This invention relates to a microphone apparatus for a video camera which is equipped with an optical zoom lens and microphones to provide video and audio signals to a video tape recorder. More particularly, this invention relates to a microphone apparatus according to the preamble of claim 1, the directivity of which can be varied in accordance with the control of the zoom lens to suitably match images and sounds.

Microphone apparatus for producing acoustic zoom effects on the basis of monaural sound recording in which the directivity or both the directivity and the sensitivity of a microphone are varied have been proposed (for example, Y. Ishigaki et al.: "Zoom Microphone" presented at the 67th Convention of the Audio Engineering Society (Oct. 31 to Nov. 3, 1980), pre-print 1713 (A-7), and US-A-3,837,736).

In such microphone apparatus, it is impossible to harmonize the working angle of the microphone with the zooming magnification of the zoom lens, resulting in that reproduced sounds are not adequately matched with reproduced images. This imbalance between the working angle and the zooming magnification will be described below by way of illustrating a video camera having a zoom lens of ten magnification and a microphone having a variable directivity (from omnidirectional to second order pressure gradient unidirectional through unidirectional). The viewing angle of the zoom lens of ten magnification in the telescopic state is very narrow (about 4 degrees), while it is about 40 degrees in the wide viewing angle state. The working angle at half maximum of the variable-directivity microphone is 360 degrees in the omnidirectional state, 180 degrees in the unidirectional state, and 100 degrees in the second order pressure gradient unidirectional state (i.e., the telescopic state). Namely, the working angle of the variable-directivity microphone is very wide in comparison with the viewing angle of the zoom lens. When defining an acoustic zooming magnification of a microphone as the ratio of the distance factor in the wide viewing angle mode to that in the telescopic mode, the acoustic zooming magnification of the above-mentioned variable-directivity microphone is about 2.7, i.e., the acoustic zooming magnification of the microphone is very much smaller than the zooming magnification of the optical zoom lens. The distance factor means a distance from a sound source to a directional microphone which is positioned so as to produce noise and echo signals equivalent to those obtained in an omnidirectional microphone separated from a sound source by a unit distance. The distance factors of an omnidirectional microphone, a unidirectional microphone and a second order pressure-gradient microphone are 1, about 1.7 and about 2.7, respectively (see, for example, "An Anthology of Articles on Microphones" from the pages of the Journal of the Audio Engineering Society vol. 1-vol. 27 (1953-1979)", p.62). To eliminate the above-mentioned imbalance, the development of a superdirectional microphone having an extremely sharp directivity is essential. With the present technology, however, it is impossible to realize a microphone having such a directivity and the capability of being built into a video camera which must be compactly constructed.

A microphone apparatus which can produce acoustic zoom effects on the basis of two-channel stereo sound recording is known. An apparatus of this type is disclosed as a stereo sound processor for television broadcasting, in US-A-4,594,610. This processor is designed to use two microphones to conduct a stereo recording. The two microphones are disposed on the right and left of a stage, separately from a video camera, to generate microphone signals L and R from which a sum signal (L+R) and a difference signal (L-R) are produced. In order to produce monophonic sounds in the telescopic mode and stereophonic sounds in the wide viewing mode, the mixing ratio of the sum signal (L+R) and the difference signal (L-R) is controlled in accordance with the control of the zoom lens of the video camera, so that the monophonic sum signal (L+R) is greater than the difference signal (L-R) in the telescopic mode, and, to the contrary, the difference signal (L-R) is greater than the monophonic sum signal (L+R) in the wide viewing angle mode. This apparatus can solve a problem in a two-channel stereo recording and reproducing system in which the sum signal (L+R) and the difference signal (L-R) are delivered without any processing, which problem is that, when images and sounds are recorded simultaneously by panning the video camera to the left and zooming in, the zoomed subject is displayed largely in the center on the television image, but the sound is delivered only from the left loudspeaker.

