JPH0865789A - Sound signal processor - Google Patents

Abstract

PURPOSE: To reduce only noise components without influencing sound signals. CONSTITUTION: Signals from microphones 1A and 1B are taken out to output terminals 7A and 7B through amplifiers 2A and 2B, A/D conversion circuits 3A and 3B, low-cut filters 4A and 4B, subtraction circuits 5A and 5B and the amplifiers 6A and 6B. Also, the signals from the filters 4A and 4B are supplied to variable gain amplifiers 9A and 9B through addition circuits 8a and 8B and the output is supplied to the subtraction circuits 5a and 5B and also fed back to the addition circuits 8a and 8B through delay circuits 10A and 10B corresponding to periodic noise. Further, the signals from the filters 4A and 4B are supplied to a comparator circuit 12 through absolute value circuits 11A and 11B, larger signals are supplied to the setting circuits 14 and 15 of attack characteristics and recovery characteristics through an envelope detection circuit 13 and the set respective characteristics are added in the addition circuit 16 and supplied to the control terminals of the amplifiers 9A and 9B.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an audio signal processing device suitable for use in, for example, a VTR integrated video camera.

[0002]

2. Description of the Related Art In a VTR-integrated video camera, for example, mechanical vibration generated in a VTR portion or the like, in particular, periodic vibration generated by hitting a tape with a rotary head is transmitted to a microphone. The generation of vibration noise that forms is a problem. Such vibration noise is generated as follows.

That is, when the above mechanical vibration is transmitted to the microphone, the vibration energy is transmitted to the vibrating membrane in the microphone, and the vibrating membrane vibrates to output the vibration as it is as an audio signal. This is vibration noise, and in order to eliminate it,
It is necessary to reduce the mass of the vibrating membrane to zero or prevent the vibration from being transmitted to the microphone. Here, it is impossible to completely reduce the mass of the vibrating membrane to zero.

Therefore, in the conventional device, the microphone is installed away from the VTR part. The VTR part uses a cabinet structure that prevents mechanical vibration from leaking to the outside. Make the microphone directional. The microphone has a structure that cancels incoming vibration noise. Etc. were adopted. However, such a structural method requires a large volume of the device, and there is a limit particularly when miniaturization of the entire device is promoted.

On the other hand, when the noise has a constant frequency component, a filter for removing this component is provided in the signal system. It is possible. However, when such a filter is simply provided, the noise component is removed, and at the same time, the sound quality of the audio signal to be collected is affected.

[0006]

That is, the problem to be solved by the present invention is that the conventional methods (1) to (3) require a large volume of the apparatus, and there is a limit when the miniaturization of the entire apparatus can be promoted. . According to the other method, the noise component is removed, and at the same time, the sound quality of the audio signal to be collected is affected.

[0007]

A first means according to the present invention supplies a voice signal to a filter means (5A, 8A to 10A) for removing a predetermined noise component and detects the level of the voice signal. Detecting means (11A to 16) is provided, and the removal level of the noise component of the filter means is controlled according to the level detected by the detecting means (9
A) A voice signal processing device.

According to a second aspect of the present invention, in the audio signal processing device according to the first aspect, the detecting means performs envelope detection (13) on the audio signal, and a predetermined attack characteristic and a predetermined attack characteristic are applied to the detected signal. Set recovery characteristics (14, 15)
Then, the audio signal processing device is adapted to detect the level.

According to a third means of the present invention, in the audio signal processing device according to the first means, when a plurality of the audio signals are supplied, the detection means performs envelope detection of the audio signals. The signal is the maximum level audio signal (1
Regarding 2), the audio signal processing device is adapted to detect the level thereof.

A fourth means according to the present invention is the audio signal processing device according to the first means, wherein the filter means comprises:
A noise component is extracted by repeatedly adding signals in which periodic noise is delayed by the period, the noise component is subtracted from the original signal, and the level of the extracted noise component is detected by the detection means. The audio signal processing device is configured to be controlled according to the set level.

A fifth means according to the present invention is the audio signal processing device according to the first means, wherein the audio signal is VT.
The audio signal processing device is an audio signal picked up by the built-in microphone of the R-integrated video camera, and the noise component is a noise component generated in the VTR portion of the VTR-integrated video camera.

According to a sixth aspect of the present invention, in the audio signal processing device according to the first aspect, the audio signal is VT.
The noise component is a sound signal reproduced after being picked up by the built-in microphone of the R-integrated video camera, recorded, and the noise component is included in the reproduced sound signal at the time of recording by the VTR-integrated video camera. The audio signal processing device is a noise component generated in the VTR portion.

[0013]

According to this, the audio signal is supplied to the filter means for removing a predetermined noise component, the detecting means for detecting the level of the audio signal is provided, and the noise component removal level of the filter means is detected by the detecting means. By controlling according to the detected level, it is possible to favorably reduce only the noise component without affecting the actual audio signal.

