JPH1023123A - Speech device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a transmission signal with optimum sound quality in response to a surrounding noise level. SOLUTION: The device is provided with an air conduction microphone 1, a bone conduction microphone 2, a high-pass filter 6 for the air conduction microphone 1, a low-pass filter 7 for the air conduction microphone 1, and a low-pass filter 8 for a bone conduction microphone extracting each frequency component. A surrounding noise level is applied to a surrounding noise level input terminal 12 to receive a surrounding noise level. On the other hand, the surrounding noise level when a level of a high frequency component for air conduction microphone starts decreasing is set higher than the surrounding noise level when the level ratio the low frequency components for the air conduction and bone conduction microphones becomes '1'.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention uses a microphone for air conduction sound (hereinafter referred to as air conduction microphone) and a pickup for bone conduction sound (hereinafter referred to as bone conduction microphone) as a transmitter and is attached to an ear. BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication device for transmitting good voice in a noise environment from low noise to high noise.

[0002]

2. Description of the Related Art There has been provided a communication device capable of transmitting and receiving telephone calls by attaching a transmitter and a receiver integrally to an ear. The transmitters of these devices include air-conducting microphones and bone-conducting microphones. The sound pickup signal of the air conduction microphone has a wide band and good sound quality, but is easily affected by ambient noise. On the other hand, the sound pickup signal of the bone conduction microphone has a narrow band (only low frequency components) and poor sound quality, but has a characteristic that it is hardly affected by ambient noise. Utilizing these features, a method of processing a signal in a conventional communication device by dividing the signal into a low frequency component and a high frequency component has been proposed. That is, when picking up an audio signal, the user manually adjusts the high-frequency components of the air-borne microphone's picked-up signal and the low-frequency components of the bone-conducted microphone's picked-up signal according to the surrounding noise level. It is a method of selecting or mixing. However, when there is no or low ambient noise, the low-frequency component signal is only the bone conduction sound. Therefore, if the bone conduction sound is left with emphasis on securing the frequency band, the poor quality of the bone conduction sound is conspicuous. On the other hand, there is a disadvantage that a low frequency band cannot be secured if bone conduction sound is removed with emphasis on sound quality.

[0003] In order to overcome the drawbacks, there has been proposed a method of dividing a sound pickup signal of an air-conducting microphone or a bone-conducting microphone into bands and synthesizing it into a transmission signal having an optimum sound quality according to an ambient noise environment during use. (JP-A-7-3126)
No. 34).

[0004]

However, a method of mixing the sound pickup signals of the air-conducting microphone and the bone-conducting microphone for ordinary noise mainly including low-frequency components has not been sufficiently established. Therefore, in the related art, there is no one that can generate a high-quality transmission signal in accordance with the presence / absence and magnitude of ambient noise in the environment in which it is used.

An object of the present invention is to synthesize a transmission signal so as to obtain an optimum sound quality in accordance with an ambient noise level in an apparatus for transmitting using an air conduction microphone and a bone conduction microphone as a transmitter. To be realized.

[0006]

Means for Solving the Problems Claim 1 according to the present invention.
According to the invention described in the above, two sound collection units of an air conduction sound microphone and a bone conduction sound pickup, a low frequency component and a high frequency component of a sound pickup signal of the air conduction sound microphone, and the bone conduction sound Frequency component extracting means for respectively extracting low frequency components of a sound pickup signal of a pickup for use, an ambient noise level input means for inputting an ambient noise level when the sound pickup section is used, and when the ambient noise level becomes high. Therefore, the level ratio between the low-frequency component of the sound pickup signal of the air-conducting microphone and the low-frequency component of the sound pickup signal of the bone-conduction sound pickup is reduced, and the sound pickup signal of the air-conducting microphone is reduced. A communication apparatus comprising: level control means for reducing the level of the high frequency component; and synthesizing means for synthesizing the three types of frequency components adjusted by the level control means as a transmission signal. And controlling the level control means with respect to the ambient noise level at which the level ratio between the low-frequency component of the sound signal picked up by the air-conducting microphone and the low-frequency component of the sound signal picked up by the bone-conducting sound pickup becomes 1. The ambient noise level at which the level of the high frequency component of the sound pickup signal of the air conduction microphone starts to decrease is set high.

