JPH03106299A - Microphone device - Google Patents

Abstract

PURPOSE:To reduce wind noise and to sufficiently secure a low frequency range, directivity, etc., in a windless condition by connecting a high pass filter(HPF) in accordance with a difference between the output levels of an unidirectional microphone and a non-directional microphone. CONSTITUTION:The microphone device is provided with the unidirectional microphone 1 for outputting the 1st acoustic signal, the non-directional microphone 2 for outputting the 2nd acoustic signal, a correcting means 3, the 1st detecting means 6 for detecting the output level of the 1st acoustic signal, the 2nd detecting means 7 for detecting the output level of a correction signal, a comparing means 8 for comparing both the output levels, and a control means 12 for connecting the HPF 10 to an acoustic output terminal 13 in response to the detection signal. Since the single directivity microphone 1 is more easily influenced by wind noise as compared with the non-directional microphone 2, the superposition of wind noise to the microphone device can be detected when the 1st output level is higher than the 2nd output level. Thereby, noise can be cut out from an acoustic output signal by connecting the HPF 10 to the acoustic output terminal 13.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application The present invention relates to a microphone device used in a camera-integrated VTR (video tape recorder) and the like.

(B) Prior Art When collecting sounds outdoors, when wind hits the microphone, low-frequency noise is generated due to pressure fluctuations around the diaphragm of the microphone. This is called wind noise.

Generally, wind noise has a frequency of 50 Hz or less, centered around 200 Hz or less.
This is noise up to about 0Hz.

A unidirectional microphone is often used in a camera-integrated VTR. Unidirectional microphones are more susceptible to wind noise than omnidirectional microphones. In unidirectional microphones, the excitation force acting on the diaphragm due to sound pressure tends to decrease as the frequency becomes lower. This is due to the fact that the impedance of the

As a measure to reduce wind noise, it is common practice to attach a wind screen made of urethane foam or the like to a microphone. In this case, the microphone is shielded from the airflow, making it difficult for pressure fluctuations occurring in the airflow due to the wind to be transmitted to the diaphragm surface of the microphone.

Also, 100P-10 of the magazine "Broadcasting Technology November 1983 issue"
5P describes a ``microphone with a wind noise prevention mechanism.'' This microphone is provided with an m-structure that reduces and equalizes the pressure on the front and back sides of the microphone's diaphragm, thereby reducing wind noise by reducing microphone sensitivity at very low frequencies.

(c) Problems to be solved by the invention However, when reducing wind noise using a windscreen, a fairly large windscreen is required to obtain a sufficient effect, which poses practical and design problems. arise. Further, in the latter example, problems arise such as the structure of the microphone itself becoming complicated and the sensitivity not only to pressure fluctuations due to wind but also to voice being reduced at low frequencies.

SUMMARY OF THE INVENTION An object of the present invention is to provide a microphone device that has a simple structure and can sufficiently ensure low frequency range, directivity, etc. in windless conditions.

(2) Means for Solving the Problems In view of the above problems, the microphone device of the present invention has the following features:
a unidirectional microphone that derives a g-sound signal;
correcting the second acoustic signal so that the output levels of the first acoustic signal and the second acoustic signal are equivalent when the same level of sound pressure is input to an omnidirectional microphone that derives the acoustic signal; a correction means for deriving the reinforcement signal as a reinforcement signal; a first detection means for detecting the output level of the first acoustic signal as a first output level; and a first detection means for detecting the output level of the reinforcement signal as a second output level. 2 detection means;
a comparison means for comparing the output level and the second output level and deriving a detection signal when the first output level becomes higher than the second output level by a predetermined value; and in response to the detection signal, an acoustic output terminal; The first feature is that the control means is provided with a control means for connecting a high-pass filter to the high-pass filter.

In addition, the second feature of the present invention is that instead of connecting a high-pass filter to the audio output terminal, a supplementary signal is selectively supplied to the audio output terminal.

