JP3000617B2 - Microphone device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microphone device suitable for reducing unnecessary noise signals by adaptive signal processing.

[Summary of the Invention]

The present invention relates to a microphone device suitable for reducing unnecessary power consumption when reducing unnecessary noise signals from an audio signal, and is arranged at a position affected by vibration from a vibration source. Microphone means for generating an output signal in the installed state, first detection means for detecting the level of the output signal of the microphone means, second detection means for detecting a vibration state from the vibration source, Processing means for removing a signal generated in accordance with the detection output of the second detection means from the output signal of the microphone means, and detection of the vibration state by the second detection means is identified independently. Operating state detecting means for detecting the operating state of the vibration source; and performing the processing in accordance with the level of the output signal detected by the first detecting means and the output of the operating state detecting means. By controlling the operation of the means, it is possible to control the operation state of the processing means between the operation state and the non-operation in accordance with the change in the operation state of the vibration source, thereby saving wasteful power consumption. The processing by the processing means can be performed efficiently.

[Conventional technology]

In a recording device such as a camera-integrated video or the like, in addition to a desired audio signal, an unnecessary noise signal generated from an internal (mechanical system) or an external vibration source is collected and output by a microphone.

That is, while the vibration (inside) of a video drive unit or the like is picked up by a microphone and becomes noise, for example, when a recording device is placed on a desk, if any vibration (outside) is applied to the desk, This vibration is picked up as noise.

For this reason, a configuration is adopted in which the microphone is provided with directivity to lower the sensitivity in the noise generation direction, and a configuration in which the microphone is mounted at a position as far as possible from the noise generation unit, but the noise signal reduction is insufficient. Therefore, when the noise is heard during reproduction, and when vibration is directly applied to the microphone from the outside, the vibration is directly picked up as noise.

Therefore, adaptive signal processing in which a noise signal picked up and output by a microphone is electrically processed and reduced is known, and as understood from FIG. 7, an adaptive signal processing used in the processing is performed. The filter (11) has (K-1) delay elements (per clock) (20) {} and K variable amplifiers (30) { At the left end) of the amplifier (30), the reference signal (n ₁₎ is input, the subsequent amplifier (30), the reference signal (n ₁₎ is input via the sequential delay element (20).

In this case, W _{k, t} is a coefficient of the applied filter (11).
_The following equation (1) holds between _{k, t} and W _{k, t-1} .

_{W k, t = W k,} t-1 + 2με t-1 n 1kt-1 ...... (1) The coefficient (W _K) are sequentially updated, each time it is updated, a reference signal (n ₁₎ and the like A corresponding film is constructed.

For the adaptive filter (11), refer to "B. Widrow a
nd SDStearns: “Adaptive Signal Processing”, Prent
ice-Hall, 1985 ", [Digital Signal Processing-Advanced Course, <Adaptive Signal Processing>, The Acoustical Society of Japan, 35th Technical Lecture Journal, etc.].

[Problems to be solved by the invention]

However, in the processing for reducing such a noise signal, even if the vibration generating source that generates noise is not always operating but is a type of intermittently operating vibration generating source, this processing is also performed. If the part performing the operation is always kept in the operating state, wasteful power is consumed, which is a problem in power use efficiency.

An object of the present invention is to detect the operation of the vibration source, and control the operation state of a part that performs this processing in accordance with a change in the operation state of the vibration source based on the detection signal. An object of the present invention is to provide a microphone device in which a noise signal is appropriately reduced in a state where power consumption is reduced and this processing can be performed efficiently.

[Means for solving the problem]

In order to achieve the above object, a microphone device according to the present invention includes a microphone unit that generates an output signal in a state where the microphone unit is disposed at a position affected by vibration from a vibration source, and a microphone device that generates an output signal. A first detecting means for detecting a level, a second detecting means for detecting a vibration state from the vibration source, and a signal generated from an output signal of the microphone means in accordance with a detection output of the second detecting means. Processing means for removing the generated signal; and operating state detecting means for detecting an operating state of the vibration source identified independently of the detection of the vibration state by the second detecting means. The operation of the processing means is controlled in accordance with the level of the output signal detected by the first detecting means and the output of the operating state detecting means.