In such an apparatus, since the microphone is not installed on the video camera, the pan operation of the video camera is performed regardless of the direction of the principal axis of the directivity of the microphone. When the sound source is positioned in the panned direction, therefore, no problem is caused. But, when the sound source is not in the panned direction, the displayed image and the reproduced sound fail to coincide with each other. Even if the apparatus is installed on the video camera and a microphone having any directivity is employed, as far as the processing is executed on the basis of the two signals L and R, it is difficult to simultaneously satisfy both the quality (such as the localization, spaciousness and perspective) of stereo sounds required in the wide viewing angle mode and the quality (such as clearness) of monophonic sounds required in the telescopic mode, resulting in that either quality must be ignored.

A conventional microphone apparatus, for example, disclosed in the above-mentioned three prior art references is provided with a signal means for generating a signal corresponding to the zooming magnification of the zoom lens. This signal means comprises a potentiometer the resistance of which can be changed by sliding a contactor which is driven in accordance with the movement of the zoom lens, through a means mechanically interconnecting the contactor and the zoom lens.

A conventional microphone apparatus provided with such a signal means has a problem in that mechanical vibrations propagate through the casing or the space to the microphone to generate noise signals. Since the resistance of the potentiometer must be high in view of the power consumption, the level of the noise electromagnetically induced in the potentiometer is so high that the noise is mixed into the signals of the microphone. In the potentiometer, moreover, ncises are generated when the contactor of the potentiometer is slid, to be mixed into the signals of the microphone. Besides, a pctentiometer, which is a slide-type variable resistor, has problems in reliability and reproducibility, resulting in that a potentiometer is not suitable to be used as a part which is frequently operated.

From GB-A-1,116,746 a microphone apparatus according to the preamble of claim 1 is known. This microphone apparatus includes a potentiometer which regulates the voltage supply to two microphones. This potentiometer controls the amplification of microphone signals in accordance with a position signal which is derived from position sensors arranged in connection with the lens system of a video camera. This position sensor or zoom position detection means functions on the basis of the interaction of mechanical and electrical portions.

It is the object of the present invention to provide a microphone apparatus which is able to measure the values to adjust the sound in accordance to the setting of the zoom lens in an approved manner.

This object is solved by the microphone apparatus according to claim 1. Advantageous embodiments of the microphone apparatus according to the invention are defined by the features listed in the subclaims.

In a preferred embodiment, the zoom position detection means detects the zoom position of said zoom lens without making mechanical contact with said zoom lens.

In a preferred embodiment, the first and second signal means further comprise an analog multiplexer which selects one of channels in accordance with a digital signal, and each of said first and second control signals is a DC signal the level of which corresponds to said selected channel.

In a preferred embodiment, the first and second signal means further comprise: an analog multiplexer which selects one of channels in accordance with a digital signal; a reference voltage source connected to the common terminal of said analog multiplexer; resistors one end of each of which is connected corresponding one of said channels of said analog multiplexer; and a reference resistor, one end of said reference resistor being connected to other end of each of said resistors, and the other end of said reference resistor being grounded.

In a preferred embodiment, at the wide viewing angle zoom position of said zoom lens, the mixing ratio of said stereo sound pickup signals is set to 100%, and the mixing ratio of said superdirectional sound pickup signal is set to 0%, and, at the telescopic zoom position of said zoom lens, the mixing ratio of said stereo sound pickup signals is set to 0%, and the mixing ratio of said superdirectional sound pickup signal is set to 100%, said mixing ratios being varied within said ranges in proportion to the variation of the viewing angle of said zoom lens.

In a preferred embodiment, the first and second sum signals are varied in proportion to a power of a zooming magnification of said zoom lens.

In a preferred embodiment, the first and second sum signals are varied in proportion to a power ranging 0.3 to 0.5 of a zooming magnification of said zoom lens.

In a preferred embodiment, at the wide viewing angle zoom position of said zoom lens, the mixing ratio of said stereo sound pickup signals and is set to 100%, and the mixing ratio of said superdirectional sound pickup signal is set to 0%, and, at the telescopic zoom position of said zoom lens, the mixing ratio of said superdirectional sound pickup signal is set to be larger than the mixing ratios of said stereo sound pickup signals, said mixing ratios being varied within said ranges in proportion to the variation of the viewing angle of said zoom lens.

