KR0126255B1 - Voice output level control apparatus - Google Patents

Abstract

The output level controlling apparatus of the present invention is comprised of detecting an audio signal(OS) provided from a first sound generating element(14)generated from an audio apparatus(12); an adapted artificial sound having the inverse phase compared with the audio signal being generated in response to the detected audio signal; namely, when the sound pressure level sensors(LS1-LS3) attached to the exterior of an automobile detects an alarming sound of more than a predetermined level, a delivering gate(40) supplying one of outputs of the sound pressure level sensors as a play level attenuation controlling signal to an electronic switch(24); the electronic switch switching to supply the artificial sound provided from DAC(22) to a second sound generating element(28) through an amplifier(26) in the response to the play level attenuation controlling signal; the second sound generating element(28) outputting the artificial sound of the inverse phase.

Description

Voice Pronunciation Output Level Control Device

1 is a voice speaker output level control apparatus according to the present invention.

2 is an attachment position diagram of a sound pressure sensor when the sound pronunciation body output level control device according to the present invention is installed in an automobile.

3 is a waveform diagram illustrating the operation of FIG. 1 according to the present invention;

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a voice output level control circuit of an audio device, and more particularly, to an apparatus for generating an artificial sound having a reverse phase of a sound output from a speaker to attenuate the sound from the speaker.

In general, the method of controlling the output level of an audio device is most commonly used to control the output volume of a volume using a control element such as a variable resistor or a microprocessor or the like. However, the output volume control method of the audio device as described above does not automatically adjust the volume in response to the ambient noise level unless the user manually adjusts the output. This control method becomes an impediment to the safe operation of car audio equipment. For example, if you drive a car with a very high output volume, you may not be able to hear the nearby warning sounds (crackson sounds) in the car's interior, causing driving accidents. This problem causes more problems when driving a complicated road because the user can not adjust the output volume of the car audio in response to the external loudness.

Accordingly, an object of the present invention is to provide an apparatus for attenuating and controlling the volume of sound reproduced from an audio speaker inside a vehicle when the sound pressure level generated from the outside of the vehicle is equal to or greater than a preset sound pressure level.

It is another object of the present invention to adaptively generate an anti-sound having a phase and an inverse phase of an original sound reproduced from a speaker of an audio device by adapting to an external sound and adaptively generating the regenerated sound. The present invention provides an apparatus for controlling the intensity of sound reproduced.

Another object of the present invention is to provide an apparatus for automatically controlling the level of the audio signal output from the speaker of the car audio by adapting to the external sound pressure.

The principle of the present invention for achieving the above object is an adaptive coefficient in a sounding body output level control circuit having an audio device for outputting a voice signal and a first sounding body for reproducing the audio signal output from the audio device with an audible sound, Artificial sound generating means for generating an artificial sound having an inverse phase of the voice signal supplied from the audio device to the first sounding body in response to an input of the audio signal, and amplifying the input voice signal into a predetermined level signal to reproduce the audible sound; Voice signal reproducing means including a second sounding body, transmission means for switching in response to an input of a reproducing level attenuation control signal to transmit output from the artificial sound generating means to the voice signal reproducing means, and more than a preset sound pressure level. Supplying a regeneration level attenuation control signal to the transmission means in response to detecting a large sound pressure level. A sound pressure level detecting means and an adaptation coefficient generating means which is located in a space in which the first and second sounding bodies are placed and provides an adaptation coefficient corresponding to the intensity of an audible sound propagated in the space to the artificial sound generating means; And when the external sound greater than a predetermined sound pressure level is detected, an artificial sound having an inverse phase of the audible sound reproduced by the first sounding body is reproduced by the second sounding body to cancel the sound from the first sounding body. do.

Hereinafter, the present invention will be described in detail with reference to FIGS. 1 to 3.

1 is a block diagram of an apparatus for controlling a sound pronunciation output level according to the present invention. The apparatus for controlling a sound pronunciation output level according to the present invention will be more easily understood by the following description of the operation, but detecting the reproduction sound output from the speaker and generating an artificial sound having an inverse phase of the detected reproduction sound to cancel the sound of the speaker. Sound field control theory is applied.

FIG. 2 is a diagram illustrating the attachment position of the sound pressure sensor when the sound pronunciation output level control device according to the present invention is installed in the vehicle 42, in order to effectively detect warning sounds from the outside. In the present invention, the sound pressure sensors LS1 to LS3 are attached to the left and right side surfaces and the rear surface of the vehicle 42 to effectively detect external warning sounds.