Further, a plurality of unidirectional microphones, an adding means for adding the outputs of these microphones to derive the first acoustic signal, and an omnidirectional microphone for deriving the second acoustic signal, said first when the sound pressure is input.
a correction means for correcting the second acoustic signal so that the output level of the acoustic signal and the second acoustic signal are equal, and deriving it as a supplementary signal, and setting the output level of the first acoustic signal as a first output level; A first detection means detects the output level of the reinforcement signal, and a second detection means detects the output level of the reinforcement signal as a second output level, and compares the first output level and the second output level, and determines that the first output level is A third aspect of the present invention further comprises a comparison means for deriving a detection signal when the second output level becomes higher than a predetermined value, and a control means for connecting a high-pass filter to the acoustic output terminal in response to the detection signal. Features.

Further, in the third feature, a fourth feature is that instead of connecting a high-pass filter to the audio output terminal, a supplementary signal is selectively supplied to the audio output terminal.

(e) Effect According to the first feature, unidirectional microphones are much more susceptible to wind noise than omnidirectional microphones, so the first output level is is larger than the second output level, it can be detected that wind noise is superimposed on the microphone device. Therefore, if a high-pass filter is connected to the audio output terminal at this time, noise can be cut from the audio output signal.

According to the second characteristic, while noise is expected to be superimposed on the output from a unidirectional microphone, the signal from an omnidirectional microphone is relatively less affected by wind noise. Since the sound is emitted from the acoustic output terminal, the output signal from the microphone device can be made strong against wind noise.

A unidirectional microphone does not output a signal unless the sound source is directly in front of it. Omnidirectional microphones, on the other hand, can pick up sound and emit a signal no matter where the source is. Therefore, according to the above two claimed inventions, when there is wind and the sound source is not in front of the unidirectional microphone, the omnidirectional microphone is lower than the first output level corresponding to the noise caused by the wind. The second output level increases depending on the sound picked up by the microphone, and therefore wind noise cannot be detected. On the other hand, according to the third and fourth features described above, a plurality of unidirectional microphones are arranged so that each microphone can pick up sound in all directions, and the output from each microphone is The signals are combined to form a first acoustic signal.

Therefore, the first acoustic signal emits a signal corresponding to the sound source, regardless of the direction of the sound source. Therefore, when the sound source is at an arbitrary position and there is wind, the first acoustic signal will be a signal corresponding to the sound and wind, and therefore the first output level will be:
The second output level is higher than the second output level corresponding to only the sound, so that noise can be detected even in such a case.

The third feature is that, in response to the detection of such noise, a high-pass filter is connected to the audio output terminal of the microphone device to cut noise caused by the wind from the output signal of the audio output terminal.

A fourth feature is that, in response to the noise detection, a signal from an omnidirectional microphone on which wind noise is not easily superimposed is supplied to the acoustic output terminal.

It supplies the signal from the microphone.

(f) Example Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram of the first embodiment. In the figure, (1) is a unidirectional microphone, which receives audio and the like and derives a first acoustic signal. (2) is an omnidirectional microphone, which derives the second acoustic signal. Unidirectional microphones and omnidirectional microphones have different frequency characteristics, sensitivity, etc. Generally, omnidirectional microphones are flat over the entire band, while unidirectional microphones have sensitivity, etc. attenuated in the low range. Tend. (3) compares the frequency characteristics, sensitivity, etc. in the low range of the omnidirectional microphone (2) with the unidirectional microphone (
This is a correction circuit (correction means) that corrects the second acoustic signal and derives a supplementary signal so that it is equivalent to 1), and when the sound source is at a predetermined position and the same level of sound pressure is input. The levels of the first acoustic signal and the reinforcement signal are corrected to be equivalent.