Further, since the periodic noise component is extracted and processed, the noise component is favorably treated especially with respect to the periodic vibration noise generated by the tape being hit by the rotary head. Can be reduced.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In FIG. 1, 1A and 1B are stereo left and right microphones incorporated in a VTR integrated video camera, for example. The signals from these microphones 1A and 1B are respectively sent to the A / Ds through the amplifiers 2A and 2B.
It is supplied to the conversion circuits 3A and 3B. The digital signals converted by this are the low-cut filters 4 respectively.
It is supplied to subtraction circuits 5A and 5B for removing noise components described later through A and 4B. The signals from these subtraction circuits 5A and 5B are fed to amplifiers 6A and 6B, respectively.
Through the output terminals 7A and 7B.

The signals from the low cut filters 4A and 4B are supplied to the adder circuits 8A and 8B. The signals from the adder circuits 8A and 8B are respectively supplied to the variable gain amplifier 9
A and 9B, and these variable gain amplifiers 9A and 9B are supplied.
The output of B is added through an adder circuit 8 through delay circuits 10A and 10B having delay times corresponding to the cycle of periodic noise.
Returned to A and 8B. As a result, the adder circuits 8A, 8
From B, only the periodic noise components corresponding to the delay times of the delay circuits 10A and 10B are emphasized and extracted, and the extracted noise components are supplied to the subtraction circuits 5A and 5B.

Further, the signals from the low-cut filters 4A and 4B are converted into absolute value (ABS) circuits 11A and 11 respectively.
Supplied to B. The signals from these absolute value circuits 11A and 11B are supplied to the comparison circuit 12, and the larger signal is extracted and supplied to the envelope detection circuit 13.
The signal from the envelope detection circuit 13 is supplied to the attack characteristic setting circuit 14 and the recovery characteristic setting circuit 15. The respective characteristics set here are added by the adding circuit 16 and supplied to the control terminals of the variable gain amplifiers 9A and 9B described above.

In this device, when the envelope of the signal extracted from the comparison circuit 12 is at a predetermined level or higher, the noise component is not noticeable, so that the gains of the variable gain amplifiers 9A and 9B are reduced. Next, when the envelope falls below a predetermined level, the gains of the variable gain amplifiers 9A and 9B are increased so that the noise component is removed. However, if the noise component is sharply removed when the envelope becomes smaller, the change point can be easily recognized by the auditory sense. Therefore, the attack characteristic of the setting circuit 14 described above is set relatively gently.

On the other hand, when the envelope becomes large, if the recovery characteristic is set too gently,
When the sound is interrupted for a moment, unnecessary noise components are continuously removed, which is not preferable in hearing.
Therefore, the recovery characteristic in the setting circuit 15 described above is set relatively steeply.

Thus, according to the above-mentioned device, the audio signal is supplied to the filter means for removing a predetermined noise component, and the detecting means for detecting the level of the audio signal is provided to detect the noise component removal level of the filter means. By controlling according to the level detected by the detection means, only the noise component can be satisfactorily reduced without affecting the actual audio signal.

Further, since the periodic noise component is extracted and processed, the noise component is favorably treated especially with respect to the periodic vibration noise generated when the tape is hit by the rotary head. It can be reduced.

By the way, in the above-mentioned device, if the attack characteristic is set steeply, in the case where the envelope is gradually reduced as described above, the change point may be easily recognized by the sense of hearing. . On the other hand, if the attack characteristics are made too gentle, there is a risk of adversely affecting the returning voice when the voice is interrupted for a moment.
Therefore, for this attack characteristic, for example, a change in the envelope can be detected, and the time constant of the characteristic can be changed according to the change.

That is, FIG. 2 shows a processing flow from the output of the comparison circuit 12 to the addition circuit 16. In FIG. 2, in block 21, the value D _(t) of the output from the comparison circuit 12 is compared with the reference level K. When D _(t) <K is not satisfied in this block 21 (N),
In block 22, the value C _t for controlling the gains of the variable gain amplifiers 9A and 9B is set to C _t = 0.

When D _(t) <K in the block 21 (Y), the output value D _(t) from the comparison circuit 12 in the block 23 becomes the output value D _(t-1) one sample before. Be compared. When D _(t) <D _(t-1) is not satisfied in this block 23 (N), the variable gain amplifiers 9A and 9A are used in block 24.
The value C _t controlling the gain of B is set to C _t = C _t-1 −τ _R. In this block 24, τ _R corresponds to the time constant of the recovery characteristic described above, and is set to a value that provides a relatively steep characteristic as described above.

Further, when D _(t) <D _(t-1) (Y) in block 23, D _{( t -1)} -D _(t) is compared with an arbitrary value L in block 25. And in this block 25 D
_{If (t-1)} -D _(t) <L (Y), block 26
_t = C _t-1 + τ _A1 . Also at block 25 D
_{If (t-1)} -D _(t) <L (N), then block 27
Then, C _t = C _t-1 + τ _A2 . In these blocks 26 and 27, τ _A1 and τ _A2 correspond to the time constants of the above-mentioned attack characteristics, and these values are τ _A1 <τ _A2
Is set to

Therefore, in this device, for example, in FIG.
In the case where the sound is interrupted for a moment as shown in (4), the envelope is sharply lowered, and therefore, in block 25, D
It is determined that _(t-1) -D _(t) <L is not satisfied, and block 2
In step 7, C _t = C _t-1 + τ _A2 is set to sharpen the attack characteristic of the filter as shown in B of FIG. When the voice is restored, the filter is removed with a sharp recovery characteristic so that the voice is not adversely affected.