3 is a waveform diagram illustrating the operation of FIG. 1 according to the present invention, which is an artificial sound (AS) having a phase and an inverse phase of the reproduced sound (OS) when the reproduced sound (OS) is converted and released from the sounding body into an audible sound. To convert the audible sound into an audible sound using another sounding body, and cancel the playing sound OS when it is emitted to a field for listening to the playing sound. This principle has already been established in sound field control theory.

Now, when the audio signal OS as shown in FIG. 3 is reproduced and output from the audio device 12, the reproduced audio signal OS is connected to the speaker 14 connected to the output stage and the low pass filter (hereinafter referred to as LPF) ( 16) respectively. The sounding body 14 converts the audio signal output from the audio device 12 into an audible sound and emits it to the interior of the vehicle, that is, the listening field of the reproduction audio. The LPF 16 low-pass filters the audio signal reproduced from the audio device 12. A first analog-to-digital converter (hereinafter referred to as ADC and numbered) 18 connected to the output terminal of the LPF 16 indicates digital audio data output of the LPF 16. It is converted into and supplied to the input terminal of the adaptive digital filter 20.

On the other hand, the microphone 30 located in the field where the sounding body 14 emits an audible sound converts the audible sound in the field into an electrical signal and supplies it to the LPF 32. The LPF 32 low-pass filters the input voice signal and supplies it to the ADC2 34. The ADC2 34 converts the detection signal output from the LPF 32 into a digital signal and outputs the digital signal to the filter coefficient generator 36. Therefore, if the voice signal OS as shown in FIG. 3 from the speaker 14 is converted to an audible sound and output, the microphone popphone 30 detects a signal corresponding to the level of the audible sound output from the speaker 14. It can be seen that the digital coefficient corresponding to the volume level of the field in which the sounding body 14 is located is supplied to the filter coefficient generator 36 by outputting. That is, if a signal such as the OS of FIG. 3 is reproduced from the sounding body 14, digital data corresponding to the OS of FIG. 3 is supplied to the filter coefficient generator 36. FIG.

The filter coefficient generator 36 generates a filter coefficient 38 for generating an inverse phase value of the input digital data value and outputs it to the adaptive digital filter 20. The adaptive digital filter 20 generates digital voice data having a phase opposite to that of the digital voice data output from the LPF 16 in response to the value of the supplied filter coefficient and supplies the digital voice data to the DAC 22. The DAC 22 converts the digital voice data output from the adaptive digital filter 20 into an analog signal and outputs an artificial artificial sound having a waveform like AS in FIG. The digital sound data generated from the adaptive digital filter 20 by this operation is artificial sound that is pseudo-generated.

The digitally generated voice data as described above is input to the electronic switch 24. The electronic switch 24 is switched by the output of the transfer gate 40 which gates one of the outputs of the sound pressure level sensors LS1, LS2, LS3 and outputs a reproduction level attenuation control signal. The transfer gate 40 can be selectively used according to the state of the output signal of the sound pressure level sensors LS1 to LS3. For example, when the output of the sound pressure level sensors LS1 to LS3 is an analog signal, the wired OR circuit may be used. In the case of a logic signal, an OR gate may be used.

As shown in FIG. 2, one of the three sound pressure level sensors LS1 to LS3 attached to the outside of the vehicle 42 detects and outputs an external warning sound, for example, a clock sound having a predetermined level or more. In this case, the transfer gate 40 supplies one of the outputs of the sound pressure level sensors LS1 to LS3 to the electronic switch 24 as a reproduction level attenuation control signal. The electronic switch 40 responds to the regeneration level attenuation control signal output from the transfer gate 40 and through the amplifier 26 outputs an artificial sound output as shown in FIG. 3 as output from the DAC 22. It is supplied to the sounding body 26. By the above-described operation, the sound signal 28 is output from the sounding body 28 opposite to the phase of the reproduction sound signal as shown in FIG.