[Action]

In the microphone device according to the present invention, even when the vibration generating source that generates noise is not always in operation and is a type of intermittently operating vibration generating source, unnecessary power consumption is omitted to reduce this vibration. Processing for reducing a noise signal generated due to the generation source can be efficiently performed.

〔Example〕

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

FIG. 1 shows an overall schematic diagram of a microphone device (1) to which the present invention is applied. In a microphone (3), a desired sound such as a human voice is collected and an audio signal (S) is obtained. ), And the noise (vibration) generated by the vibration source is collected and output as a noise signal (n ₀ ).

The sound signal (S) and the noise signal (n ₀ ) are taken in a combined state by an adder (9), and the output of the adder (9) is input to a recording system (not shown) via a terminal (10). And input to the adaptive filter (11).

Here, as the vibration source, when the microphone unit (1) is equipped, for example, when the drive unit of the camera-integrated video is operated (generation from inside), the microphone unit (1) is placed on the desk. In this case, when some vibration is applied to the desk (for example, when a person is hit with a hand-
Externally generated).

Therefore, the vibration detecting means (pickup) (13) composed of a piezoelectric element or the like, which outputs a detection signal (n ₁ ) of the vibration in response to the vibration of the vibration generating source, can be obtained from FIG. 1 and FIG. As will be understood, for the generation from the inside, for example, the position where the vibration of the auto-focus motor (102) and the zoom motor (104) of the camera-integrated video (100) can be detected (the position of the motor or gear) In the vicinity, on the other hand, it is set to a position where vibration from the desk (106) can be detected with respect to generation from the outside.

Then, as can be understood from FIG. 4, when recording the camera-integrated video (100) (pickup) (13)
Are mounted on a flexible substrate mounted on a rotating drum), peak values (A ₁ ), (A ₂ ),
A noise signal (n ₀ ) of the spectrum having (A ₃ ) and (A ₄ )
And the spectrum of the signal (n ₁ ) output from the pickup (13) has a plurality of peak values, as can be understood from FIG.
1) As a result of adaptive signal processing by (adaptive signal processing unit)
As can be understood from FIG. 6, the camera-integrated video (10
The peak values (A ₁ ), (A ₂ ), (A ₃ ), and (A ₄ ) are removed from the spectrum of the noise signal (n ₀ ) from ( ₀ ).

As described above, in the present embodiment, the reference signal (n ₁ )
The output signal (n ₁ ) of the pickup (13) is used, and the peak value (A ₁ ), (A ₂ ), (A ₂ ) of the noise signal (n ₀ ) is obtained by the adaptive signal processing unit such as the adaptive filter (11). A ₃ ),
(A ₄ ) is removed.

As a result, the noise signal (n ₀ ) is appropriately reduced, and the sound signal is reproduced satisfactorily.

As can be understood from FIG. 2, when the pickup (13) detects vibration of the autofocus motor (102) and the zoom motor (104), the output terminal side of the adder (9). A switch (200) is interposed between the switch and the input terminal of the adaptive filter (11), and the switch (200) is set to be closed only when the motor (102) or the motor (104) operates. By doing so, the adaptive signal processing is performed only when the motor (102) or the motor (104), which is the vibration source, operates independently of the detection of this vibration. Sound is reliably removed, and unnecessary power is omitted, and adaptive signal processing can be performed efficiently.

In addition, when the noise signal (n ₀ ) is reduced by, for example, an analog circuit, the microphone (3) and the pickup (1)
It is difficult to adjust the gain with (3), and if the adjustment is not appropriate, the noise signal (n ₀ ) cannot be sufficiently reduced. However, by performing the adaptive signal processing as in this example, the noise signal (n ₀₎ ) Can be easily and reliably reduced.

Furthermore, even if the reproduced sound from the speaker includes, for example, a musical sound and noise, if the volume of the musical sound is equal to or higher than a certain level, the noise may not be generally discriminated by human hearing.