According to a second aspect of the present invention, the level of the low-frequency component of the sound signal picked up by the microphone for air conduction sound and the low-frequency component of the sound signal picked up by the pickup for bone conduction sound relative to the ambient noise level. The level control means is set so that the rate of change of the level of the high frequency component of the sound pickup signal of the air conduction microphone is smaller than the rate of change of the air conduction sound microphone.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION Ambient noise level and sound pickup of an air-conducting microphone when the level ratio between the low-frequency component of the sound signal collected by the air-conducting microphone and the low-frequency component of the sound signal collected by the bone-conducting microphone is 1. The relationship between the ambient noise level at which the level of the high-frequency component of the signal begins to decrease, and the ambient noise level of the low-frequency component of the sound-collected signal of the air-conducting microphone and the low-frequency component of the signal collected by the bone-conducting microphone It is a feature of the present invention to control the relationship between the rate of change of the level and the rate of change of the level of the high frequency component of the air conduction microphone.

The high frequency component of the picked-up signal is composed of only the high frequency component of the picked-up signal of the air-conducting microphone because the frequency band of the picked-up signal of the bone-conducting microphone is narrow and only the low band. FIG. 1 shows the relationship between the sound quality of the high frequency component of the sound pickup signal of the air-conducting microphone and the ambient noise level (indicated by solid lines as air-conducted sound). The sound quality of the high frequency component of the sound pickup signal of the air-conducting microphone is greatly affected by the level of the ambient noise, and when the noise level is high, the sound quality is significantly deteriorated. However, since the high-frequency components of the picked-up signal are only the high-frequency components of the picked-up signal of the air-conducting microphone, the level should be as high as possible from the viewpoint of securing the audio frequency band. Therefore, the noise level at which the high-frequency component of the sound pickup signal of the air-conducting microphone starts to decrease is set as high as possible, and the rate of change at which the level decreases is set as small as possible. According to the noise level, the level of the high frequency component of the sound signal collected by the air-conducting microphone is adjusted to the level of the high frequency component of the audio signal based on the sound quality-noise level characteristic of FIG. By adjusting as described above, sound quality can be ensured even when the noise level increases.

On the other hand, regarding the low-frequency components of the picked-up signal, the relationship between the sound quality of the low-frequency components of the picked-up signal of the air-conducting microphone and the ambient noise level (shown by solid lines as the air-conducted sound), FIG. 3 shows the relationship between the sound quality of the low-frequency component of the picked-up signal and the ambient noise level (indicated by dotted lines as bone-conducted sound). The sound quality of the low frequency component of the sound pickup signal of the air-conducting microphone is good when the level of the ambient noise is low, but is greatly affected by the level of the ambient noise, and when the ambient noise level is high, the sound quality is significantly deteriorated.

On the other hand, the sound quality of the low-frequency component of the sound pickup signal of the bone conduction microphone is inferior to the sound pickup signal of the air conduction microphone when the ambient noise level is low, but is relatively affected by the level of the ambient noise. However, even when the noise level is high, the deterioration of the sound quality is relatively small. Since the low-frequency component has two components, the pick-up signal of the air-conducting microphone and the pick-up signal of the bone-conducting microphone, the selection of both low-frequency components is quick at the noise level where the superiority of the sound quality is reversed. It is better to go for the sound quality. Therefore, the rate of change of the low-frequency component of the sound pickup signal of the air conduction microphone and the rate of increase of the low-frequency component of the bone conduction microphone are set as large as possible. In addition, since normal noise contains many low-frequency components, the noise level at which the low-frequency component of the picked-up signal of the air-conducting microphone starts to decrease and the low-frequency component of the bone-conducting microphone starts to increase. The noise level is set lower than the noise level at which the high-frequency component of the sound pickup signal of the microphone starts to decrease. Depending on the noise level, the weight at the time of adding the low frequency component of the sound pickup signal of the air conduction microphone and the low frequency component of the sound pickup signal of the bone conduction microphone is controlled as shown in FIG. By synthesizing the optimal low frequency components of the audio signal, sound quality can be ensured even when the noise level increases.