Further, if the envelope is gradually lowered as shown in A of FIG.
_(t-1) -D _(t) <L is determined, and in block 26, _Ct =
By setting C _t-1 + τ _A1 , the attack characteristic of the filter is moderated as shown in FIG. 4B. Therefore, the change point becomes unclear by the sense of hearing, and a good noise component removal process can be performed.

That is, in this device, a change in the envelope is detected, and the time constant of the characteristic is changed according to the change, so that a response characteristic that is natural to the sense of hearing can be obtained.

In the block 25, D _(t-1) -D _(t)
The determination of (1), that is, the determination of the change of the envelope, can be performed by further subdividing the value of L into a plurality of stages to obtain a more natural response characteristic. Similarly, the recovery characteristic may be changed by discriminating the change in the envelope.

Further, in the above embodiment, the audio signal is the signal from the left and right stereo microphones built in the VTR integrated video camera, for example, but the invention of the present application can also be applied to a monaural audio signal. In that case, the lower half circuit and the comparison circuit 12 in FIG. 1 are not necessary.
In addition, the left and right sides of the stereo audio signal can be controlled independently.

Further, since the invention of the present application is carried out by purely electric signal processing, it can be used in combination with the conventional measures for eliminating vibration noise as shown in the above-mentioned items 1 to 3, for example. Further, by implementing the invention of the present application also in the reproduction system of the audio signal once recorded, it is possible to remove the vibration noise collected during recording.

In the above embodiment, the delay circuit 10
The delay amounts of A and 10B are determined by the sampling frequency of the audio signal and the rotation cycle of the drum. In that case, in the above filter configuration, cos θ is set to | 1-co
Since sθ | is the output transfer function, a dip is formed once in a half cycle.

Therefore, for example, the drum rotation cycle is set to 150H.
In the case of z, it is necessary to provide a delay amount of 150/2 = 75 Hz in order to provide a dip for each 150 Hz and 150 Hz. In this way, the delay amounts of the delay circuits 10A and 10B are determined.

[0034]

According to the present invention, the audio signal is supplied to the filter means for removing a predetermined noise component, and the detecting means for detecting the level of the audio signal is provided to detect the noise component removal level of the filter means. By controlling according to the level detected by the detection means, it has become possible to satisfactorily reduce only the noise component without affecting the actual audio signal.

Further, since particularly the periodic noise component is extracted and processed, this noise component is favorably dealt with especially for the periodic vibration noise generated by the tape being hit by the rotary head. It can be reduced.

[Brief description of drawings]

FIG. 1 is a configuration diagram of an example of an audio signal processing device according to the present invention.

FIG. 2 is a block diagram for explaining another example.

FIG. 3 is a waveform diagram for the explanation.

FIG. 4 is a waveform diagram for the explanation.

[Explanation of symbols]

 1A, 1B Microphone 2A, 2B, 6A, 6B Amplifier 3A, 3B A / D conversion circuit 4A, 4B Low-cut filter 5A, 5B Subtraction circuit 7A, 7B Output terminal 8A, 8B Addition circuit 9A, 9B Variable gain amplifier 10A, 10B Delay Circuits 11A and 11B Absolute value (ABS) circuit 12 Comparison circuit 13 Envelope detection circuit 14 Attack characteristic setting circuit 15 Recovery characteristic setting circuit 16 Adder circuit

Claims (6)

[Claims] 1. An audio signal is supplied to a filter means for removing a predetermined noise component, and a detection means for detecting the level of the audio signal is provided, and the removal level of the noise component of the filter means is detected by the detection means. An audio signal processing device adapted to be controlled according to the level detected in. 2. The audio signal processing device according to claim 1, wherein the detection means performs envelope detection of the audio signal, sets predetermined attack characteristics and recovery characteristics in the detected signal, and detects the level thereof. An audio signal processing device adapted to perform. 3. The audio signal processing device according to claim 1, wherein when a plurality of the audio signals are supplied, the detection means detects the envelope signal of the audio signals and detects the maximum level of the detected audio signals. , An audio signal processing device adapted to detect its level. 4. The audio signal processing device according to claim 1, wherein the filter means repeatedly adds signals obtained by delaying periodic noise by the period to extract a noise component, and extracts the noise component from the original noise component. An audio signal processing device that subtracts from a signal and controls the level of this extracted noise component according to the level detected by the detection means. 5. The audio signal processing device according to claim 1, wherein the audio signal is an audio signal picked up by a built-in microphone of a VTR integrated video camera, and the noise component is the VTR integrated video camera. V
An audio signal processing device that is a noise component generated in the TR portion. 6. The audio signal processing device according to claim 1, wherein the audio signal is an audio signal which is picked up by a built-in microphone of a VTR-integrated video camera, recorded, and reproduced, and the noise component. Is the V in the reproduced audio signal.
An audio signal processing device that is a noise component generated in the VTR portion during recording with a TR-integrated video camera.