Therefore, in such a case, it is not always necessary to perform the adaptive signal processing, and the adaptive signal processing is performed only when the level of the musical sound, that is, the level of the audio signal (S) is lower than a certain level. Are also suitable.

That is, adaptive signal processing is performed only when the level of the audio signal (including the noise signal (n ₀ )) is equal to or less than a certain “threshold”, and the degree of the “threshold” is determined. It is also possible to adopt a configuration where it is appropriately selected and set according to the type of the audio signal (S) (human voice, music, etc.).

In this case, as understood from FIG. 2, the output of the microphone (3) is taken into the level detection circuit (50),
The level is detected and input to the amplifier (60).
The amplification factor μ is changed in the amplifier (60).

The output (εk) of the adder (9) is supplied to the amplifier (6
In (0), the signal is amplified to (μεk) and input to the adaptive filter (11).

And if the detected level is large, the amplification factor (μ)
Is small, and when the level is small, the amplification factor (μ) increases.

With the above configuration, the level detection circuit (50) determines that the signal [(S) + (n ₀ )] is smaller than a certain “threshold”.
The adaptive signal processing is performed by the adaptive filter (11) and the like only when the signal is detected in the step (1).

Therefore, while having the same effect as the above embodiment,
Since unnecessary power or the like is not consumed, adaptive signal processing can be performed efficiently.

In this case, the switch (200) does not necessarily need to be provided.

On the other hand, as understood from FIG. 3, in the configuration in which the pickup (13) detects the vibration of the desk (106), the desk (1)
06) is effective, especially when sudden vibration is output from the microphone (3) as a noise signal (n ₀ ).

That is, the main audio signal (S) may not be distinguished due to the sudden noise signal (n ₀ ). However, the output signal of the pickup (13) is used as the reference signal (n ₁ ) as the adaptive filter (11). , The noise signal (n ₀ ) is almost removed, and the audio signal (S) can be reproduced in a good state.

〔The invention's effect〕

In the microphone device according to the present invention, when detecting that the vibration source that generates noise is vibrating and performing processing for reducing a noise signal caused by the vibration using the detection signal as a reference signal, Since the operation of the vibration source is detected and the state of performing this processing is controlled based on the detection signal in accordance with the change in the operation state of the vibration source, for example, as shown in FIGS. 1 and 2. Even when the vibration source is of a type that operates intermittently, this process can be performed efficiently without wasteful power consumption.

[Brief description of the drawings]

1, 2 and 3 are schematic diagrams of a microphone device in a preferred embodiment of a microphone device according to the present invention, respectively, a fourth diagram is a correlation diagram showing a spectrum at the time of recording of a camera-integrated video, FIG. 5 is a correlation diagram showing the spectrum of the signal (n ₁ ), FIG. 6 is a correlation diagram showing the spectrum after adaptive signal processing, and FIG. 7 is a conceptual diagram showing the functions and the like of the adaptive filter. (1) is a microphone device, (3) is a microphone,
(9) is an adder, (11) is an adaptive filter, (13) is a pickup (vibration detecting means), (S) is an audio signal, (n ₀ )
Is a noise signal, and (n ₁ ) is a reference signal.

────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Akira Kimura 6-7-35 Kita-Shinagawa, Shinagawa-ku, Tokyo Inside Sony Corporation (56) References JP-A-63-5696 (JP, A) 63-15693 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) H04R 3/00 G01H 3/00

Claims (1)

(57) [Claims] 1. A microphone means for generating an output signal in a state where it is disposed at a position affected by vibration from a vibration source, a first detection means for detecting a level of an output signal of the microphone means, Second detecting means for detecting a vibration state from the vibration source; processing means for removing a signal generated in accordance with a detection output of the second detecting means from an output signal of the microphone means; Operating state detecting means for detecting an operating state of the vibration source identified independently of the detection of the vibration state by the second detecting means; and a level of the output signal detected by the first detecting means. And controlling the operation of the processing means according to the output of the operation state detecting means.