The low-frequency and high-frequency components of the picked-up signal have been described individually with reference to FIGS. 2 and 4. FIG. 5 shows the relative relationship between each level of the low-frequency component of the collected sound signal and the noise level. As shown in the figure, the ambient noise level LAL at which the level ratio between the low-frequency component of the sound signal collected by the air-conducting microphone and the low-frequency component of the sound signal collected by the bone-conducting microphone is 1
With respect to BL, the ambient noise level LAL at which the level of the high frequency component of the sound pickup signal of the air-conducting microphone starts to decrease is high,
Compared to the rate of change in the level of the low-frequency component of the sound signal collected by the air-conducting microphone and the low-frequency component of the signal collected by the bone-conducting microphone with respect to the ambient noise level, the high-frequency By reducing the rate of change of the component level, the sound quality of the picked-up signal can be ensured even when the noise level increases.

[0013]

FIG. 6 is a block diagram showing the configuration of an embodiment of the present invention.

1 is an air conduction microphone, 2 is a bone conduction microphone, 3 is an air conduction microphone amplifier, 4 is a bone conduction microphone amplifier, and 5 is a low-frequency component of a picked-up signal from the air conduction microphone amplifier 3. And a high-pass frequency component. The filter includes a high-pass filter (HPF) 6 for an air-conducting microphone and a low-pass filter (LPF) 7 for an air-conducting microphone. 8 is a low-pass filter (LPF) for a bone conduction microphone. Reference numeral 9 denotes a control information providing unit 1 which describes a level of a high-frequency component of the air conduction sound extracted by the high-pass filter (HPF) 6, which will be described later.
A level control unit for controlling based on control information from 3;
Reference numeral 0 denotes a level control unit that controls the level of a low-frequency component of a sound signal collected by the air conduction microphone 1 from the low-pass filter (LPF) 7 based on control information from the control information providing unit 13. The level of the low-frequency component of the sound pickup signal of the bone conduction microphone 2 from the low-pass filter (LPF) 8 is
A level control unit that performs control based on control information from the control information providing unit 13, and the level control units 9, 10, and 11
For example, it is constituted by a gain control circuit capable of controlling the amplification factor of an input signal by a control voltage. Reference numeral 12 denotes an ambient noise level input terminal to which, for example, a voltage level corresponding to the noise level is input. Reference numeral 13 denotes a level control unit 9 for a high-frequency component of a sound signal collected by the air-conducting microphone 1 and a level control unit 10 for a low-frequency component of a sound signal collected by the air-conducting microphone 1; A control information providing unit for providing control information to the level control unit 11 for the low frequency component, and a high frequency component of the sound pickup signal of the air conduction microphone 1 from the level control unit 9; This is a mixing circuit for synthesizing the low-frequency component of the sound signal collected by the air-conducting microphone 1 from the microphone and the low-frequency component of the sound signal collected by the bone-conducting microphone 2 from the level controller 11. Reference numeral 15 denotes a transmission signal output terminal to a telephone line circuit.

Next, the operation will be described.

The audio signal picked up by the air conduction microphone 1 is amplified by the air conduction microphone amplifier 3. The audio signal collected by the bone conduction microphone 2 is amplified by the bone conduction microphone amplifier 4. The picked-up signal from the air-conducting microphone amplifier 3 is supplied to a high-pass filter (HPF) 6 and a low-pass filter (LPF) 7.
, High frequency and low frequency components are extracted. From the sound pickup signal of the bone conduction microphone 2, a low-frequency component is extracted by a low-pass filter (LPF) 8.