Therefore, when a warning sound having a predetermined level or more is detected from the outside of the vehicle 42, the sounding body 28 automatically reverses the output of the sounding body 14 which converts the output of the audio device 12 into an audible sound and emits it. The artificial sound having the sound output is instantaneously reduced in the sound pressure level in the field in which the sounding bodies 12 and 28 are placed. At this time, the warning sound of the outside of the car 42 and the artificial sound generated as described above, only the audio sound emitted from the sounding body 14 is weakened without a correlation device, and the external sound, that is, the warning sound remains. By this operation, even when the car-audio output in the vehicle 42 is very large, when an external warning sound is detected, the user automatically attenuates the sound pressure level output from the speaker 12, that is, the speaker, in the vehicle 42. Third party warnings can be easily recognized. By the above operation, even if the volume of the car audio is not manually operated by the driver, the driver can recognize the external warning sound accurately and help the safe driving.

As described above, according to the present invention, in response to the detection of an external warning sound, the driver generates an artificial sound having an antiphase with an audio signal reproduced from a car audio speaker (speaker) inside the vehicle, thereby reducing the sound pressure level inside the vehicle. External warning sound can be recognized accurately for safe operation.

Claims (5)

A sounding body output level control circuit having an audio device for outputting an audio signal and a first sounding body for reproducing the audio signal output from the audio device with an audible sound, comprising: a first sound source from the audio device in response to input of an adaptive coefficient; An artificial sound generating means for generating an artificial sound having an inverse phase of a voice signal supplied to the sounding body, a voice signal reproducing means including a second sounding body for amplifying an input voice signal into a signal of a predetermined level and reproducing the audible sound; A transmission means for switching in response to the input of the reproduction level attenuation control signal to transmit the output from the artificial sound generating means to the audio signal reproduction means, and a reproduction level attenuation in response to detecting a sound pressure level greater than a preset sound pressure level; Sound pressure level detection means for supplying a control signal to the transmission means, and the first, second sounding body Located in the space, and having an adaptation coefficient generating means for providing the artificial sound generating means with an adaptation coefficient corresponding to the intensity of the audible sound propagated in the space when the external sound greater than a predetermined sound pressure level is detected. And an artificial sound having an inverse phase of an audible sound reproduced in the first sounding body cancels the sound from the first sounding body so as to be reproduced in the second sounding body. 2. The apparatus according to claim 1, wherein said artificial sound generating means comprises: first digital changing means for digitally converting a voice signal supplied from said audio device to said first sounding body, and adapting the data output from said first digital converting means; Adaptive digital filtering means for adaptively filtering coefficients and generating digital speech data having a phase and an inverse phase value of a speech signal supplied to the first sounding body; and digital speech data output from the adaptive digital filtering means. And an analog conversion means for converting the signal into a signal and supplying the signal to the transmission means. The microphone according to claim 1 or 2, wherein the adaptive coefficient generating means comprises: a microphone which is located in a space in which the first and first sounding bodies are placed, and converts an audible sound propagated in the space into an electrical signal; Second digital converting means for converting the electric signal from the digital voice data into digital voice data, and filter coefficient generating means for generating an adaptation coefficient of an inverse phase of the digital voice data output from the second digital converting means. Pronunciation body output level control circuit. 3. The sound pressure level detecting means according to claim 2, wherein the sound pressure level detecting means includes sound pressure sensors for generating a reproduction level attenuation control signal in response to detecting an audible signal having a level greater than a preset sound pressure level, and outputs of the sound pressure sensors. And a transfer gate for supplying a reproduction level attenuation control signal to the transmission means in response to at least one output of the sound generator output level control circuit. A sounding body output level control circuit having an audio device for outputting a sound signal and a first sounding body for reproducing a sound signal output from the audio device with an audible sound, the sound signal supplied from the audio device to the first sounding body. First digital converting means for digitally converting, adaptive digital filtering means for generating artificial sound data having a digital voice data phase and an inverse phase output from the first digital converting means in response to input of an adaptive coefficient, and an input voice An audio signal reproducing means comprising a second sounding body for amplifying a signal into a signal of a predetermined level and reproducing it with an audible sound, and artificial sound data which is switched in response to an input of a reproducing level attenuation control signal and output from the adaptive digital filtering means. Digital analog converting means for converting into signals And switching means for switching and connecting the output of the digital analog conversion means to the audio signal reproducing means in response to an input of an audible sound from the outside, and the first and second sounding bodies are located in a space where the space is placed. Filtering for providing the sounding device output level detection means for outputting the digital data to the intensity of the audible sound propagated to the adaptive digital filtering means, and the adaptive coefficient for inverting the phase in response to the digital data output from the sounding body output level detection means. A sounding body output level control circuit comprising: coefficient generation means.