In a preferred embodiment, the zoom position detection means further comprises: two reflector areas formed on the outer periphery of a zoom ring of said zoom lens, each of said reflector areas being formed by a material of a high reflection index material and having a triangle shape which elongates along the rotation direction of said zoom ring; a light emitting means for irradiating light on said reflector areas; and a light receiving means for detecting light reflected from each reflector areas, and said first and second control signals are analog signals.

Thus, the invention described herein makes possible the objectives of:

• (1) to provide a microphone apparatus for a video camera which can record sounds adequately matched with images;
• (2) to provide a microphone apparatus for a video camera which can record sounds with excellent acoustic zooming effects;
• (3) to provide a microphone apparatus for a video camera in which noise due to the operation of the zoom lens can be prevented from being generated;
• (4) to provide a microphone apparatus for a video camera which is excellent in reliability;
• (5) to provide a video camera which can record sounds adequately matched with images;
• (6) to provide a video camera which can record sounds with excellent acoustic zooming effects;
• (7) to provide a video camera in which noise due to the operation of the zoom lens can be prevented from being generated;
• (8) to provide a video camera which is excellent in reliability.

This invention may be better understood and its numerous objects and advantages will become apparent to those skilled in the art by reference to the accompanying drawings as follows:

Figure 1 is a block diagram of a microphone apparatus according to the invention.

Figure 2a shows a reflector pattern formed on the zoom ring of the zoom lens in the apparatus of Fig. 1.

Figure 2b is a circuit diagram of the zooming magnification detection means.

Figure 3 is a circuit diagram illustrating the first and second signal means.

Figure 4 is a graph showing the relation between the control voltage and the attenuation in the first, second and third amplifying means.

Figure 5 is a graph showing a preferable relation between a viewing angle of the zoom lens and the mixing ratio of the superdirectional sound pickup signal to the stereo sound pickup signal.

Figure 6 is a graph showing preferable relations between a zooming magnification of the zoom lens and the magnitudes of the sum signals supplied from the first and second adding means.

Figure 7 is a graph showing the relation between the viewing angle of the zoom lens and the rotation angle of the zoom ring.

Figure 8 is a graph showing the relation between the viewing angle and the zooming magnification of the zoom lens.

Figure 9 is a diagram showing the relation between the viewing angle and the mixing levels of the the superdirectional sound pickup signal and stereo sound pickup signal, when the zoom lens having the properties shown in Figs. 7 and 8 and the mixing is conducted under the relations shown in Figs. 5 and 6.

Figure 10 is a graph showing another preferable relation between a viewing angle of the zoom lens and the mixing ratio of the superdirectional sound pickup signal to the stereo sound pickup signal.

Figure 11a is a block diagram of another microphone apparatus according to the invention.

Figure 11b shows a reflector pattern formed on the zoom ring of the zoom lens in the apparatus of Fig. 11a.

Figure 11c is a diagram illustrating the zoom position detection means of the apparatus of Fig. 11a.

Figure 1 is a block diagram of a microphone apparatus for a video camera according to the invention. The microphone apparatus of Fig. 1 comprises an optical zoom lens 1, a superdirectional sound pickup means 2, a stereo sound pickup means 3, a zoom position sensor 4, first and second mixing control circuits 5 and 6, and first to third amplifiers 7 - 9.

The zoom lens 1 incorporates a lens optical system 100 for focusing the light from an object, and a photoelectric converting device 200 for converting the image of the object formed by the lens optical system 100 into electric signals. The lens optical system 100 is a conventional optical system composed cf plural fixed and movable lens elements. A typical example of the photoelectric converting devices 200 is a charge coupled device (CCD). The output signals of the photoelectric converting device 200 are supplied to a video signal processing circuit 300 and processed therein in a usual manner to be converted into image signals such as composite television signals, RGB signals, and two-channel component signals composed of luminance signals and color signals.