First, a method of controlling the level of a high frequency band according to the noise level will be described. Air conduction microphone 1
Has a relationship depending on the noise level (FIG. 1). Therefore, when controlling the level of the sound pickup signal of the air-conducting microphone 1, the noise level dependence (FIG. 2) of the optimum level obtained based on FIG. 1 is used. The level control unit 9 receives information from the control information providing unit 13 for controlling the high-frequency component of the air-conducting microphone 1 to an optimum level according to the noise level, and receives a high-pass filter (HPF) of the air-conducting microphone 1. 6 to optimally control the level of the high frequency component.

Next, a method of controlling the weight of the air conduction sound and the bone conduction sound in the low frequency band according to the noise level will be described. There is a relationship (FIG. 3) in which the sound quality of the low frequency band component of the bone conduction microphone 2 and the sound quality of the low frequency band component of the air conduction microphone 1 depend on the ambient noise level. Therefore, when controlling the weight of the sound pickup signal of the bone conduction microphone 2 and the weight of the sound pickup signal of the air conduction microphone 1, the noise level dependence (FIG. 4) of the optimum mixing ratio obtained based on FIG. 3 is used. The control information providing unit 13 receives information for controlling the picked-up signal of the air-conducting microphone 1 to an optimum level according to the noise level, and receives a low-frequency component from a low-pass filter (LPF) 7 for the air-conducting microphone. Is optimally controlled by the level control unit 10. On the other hand, it receives information for controlling the sound pickup signal of the bone conduction microphone 2 to an optimal level, and receives a low-pass filter (LPF) 8 for the bone conduction microphone.
The level of the low-frequency component from is controlled optimally by the level control unit 11.

Thus, based on FIGS. 2 and 4, FIG.
The relationship between the noise level and the high-frequency component and low-frequency component of the sound signal collected by the air-conducting microphone 1 and the low-frequency component of the sound signal collected by the bone-conducting microphone 2 as shown in FIG. The optimal sound quality can be controlled. For the ambient noise level at which the level ratio between the low-frequency component of the sound signal picked up by the air-conducting microphone 1 and the low-frequency component of the sound signal picked up by the bone-conducting microphone 2 is 1, the sound signal collected by the air-conducting microphone 1 The level control units 9, 10, and 11 are set so that the ambient noise level at which the level of the high-frequency component of the microphone begins to decrease becomes higher.
Compared with the rate of change in the level of the low frequency component of the sound signal collected by the bone conduction microphone 2 and the level of the low frequency component of the sound signal collected by the bone conduction microphone 2 with respect to the ambient noise level. By setting the rate of change of the level to be smaller, sound quality can be ensured even when the noise level increases.

Based on the noise level at the ambient noise level input terminal 12, the control information providing unit 13 determines the information to be provided to the high frequency signal level control unit 9 and the low frequency signal level control units 10 and 11. For example, in the case where the level control units 9, 10, and 11 are amplifiers that can control the amplification factor of the input signal by the control voltage, the correspondence between the ambient noise level and the input terminal voltage is determined in advance, so that the levels shown in FIGS. The characteristics can be reflected in the level controllers 9, 10, and 11.

The high frequency component of the transmission signal from the level control unit 9 and the low frequency component of the transmission signal from the level control units 10 and 11 are mixed by a mixing circuit 14. The signal mixed by the mixing circuit 14 is sent to a transmission signal output terminal 15 for a telephone line circuit.

The correspondence between the present invention and the embodiment is as follows.

In the present invention, as shown in FIG. 6, an air-conducting microphone 1 and a bone-conducting microphone 2 are provided as sound pickup units, and a high-pass filter 6 and a low-pass filter for the air-conducting microphone are used as frequency component extracting means. 7 and a low-pass filter 8 for a bone conduction microphone. An ambient noise level input terminal 12 corresponds to the ambient noise level input means. Further, as level control means, level control units 9, 10, 11
The mixing circuit 14 corresponds to the synthesizing means.

[0024]

As described above, the present invention relates to a communication device using an air conduction microphone and a bone conduction microphone as a sound collection unit, and a low frequency component of a sound pickup signal of the air conduction microphone and a bone conduction microphone. Ambient noise at which the level of the high-frequency component of the sound pickup signal of the air-conduction sound microphone begins to decrease with respect to the ambient noise level at which the level ratio of the sound pickup signal of the sound pickup to the low-frequency component becomes 1 Since the level is set high, it is possible to transmit a good voice in the usage environment.

