거리감을 갖고서 음상을 줌잉할 수 있으며, 한편, 음량도 서서히 증대시킬 수 있어 화상과 음과의 극히 자연스러운 일체감을 얻을 수가 있다. 또, 줌엎하고 있을때에, 그의 영상과 관계가 없는 음은 수음되지 않기 때문에 자연스러운 회면을 얻을 수가 있다.As described above, according to the microphone of the present invention, the mixing ratio α between the output of the microphone 12a and the output of the microphone 12b is 0 by varying the volumes VR ₁ and VR ₂ accompanying the zooming operation.

α

Changed over a range of 1 to obtain first order unidirectionality from nondirectional, and zero mixing ratio β between the output of microphone 12a and the output of microphone 12c.

β

By varying over a range of 1, it is possible to obtain 2nd single directionality from 1st unidirectionality, and it is possible to take a wider range of directivity change than the conventional one, and from directivity to 2nd unidirectional with zooming of the screen. By varying, the sound image can be zoomed with a sufficient sense of distance, and on the other hand, the volume can also be gradually increased to obtain an extremely natural sense of unity between the image and sound. In addition, when zooming in, a sound that is not related to his video is not picked up, so a natural reflection can be obtained.

In addition to the microphones 12a to 12c arranged as shown in FIG. 2, an appropriate number of microphone photophones are provided, and an amplifier or volume is provided in response to this in the circuit shown in FIG. Tertiary, quaternary, ... monodirectional more than unidirectional can be obtained, but in practice it is sufficient to obtain second unidirectional.

9 (a) and 9 (b) respectively show an embodiment of the variable-directional microphone according to the present invention applied to a television camera having a structure different from that shown in FIGS. 1 (a) and 1 (b). The front view and the side surface are shown, The same code | symbol is attached | subjected to the part which has the same function in FIG. 1 (a) and 1 (b), and the description is abbreviate | omitted. 11 'is a control part, inside which the variable resistor part 9, the gear 10 attached to the rotating side, and the gear 22 which meshed with the gear 10 and protruded downward from the lower surface are provided, And a circuit as shown in FIG.

In addition, the zoom ring 4, the gears 6, 8, 10, and 22 do not necessarily have to be gear shape. As an example, a member having high viscosity such as rubber on a circumference may be adhered to each other and pressed against each other.

In addition, the variable resistor unit 9 can be used for linearly displacing or circularly displacing without being limited to rotational displacement.

Moreover, the microphone of the present invention can also be used for other things applicable to a television camera equipped with a zoom lens system.

As described above, the variable-directional microphone according to the present invention is provided by combining three primary single-directional microphones, mixing the microphone outputs respectively, and varying the mixing ratio thereof by a predetermined amount so that the primary sound pressure hardness single directivity, 2 Since the sound pressure gradient is also unidirectionally variable, the directivity can be varied widely, zooming can be performed with a sufficient sense of distance, and a combination of the three microphone groups is installed in a camera equipped with a zoom lens system, and the mixing ratio can be adjusted. As it is set to change in response to zooming operation, in 8 millimeter camera or VTR camera etc., we can zoom in sound image with screen zooming, and we can get extremely natural unity with image and sound, and microphone of original beforehand To install, switch or blend them as you zoom. In addition, it is easier to operate than the method of changing the directivity by using two microphones, and the sound zooming with a sufficient sense of distance can be obtained, and the sound that is not related to his image is not picked up when it is zoomed. The screen can be obtained.

Claims (1)

11. A directional microphone device for outputting a signal such that the directivity is changed by mixing and synthesizing the outputs of a plurality of unidirectional microphones, the directional microphone device comprising: primary sound pressure hardness unidirectional microphones (12a, 12b, 12c); A mixing circuit (VR ₁ , VR ₂ , 15b, 15c, 22a, 22b, 22c) having variable resistors (VR ₁ , VR ₂ ) for varying the mixing ratio of the output signals of the microphones; Frequency characteristic compensation circuits VR ₃ , VR ₄ , 17, 18, 21 having variable resistances VR ₁ , VR ₂ for performing frequency characteristic compensation of the output signal of the mixed circuit; A variable-directional microphone device characterized by a variable resistor (VR ₅ ) for increasing or decreasing the output of the frequency characteristic compensation circuit.

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