The superdirectional sound pickup means or microphone 2 and the stereo sound pickup means or microphone 3 are disposed so that their front faces are directed along the center line of the viewing angle of the zoom lens 1. The superdirectional microphone 2 picks up the sound field existing in a narrow range in its frontal direction, and produces a monaural superdirectional sound pickup signal D. The stereo microphone 3 picks up the sound field existing in a wide range in its frontal direction, and generates stereo sound pickup signals L and R.

The zoom lens 1 is provided with a zoom ring 21 which can be rotated to vary the focal length of the zoom lens 1. The focal length corresponds, as shown in Fig. 7, uniquely to the rotation angle of the zoom ring 21. Namely, when rotating the zoom ring 21 in one direction, the viewing angle varies from the wide viewing angle to the telescopic, or, to the contrary, when rotating the zoom ring 21 in the reverse direction, the viewing angle changes from the telescopic to the wide viewing angle. The zoom ring 21 can be rotated not only by a manual operation but also by a motor-driven operation. A gear G1 formed at one end of the zoom ring 21 is meshed with a gear G2 mounted on the shaft of a driving motor 20 so that the rotation of the driving motor 20 energized by a power source B1 is transmitted to the zoom ring 21 through the gears G1 and G2. The modes of zoom-in and zoom-out are changed over by switching over the rotation direction of the driving motor 20 by a switch SW1.

The circumferential surface of the zoom ring 21 is formed by a black material of a low reflection index. A reflector 22 patterned as shown in Fig. 2a has an elongated rectangular shape and is formed on the surface of the zoom ring 21. The zoom position sensor 4 comprises three reflection type photosensors which, as shown in Fig. 2b, are arranged so as to face the reflector 22, and detect the rotation angle of the zoom ring 21 to deliver a 3-bit digital zoom position signal (A0, A1, A2).

The first mixing control circuit 5 is connected to the zoom position sensor 4, and receives the zoom position signal (A0, A1, A2) to produce a first control signal Vc1 of a DC voltage the level of which corresponds to the zoom position signal (A0, A1, A2) (Fig. 3). Similarly, the second mixing control circuit 6 is connected to the zoom position sensor 4, and receives the zoom position signal (A0, A1, A2) to produce a second control signal Vc2 of a DC voltage the level of which corresponds to the zoom position signal (A0, A1, A2).

The first voltage control amplifier 7 has an attenuation-control voltage characteristic shown in Fig. 4. The amplifier 7 is connected to the super-directional microphone 2 and the first mixing control circuit 5 to receive the superdirectional sound pickup signal D and the first control signal Vc1. The amplifier 7, by using the first control signal Vc1 as a control signal, multiplies the magnitude of the superdirectional sound pickup signal D by K1, and outputs the product (k1·D). Likewise, the second voltage control amplifier 8 is connected to the stereo microphone 3 and the second mixing control circuit 6 to receive the stereo sound pickup signal L and the second control signal Vc2. The second amplifier 8, by using the second control signal Vc2 as a control signal, multiplies the magnitude of the stereo sound pickup signal L by K2, and outputs the product (K2·L). The third voltage control amplifier 9 is linked to the stereo microphone 3 and the second mixing control circuit 6, and receives the stereo sound pickup signal R and the second control signal Vc2. The third voltage control amplifier 9, by using the second control signal Vc2 as a control signal, multiplies the magnitude of the stereo sound pickup signal R by K2, and outputs the product (K2·R).

The output signal (K1·D) of the first amplifier 7 and the output signal (K2·L) of the second amplifier 8 are supplied to a first adder 10, and the output signal (K1·D) of the first amplifier 7 and the output signal (K2·R) of the third amplifier 9 are supplied to a second adder 11. The first adder 10 adds the output signal (K1·D) and the output signal (K2·L) to produce a first sum signal (K1·D+K2·L). The second adder 11 adds the output signal (K1·D) and the output signal (K2·R) to produce a second sum signal (K1·D+K2·R).