The ratio of the change in the level of the low-frequency component of the sound signal picked up by the microphone for air-conducted sound and the low-frequency component of the signal picked up by the pickup for bone-conducted sound with respect to the ambient noise level is compared with the above-mentioned ratio. Since the level control means is set to reduce the rate of change of the level of the high frequency component of the sound signal collected by the air-conducting microphone, the sound signal collected by the air-conducting microphone or the signal collected by the bone-conducting microphone is optimally reproduced. Since the transmission signal is generated by controlling or synthesizing the transmission signal so as to reflect the ambient noise level, the sound quality of the transmission signal can be improved.

Here, the effects of the present invention have been described with reference to the embodiments of the communication device. However, even in the transmission and reception of ordinary telephones, the optimum sound quality can be obtained in the environment and condition of the ambient noise during use. By using the air conduction microphone and the bone conduction microphone, a transmission signal can be generated.

[Brief description of the drawings]

FIG. 1 is a diagram showing the relationship between the sound quality of a high-frequency component of a collected air-conducted sound and the ambient noise level.

FIG. 2 is a diagram showing a relationship between an optimum level of a high-frequency component of collected air conduction sound and an ambient noise level.

FIG. 3 is a diagram showing a relationship between each sound quality of low frequency components of collected bone conduction sound and air conduction sound and an ambient noise level.

FIG. 4 is a diagram illustrating a relationship between an optimum mixing ratio of low-frequency components of collected bone conduction sound and air conduction sound and an ambient noise level.

FIG. 5 is a diagram illustrating a high-frequency component of a picked-up signal;
FIG. 5 is a diagram showing a relative relationship of FIG. 4 showing low frequency components.

FIG. 6 is a block diagram showing a configuration of one embodiment of the present invention.

[Explanation of symbols]

 Reference Signs List 1 air conduction microphone (microphone for air conduction sound) 2 bone conduction microphone (pickup for bone conduction sound) 3 amplifier for air conduction microphone 4 amplifier for bone conduction microphone 5 filter 6 high pass filter (HPF) for air conduction microphone 7 Low-pass filter (LPF) for air conduction microphone 8 Low-pass filter (LPF) for bone conduction microphone 9 High-frequency component level control unit 10 Low-frequency component level control unit 11 Low-frequency component level Control unit 12 Ambient noise level input terminal 13 Control information providing unit 14 Mixing circuit 15 Transmission signal output terminal

Claims (2)

[Claims] An air-conducting microphone and a bone-conducting sound pickup, two sound-collecting parts, a low-frequency component and a high-frequency component of a sound-collecting signal of the air-conducting sound microphone, and the bone-conducting sound. Frequency component extracting means for respectively extracting low frequency components of a pickup signal of a pickup, ambient noise level input means for inputting an ambient noise level when the sound pickup section is used, and as the ambient noise level increases, Reducing the level ratio between the low-frequency component of the sound signal picked up by the air-conducting microphone and the low-frequency component of the sound signal picked up by the bone-conducting sound pickup; A communication apparatus comprising: level control means for reducing a level of a high frequency component; and synthesis means for synthesizing the three types of frequency components adjusted by the level control means as a transmission signal, The level control means controls the ambient noise level at which the level ratio between the low frequency component of the sound signal picked up by the air-conducting microphone and the low frequency component of the sound signal picked up by the bone-conducted sound pickup becomes 1. A communication device, wherein the ambient noise level at which the level of the high frequency component of the sound pickup signal of the air conduction microphone starts to decrease is set high. 2. The communication device according to claim 1, wherein a low-frequency component of a sound signal picked up by the air-conducting microphone and a low-frequency component of a sound signal picked up by the bone-conducting sound pickup have a level relative to an ambient noise level. A communication device, wherein the level control means is set to have a smaller rate of change of the level of the high frequency component of the sound pickup signal of the air conduction microphone than a change rate of the air conduction sound microphone.