(4) and (5) are low-pass filters (1.P F),
(6). (7) is a first detection circuit (first detection means) and a second detection circuit (second detection means). L P F (4
) and the first detection circuit (6), the output level of the low frequency portion of the first acoustic signal is detected as the first output level, and the LP
F(5) and the second detection circuit (7) detect the output level of the low-level portion of the reinforcement signal as the second output level. A comparison circuit (8) compares the first output level and the second output level, and derives a control signal when the second output level becomes higher than the first output level by a predetermined value or more. (11)
is a signal line that transmits the first acoustic signal derived from the first microphone (1) to the acoustic output terminal (13), and (
10) is a high pass filter (HPF) connected to the signal line (11). Switch control circuit (12)
and switch (9), the control means is 1110! ;t has been done. The switch (9> normally selects the side that outputs the first acoustic signal directly to the acoustic output terminal (13), and when the control signal is output from the comparison circuit (8), the side that outputs the first acoustic signal directly to the acoustic output terminal (13) is selected. ) performs switching control such that the switch (9) selects the side on which the first acoustic signal passes through the H P F (10) and is led out to the acoustic output terminal (13).

FIG. 5 is a sectional view showing the structure of a microphone assembly incorporating a unidirectional microphone (1) and an omnidirectional microphone (2). FIG. 6 is a sectional view of the section AA'. The unidirectional microphone (1) is
It is held by an elastic member (22) in a shield case (21) provided with a large number of through holes. Elastic member (
22), vibrations etc. are unidirectional microphone (1)
is prevented from being transmitted. Shield case (21
) is covered with a windscreen (23) made of urethane foam. The shield case (2l) is attached to the board (l4), and the shield case (2l) is attached to the board (l4).
14) is supported by an elastic member (15). The directional microphone 2) is fixed on the substrate <14>, and the outer periphery of the omnidirectional microphone (2) is covered with a wind screen (26). Omnidirectional microphone (
2) is less susceptible to noise generated by vibration, so the substrate (14). There is no problem even if it is directly fixed to h.

Next, the operation of the above Ill will be explained.

When there is no wind and sound pressure is input to the microphone assembly, the second output level of the second acoustic signal is:
Since the correction circuit (3) has corrected the signal so that it is equal to the first output level of the first acoustic signal, the comparison circuit (8)
does not derive control signals. Therefore, the first acoustic signal is directly led out to the acoustic output terminal (l3), and a sufficiently low frequency range is maintained. Further, when the sound source is located at a position different from the direction of directivity of the unidirectional microphone (1), the first output level will be lower than the second output level, but even in this case, the control signal is not derived. The first acoustic signal is directly transmitted to the acoustic output terminal (l3
) is derived.

When wind hits the microphone assembly, as mentioned above, the unidirectional microphone (1) is more susceptible to wind noise than the omnidirectional microphone (2), and the first acoustic signal is affected by low frequency noise. A large amount of noise is generated.Therefore, the first output level becomes higher than the second output level, and when the first output level becomes higher than the second output level by a predetermined value or more, the control signal is output from the comparison circuit (8). is derived, and the switch 7 (9) is switched to select the side on which the first acoustic signal passes through the H P F (10) and is derived to the acoustic output terminal (13). In this case, Since the low range that contains a lot of noise in the first acoustic signal is cut, the acoustic signal with less wind noise is sent to the acoustic output terminal (l3).
It will be derived from

As shown in Figure 5, the omnidirectional microphone (1) is double covered by windscreens (23) and (26), and is more protected from wind than the unidirectional microphone (1). Since it is not easily affected by noise, the difference between the first output level and the second output level tends to increase when the microphone assembly is exposed to wind.

Next, a second embodiment will be explained. FIG. 2 is a block diagram of the second embodiment, and the same parts as in FIG. 1 are designated by the same reference numerals and their explanation will be omitted.

In the figure, (l4) is a second signal line that transmits the supplementary signal. In the second embodiment, the switch (9) which is normally switched to output the first acoustic signal to the acoustic output terminal (13) outputs the reinforcement signal to the acoustic output terminal (13) in response to the generation of the control signal. ) is switched to the deriving side. According to the groove shown in FIG. 2, only when wind noise occurs, the omnidirectional second microphone (2) is selected, and audio that is less affected by wind noise can be obtained.