The construction and operation of the microphone apparatus of Fig. 1 will be described in more details.

Figure 2a shows the pattern of the reflector 22. The reflector 22 comprises a first reflector area 22a, a second reflector area 22b and a third reflector area 22c. In each of the reflector areas, one or more portions of a high reflection index (black regions in Fig. 2a) and one or more portions of a low reflection index (white regions in Fig. 2a) are arranged along the rotation direction of the zoom ring 21. The lateral direction in the drawing corresponds to the rotation direction of the zoom ring 21. The left end corresponds to the wide viewing angle zoom position, and the right end to the telescopic zoom position. The high reflective portions consist of aluminum, and the untreated surface of the zoom ring 21 constitutes the low reflective portions. The three reflector areas 22a - 22c which consist of high reflective and low reflective portions are arranged as shown in Fig. 2a, so that 3-bit (i.e., 8-stage) digital data on the rotation angle of the zoom ring 21 can be obtained. In this embodiment, the reflector 22 is patterned so that seven separate data a to g on the rotation angle of the zoom ring 21 can be obtained in sequence along the direction from the wide viewing angle side to the telescopic side. It is obvious for those skilled in the art that, when the reflector 22 is patterned so as to produce signals of a larger number of bits, more detailed information about the rotation angle of the zoom ring 21 can be obtained, thereby enabling the microphone apparatus to be controlled more precisely.

Figure 2b shows the relation between the zoom position sensor 4 and the reflector areas 22a - 22c. Reflection type photosensors 30, 31, 32 each of which is provided with a light emitting diode LED and a phototransistor PT are disposed to face the reflector areas 22a, 22b, and 22c, respectively. Each light emitting diode LED is connected to a load resistor Rs, and driven by a power source B2 to emit light the amount of which corresponds to the level of a forward current. Each phototransistor PT is connected to a load resistor Rd, and driven by the power source B2 to generate a current the level of which corresponds to the amount of light incident thereon, resulting in that a voltage appears across the load resistor Rd. In the photosensor 30, the light emitting diode LED constantly emits light the amount of which corresponds to the forward current level, toward the reflector area 22a, and the phototransistor PT detects the reflected light from the reflector area 22a, and converts the detected light into electric signals which are then supplied to an amplifier 33. Since the amount of the reflected light from the reflector area 22a varies in accordance with the pattern facing the photosensor 30, the output of the phototransistor PT is a binary signal the value of which varies corresponding to the rotation angle of the zoom ring 21. The amplifier 33 amplifies the signal to produce a zoom position signal A0. In the same way, the photosensors 31 and 32 respectively generate electric signals corresponding to the pattern of the reflector areas 22b and 22c. Amplifiers 34 and 35 amplify the signals from the photosensors 31 and 32 to produce zoom position signals A1 and A2. The signals A0, A1 and A2 constitute a 3-bit zoom position signal (A0, A1, A2) which represents the rotation angle of the zoom ring 21 and is supplied to the first and second mixing control circuits 5 and 6. In this embodiment, the zoom position sensor 4 is designed so as to constantly detect the zoom position. Alternatively, the sensor 4 may be designed so as to detect the zoom position intermittently.

Figure 3 illustrates the first and second mixing control circuits 5 and 6. The first mixing control circuit 5 supplies a first control voltage Vc1 to the first voltage control amplifier 7 which controls the mixing level of the superdirectional sound pickup signal D. The second mixing control circuit 6 supplies a second control voltage Vc2 to the second and third voltage control amplifiers 8 and 9 which control the mixing levels of the stereo sound pickup signals L and R. A multiplexer 40 of the first mixing control circuit 5 and a multiplexer 41 of the second mixing control circuit 6 can control an eight-channel analog switch in accordance with 3-bit digital signals.