FIG. 3 is a block diagram of the third embodiment. Components that are the same as those in FIG. 1 are designated by the same reference numerals, and their explanation will be omitted.

In the figure, (l5) is a light emitting diode (warning light) (l
6) is a transistor, and in response to the generation of a control signal, the transistor 16) is turned on, and the light emitting diode (15) lights up. Therefore, the user can know that wind noise is occurring,
Measures can be taken such as temporarily suspending sound collection. In addition, instead of lighting the light emitting diode (15), a warning sound may be generated. FIG. 4 is a block diagram of a fourth embodiment. Components that are the same as those in FIG. 1 are designated by the same reference numerals, and their explanation will be omitted.

In the fourth embodiment, two unidirectional microphones are provided, making it possible to pick up stereo sound. When the control signal is generated in the case III in FIG. 4, the switches (9) and (34) switch to H P
switch (33) sends the reinforcement signal to the combining circuit (
35) and (36). Therefore, when wind noise occurs, only the low-frequency sound is switched to monaural sound, which is less affected by wind noise and is produced by the omnidirectional second microphone (2). Note that there is little stereo effect in the low range, so there is no big problem with monaural audio.

FIG. 7 is a cross-sectional view showing the groove structure of a microphone assembly capable of stereophonic sound collection, except that a unidirectional Rch microphone (1) and an Lch microphone (31) are provided. This is similar to the microphone assembly shown in FIGS.

In addition, in the first to fourth embodiments described above, when no elegance sound is generated, the first acoustic signal is sent to the acoustic output terminal (1
3), or alternatively, when wind noise is not occurring, the second acoustic signal is output to the output terminal (13).
) may be derived as t-it. In this case, the control signal can be used to detect whether wind noise is occurring. Furthermore, in the first to fourth embodiments, l.
P F (4). Even if (5) is omitted and it is set as III1, it is usually possible to detect whether or not wind noise is occurring. Furthermore, when there is wind, the omnidirectional microphone responds to sound and the unidirectional microphone responds to wind, so wind noise may not be detected.

FIGS. 8 and 9 show fifth and sixth embodiments that solve this problem. The fifth embodiment shown in FIG. 8 is an improvement on the first embodiment shown in FIG. 1, and the sixth embodiment shown in FIG. 9 is an improvement on the first embodiment shown in FIG. The present invention relates to an improvement of the fourth embodiment.

In each of these embodiments, the first acoustic signal is created by adding signals from two unidirectional microphones having different directivity directions. Specifically, in the fifth embodiment shown in FIG. 8, a unidirectional microphone (1) is separately provided,
The signal from the microphone (1)' is added to the signal from another unidirectional microphone (1) by an adder circuit (35) to obtain a first acoustic signal. In the sixth embodiment, the output signals from the respective stereo unidirectional microphones (1) and (31) are added in an adder circuit (35) to produce the first acoustic signal.

In each of these embodiments, by configuring the directional directions of the respective unidirectional microphones to be opposite to each other, the directional direction of each of these microphones can be set to approximately 360°, and as a result, the omnidirectional microphone It can be set to the same orientation state as . Figure 10 shows one unidirectional microphone and ? ! This figure shows the difference in directivity when several unidirectional microphones are combined. When two unidirectional microphones are combined so that their directivity directions are opposite each other at an angle of approximately 180°, and one microphone is grooved, the directivity of this microphone is as shown in the ILO diagram (
It becomes as shown by the solid line in b). Such directivity is shown in the same figure (d
Although the ellipse is slightly compressed compared to the directionality of the omnidirectional microphone shown in (a), it is a significant improvement compared to the case of one unidirectional microphone shown in (a) of the same figure. I can see that it is being done. Even in the case shown in Figure (b), the directivity can be made sufficiently close to omnidirectionality, but if you want to make it even more perfect, you can make it as shown in Figure (C).
As shown in the figure, three unidirectional microphones can be combined.

(G) Effects of the Invention As described above, according to the present invention, wind noise is removed when wind hits the microassembly, and low frequency and directivity are sufficiently ensured when there is no wind. be done. or,
There is no need for a large window screen,
The shape is compact and its effects are great.

[Brief explanation of drawings]

Fig. 1 is a block diagram of the first embodiment, Fig. 2 is a block diagram of the second embodiment, Fig. 3 is a block diagram of the third embodiment, and Fig. 4 is a block diagram of the third embodiment.
The figures are block diagrams of the fourth embodiment, Figures 5, 6 and 7.
Figure 8 shows the structure of the microphone assembly.
FIG. 9 is a block diagram of the fifth embodiment, FIG. 9 is a block diagram of the sixth embodiment, and FIG. 10 is a diagram showing the directivity of the microphone. (1)(1)''(31)...unidirectional microphone, (2)...omnidirectional microphone, (3)...correction circuit (correction means), (6)...first Detection circuit (first detection means) .(7)...Second detection circuit (second detection means).(8)...Comparison circuit (comparison means), (9)
... switch (control means), (10) ... high pass filter, (11) ... signal line, (12) ... switch control circuit (control means), (15) ... light emitting diode ( (warning light), (35)...addition circuit.

Claims (4)

[Claims] (1) A unidirectional microphone that derives a first acoustic signal, an omnidirectional microphone that derives a second acoustic signal, the first acoustic signal when the same level of sound pressure is input, and the a correction means for correcting the second acoustic signal so that the output levels of the second acoustic signal are equal and deriving it as a corrected signal; and a first detection unit for detecting the output level of the first acoustic signal as the first output level. means, second detection means for detecting the output level of the correction signal as a second output level, and comparing the first output level and the second output level, the first output level being a predetermined higher than the second output level. A microphone device comprising a comparison means for deriving a detection signal when the detection signal becomes larger than a value, and a control means for connecting a high-pass filter to an acoustic output terminal in response to the detection signal. (2) A unidirectional microphone that derives the first acoustic signal, an omnidirectional microphone that derives the second acoustic signal, the first acoustic signal when the same level of sound pressure is input, and the a correction means for correcting the second acoustic signal so that the output levels of the second acoustic signal are equal and deriving it as a corrected signal; and a first detection unit for detecting the output level of the first acoustic signal as the first output level. means, second detection means for detecting the output level of the correction signal as a second output level, and comparing the first output level and the second output level, and determining whether the first output level is the second output level. A microphone device comprising: a comparison means for deriving a detection signal when the detection signal becomes larger than a predetermined value; and a control means for selectively supplying the correction signal to an acoustic output terminal in response to the detection signal. (3) A plurality of unidirectional microphones, an adding means that adds the outputs of these microphones to derive a first acoustic signal, and an omnidirectional microphone that derives a second acoustic signal, and said first when the sound pressure is input.
a correction means for correcting the second acoustic signal so that the output levels of the acoustic signal and the second acoustic signal are equivalent and deriving a corrected signal; and detecting the output level of the first acoustic signal as a first output level. a first detection means for detecting the output level of the correction signal as a second output level; and a second detection means for detecting the output level of the correction signal as a second output level; A microphone device comprising a comparison means for deriving a detection signal when the output level exceeds a predetermined value, and a control means for connecting a high-pass filter to an acoustic output terminal in response to the detection signal. (4) A plurality of unidirectional microphones, an adding means that adds the outputs of these microphones to derive a first acoustic signal, and an omnidirectional microphone that derives a second acoustic signal, and a correction means for correcting the second acoustic signal so that the output level of the first acoustic signal and the second acoustic signal are equivalent when sound pressure is input, and deriving the second acoustic signal as a correction signal; a first detection means for detecting the output level of the signal as a first output level; a second detection means for detecting the output level of the correction signal as a second output level; and a first detection means for detecting the output level of the correction signal as a second output level; and a comparison means for deriving a detection signal when the first output level becomes higher than the second output level by a predetermined value or more, and optionally transmitting the supplementary signal to the acoustic output terminal in response to the detection signal. A microphone device comprising a control means for supplying the power.