In the first mixing control circuit 5, a common terminal COM of the multiplexer 40 is connected to a DC power source from which a predetermined voltage B3 is supplied. To terminals X1 - X7 of the multiplexer 40, resistors R1 - R7 are connected respectively. The other ends of the resistances R1 - R7 are bundled together and connected to a resistor R0 the other end of which is grounded. The multiplexer 40 receives the 3-bit zoom position signal (A0, A1, A2) from the zoom position sensor 4, and selects one of the terminals X1 - X7 in accordance with the value of the zoom position signal. The multiplexer 40 is designed so as to select the terminal X1 when receiving the zoom position signal (A0, A1, A2) corresponding to the zoom position a of the reflector 22, and to select one of the terminals X2 - X7 when receiving the zoom position signal (A0, A1, A2) corresponding to one of the zoom positions b - g. Figure 3 shows the state where the common terminal COM is connected to the terminal X2 corresponding to the zoom position b. In this state, the level of the first control signal Vc1 is given by {B3·R2/(R2+R0)} where R2 and R0 are resistance values of the resistor R0 and R2, respectively. In this way, one of the resistors R1 - R7 is selected in response to the detected one of the zoom positions a - g so that the level of the first control signal Vc1 can be selected. Therefore, it is possible to freely set the mixing level of the superdirectional sound pickup signal D.

In the second mixing control circuit 6, similarly, the common terminal COM of the multiplexer 41 is connected to the same DC power source which supplies the predetermined DC voltage B3. To terminals X1 - X7, resistors R11 - R17 are connected respectively. The other ends of the resistors R11 - R17 are bundled together and connected to a resistor R10 the other end of which is grounded. The multiplexer 41 is designed so as to select one of the terminals X1 - X7 when receiving the zoom position signal (A0, A1, A2) corresponding to one of the zoom positions a - g. The second control signal Vc2 at each zoom positions, which will be supplied to the second and third voltage control amplifiers 8 and 9, is given by the division of the voltage B3 through a combination of the resistor R10 and one of the resistors R11 - R17, so that the level of the second control signal Vc2 can be selected. Therefore, it is also possible to freely set the mixing level of the stereo sound pickup signals L and R.

Figure 4 illustrates the relation between the control voltage and the attenuation in the first, second and third voltage control amplifiers 7, 8 and 9. A voltage control amplifier has a control terminal for controlling the amplification factor, and the amplification factor is controlled by applying a DC voltage to the control terminal. In Fig. 4, a curve 200 indicates the attenuation-control voltage characteristic of the amplifiers 7, 8 and 9. The axis of abscissas indicates the control voltage in the unit of volts. The axis of ordinates denotes the attenuation expressed in decibels. In these voltage control type amplifiers, when the control voltage is 0V, the attenuation is 0dB. The attenuation is increased with the increase of the control voltage, and the attenuation of 80dB can be achieved at the control voltage of about 2.5V. The gradient of the curve 200 in the straight line region is about -34dB/V. The amplifiers 7, 8 and 9 having such characteristics can control the mixing ration of the superdirectional sound pickup signal D and the stereo sound pickup signals L and R, in accordance with the control signals Vc1 and Vc2, which are DC voltages.

Figure 5 shows a preferable example of the mixing ratio between the superdirectional sound pickup signal D and the stereo sound pickup signals L and R with regard to the current viewing angle of the zoom lens 1. In Fig. 5, a curve 300 represents the mixing ratio-viewing angle relation, and the axis of abscissas denotes the viewing angle of the zoom lens 1. The left ordinate indicates the mixing ratio {K1/(K1+K2)} of the superdirectional sound pickup signal D, and the right ordinates indicates the mixing ratio {K2/(K1+K2)] of the stereo sound pickup signals L and R. At the wide viewing angle zoom position 301, the mixing ratio of the stereo sound pickup signals L and R is 100%, and, at the telescopic zoom position 302, the mixing ratio of the superdirectional sound pickup signal D is 100%. The mixing ratios of the signals are varied from 0% to 100% in proportion to the variation in the viewing angle.

In this embodiment, the resistances of the resistors R1 - R7 and R11 - R17 of the first and second mixing control circuits 5 and 6 can be determined in the following manner: (1) the mixing ratio of the superdirectional sound pickup signal D to the signals R and L is selected from the mixing ratio-viewing angle curve 300 (Fig. 5); (2) the control voltages Vc1 and Vc2 of the first, second and third voltage control amplifiers 7, 8 and 9 are determined from the attenuation-control voltage curve 200 (Fig. 4) so that they correspond to the selected mixing ratio; and (3) the resistances of the resistors R1 - R7 and R11 - R17 are set so that the control voltages Vc1 and Vc2 can be obtained at the zoom positions a-g. Consequently, the microphone apparatus can realize, in the wide viewing angle mode, the spaciousness, perspective, localization, mobility, separation from background noises and others, which are the features of the stereo sound reproduction, and, in the telescopic mode, record clearly the sound from the object sound source. Therefore, the microphone apparatus can achieve acoustic zoom effects which match well with the images and have psychoacoustical effects.

Figure 6 shows a preferable example of the relation between the current zooming magnification M of the zoom lens 1 and the magnitudes of sum signals (K1·D+K2·L) and (K1·D+K2·R) delivered from the first and second adders 10 and 11. The axis of abscissas indicates zooming magnification M in logarithmic form. The axis of ordinates expresses the magnitudes of the sum signals (K1·D+K2·L) and (K1·D+K2·R) in the unit of decibels, which are relative values against the values corresponding to the zooming magnification M of one (M=1). A curve 400 is an output level-zooming magnification relation curve obtained by varying the magnitudes of the sum signals in proportion to the 0.5th power of the current zooming magnification M. Curves 401 and 402 show similar relations obtained in the 0.4th power and 0.3th power of the magnification M, respectively. According to our experiments in psychoacoustic properties, by controlling the output level in accordance with the curve 400 when zooming-in and in accordance with the curve 402 when zooming-out, sound volumes matching with the variation of the image size can be obtained, and the acoustic zoom effects can be greatly improved. The output level is controlled by the first and second mixing control circuits 5 and 6 shown in Fig. 3. As apparent from the configuration of the first and second mixing control circuits 5 and 6, the output level and the mixing ratio can be set independently.

Figure 7 shows the relation between the viewing angle and the rotation angle of the zoom ring 21 of the zoom lens 1. A curve 500 is a viewing angle-rotation angle curve. Figure 8 illustrates the relation between the zooming magnification M and the viewing angle of the zoom lens 1. A curve 600 shown in Fig. 8 is a zooming magnification-viewing angle curve. As mentioned above, the zoom lens 1 has a zooming magnification of ten times at maximum, and hence the viewing angle is about 4.2 degrees in the wide viewing angle mode and is about 42 degrees in the telescopic mode.

Figure 9 is a diagram showing the mixing level of the superdirectional microphone signal D and the stereo microphone signals L and R, at the zoom positions a - g of the zoom lens 1. In this case, the zoom lens 1 has characteristics shown in Figs. 7 and 8, the mixing of the superdirectional sound pickup signal D and the stereo sound pickup signals L and R is set so as to satisfy the relations shown by the mixing ratio-viewing angle curve 300 (Fig. 5) and by the output level-zooming magnification curve 401 (Fig. 6). A curve 700 is a reference curve for setting the mixing level of the superdirectional sound pickup signal D, and a curve 701 is a reference curve for setting the mixing level of the stereo sound pickup signals L and R. In Fig. 9, fine lines extending laterally denote mixing levels of the superdirectional sound pickup signal D, and thick lines indicate mixing levels of the stereo sound pickup signals L and R. The symbols a - g in the upper portion of Fig. 9 denote the zoom positions of the reflector 22 shown in Fig. 2a.

Figure 10 shows a preferable example of the mixing ratio of the superdirectional sound pickup signal D and the stereo sound pickup signals L and R to the current viewing angle of the zoom lens 1. A curve 800 shows the relation between the mixing ratio and the viewing angle. At the wide viewing angle zoom position 801, the mixing ratio of the stereo sound pickup signals L and R is set to 100%, and, at the telescopic zoom position 802, the mixing ratio of the superdirectional sound pickup signal D is set to 70% and that of the stereo sound pickup signals L and R is 30%. The mixing ratios of the signals are varied within the above-mentioned range in proportion to the variation in the viewing angle. By changing the mixing ratios according to the mixing ratio-viewing angle curve 800, the microphone apparatus can pick up the background sound even when the telescopic mode is set, resulting in that the presence property is enhanced when reproducing. This is very effective, in particular, in a so-called surround-reproducing system wherein two or three loudspeakers are arranged in the front and one or two speakers in the rear. The mixing ratio of the stereo sound pickup signals L and R at the telescopic zoom position may be set to 30%, but any level is acceptable as far as the stereo sound pickup signals L and R are included.

Figure 11a illustrates another microphone apparatus according to the invention. The microphone apparatus of Fig. 11a is a modification of the apparatus of Fig. 1 in which the zoom position sensor 4 is an analog sensor so that the first and second control signal Vc1 and Vc2 can be directly obtained (i.e., the mixing control circuits 5 and 6 are omitted). Only the portions different from the apparatus of Fig. 1 will be described below. The outer surface of a zoom ring 21 which is formed by a black or low-reflection index material is covered by a reflector 60. The lateral direction in Fig. 11b corresponds to the rotation direction of the zoom ring 21, and the left end corresponds to the wide viewing angle zoom position and the right end to the telescopic zoom position. As shown in Fig. 11b, the reflector 60 comprises first and second reflector areas 60a and 60b which are made from aluminum and disposed in a substantially parallel manner. The reflector areas 60a and 60b have a shape of a long triangle elongated along the rotation direction, and are disposed in a reverse parallel manner. In other words, with the rotation of zoom ring from the wide viewing position to th telescopic position, the widths W1 of the reflector area 60a is gradually decreased, while the widths W2 of the reflector area 60b is gradually increased.

The zoom position sensor 4 is similar in structure to that used in the apparatus of Fig. 1, and comprises first and second reflection type photosen sors 30 and 31. As shown in Fig. 11c, the first photosensor 30 is faced to the first reflector area 60a, and the second photosensor 31 is faced to the second reflector area 60b. The first photosensor 30 detects the amount of light reflected from the reflector area 60a to output the first control signal Vc1. The second photosensor 31 detects the amount of light reflected from the reflector area 60b to output the second control signal Vc2. The levels of the signals Vc1 and Vc2 respectively correspond to the width W1 of the first reflector area 60a and the width W2 of the second reflector area 60b. The widths W1 and W2 vary as the zoom ring 21 rotates, so that the level of each of the control signals Vc1 and Vc2 can be freely changed in accordance with the rotation angle of the zoom ring 21. For example, in Fig. 11b, the width W1 of the first reflector area 60a is wide, and the width W2 of the second reflector area 60b is narrow, at the wide viewing zoom position, and vice versa at the telescopic position.

At the wide viewing position, therefore, the output signal Vc1 from the first photosensor 30 is greater than the output signal Vc2 from the second photosensor 31. From the attenuation-control voltage curve 200 (Fig. 4), the attenuation of the superdirectional sound pickup signal D which depends on the control signal Vc1 is greater than the attenuation of the stereo sound pickup signals L and R which depends on the control signal Vc2, thereby causing the mixing ratio of the stereo sound pickup signal L and R to be large. Conversely, at the telescopic position, the mixing ratio of superdirectional sound pickup signal D is large, since the width W1 of the first reflector area 60a is narrow and the width W2 of the second reflector area 60b is wide. The microphone apparatus of Fig. 11a has advantages that the simplified electric circuit can reduce the manufacturing cost, and that the apparatus can be continuously and finely controlled because the control signals Vc1 and Vc2 are not discrete ones.