KR102350487B1 - Active noise cancelling system and method using plural driver units - Google Patents

Abstract

An active noise canceling system equipped with a plurality of driver units comprises: a microphone that receives ambient noise; an analog digital converter (ADC) that converts an outputted signal from the microphone; a digital signal processor (DSP) that receives an audio signal and an output signal of the ADC, processes the signal, and outputs a first signal and a second signal; a first digital analog converter (DAC) that converts the first signal; a second DAC that converts the second signal; a first amplifier that amplifies an output of the first DAC; a second amplifier that amplifies an output of the second DAC; a first driver unit that outputs an output signal of the first amplifier; and a second driver unit that outputs an output signal of the second amplifier. In a noise canceling on mode, the DSP generates an inverse phase signal of the ADC output signal and outputs thereof as the first signal; processes the audio signal and outputs thereof as the second signal; and the DSP processes the audio signal, in a noise canceling off mode, and outputs the first signal and the second signal. Therefore, the present invention is capable of improving an ANC performance.

Description

An active noise canceling system and an active noise canceling method having a plurality of driver units TECHNICAL FIELD

The technology to be described below relates to an active noise canceling (ANC) system.

Recently, an earphone or a headphone that provides an ANC function is attracting attention. ANC is a technology that removes ambient noise by collecting external noise with a microphone and outputting an antiphase signal of the collected noise. A conventional earphone has a separate battery and circuit for ANC.

Korean Patent No. 10-2137151

A typical passive earphone consists of a speaker driver unit and a wired plug, and analog conversion and signal amplification are handled by a source device such as a smartphone. In contrast, active type earphones, such as Bluetooth earphones or USB earphones, receive digital signals from a source device and directly process analog signal conversion and signal amplification. Since these active earphones have their own DAC (D/A Converter), amplifier, microphone, and digital signal processing (DSP) hardware all in one, it is difficult to perform active noise cancellation, that is, active noise cancellation. It provides a suitable hardware structure. For ANC, the ambient sound collected in real time through the microphone must be converted into anti-phase in real time and output through the built-in speaker. At this time, in the case of listening to music, a signal for ANC and a music signal must be output simultaneously. A conventional ANC earphone simultaneously outputs an out-of-phase signal of ambient noise and an audio signal for listening to music through one DAC (D/A Converter), an amplifier, and a driver unit. In this case, since the ANC signal and the music signal share the limited hardware provided by the audio chain of the existing DAC, amplifier, and speaker unit, the ANC performance deteriorates, and at the same time, the final quality of the audio signal for listening to music is also has a lower limit.

The technology to be described below is intended to provide an ANC system that separately processes an ANC function and basic audio using a plurality of driver units.

An active noise canceling system including a plurality of driver units includes a first microphone that receives ambient noise, a first analog digital converter (ADC) that converts a signal output from the first microphone, an audio signal, and an output of the first ADC A digital signal processor (DSP) that receives a signal, processes the signal, and outputs a first signal and a second signal, a first digital analog converter (DAC) that converts the first signal, and a second converts the second signal DAC, a first amplifier amplifying an output of the first DAC, a second amplifier amplifying an output of the second DAC, a first driver unit outputting an output signal of the first amplifier, and an output signal of the second amplifier and a second driver unit that outputs

The first driver unit and the second driver unit are included in one first speaker device, and in a noise canceling on mode, the DSP generates an antiphase signal of the first ADC output signal to generate the first signal , and processes the audio signal to output the second signal, and in a noise canceling off mode, the DSP processes the audio signal and outputs the first signal and the second signal.

In the active noise canceling method using a plurality of driver units, a first analog digital converter (ADC) converts a signal of a first microphone that receives and outputs ambient noise into a digital signal, a digital signal processor (DSP) uses an audio signal and receiving the output signal of the first ADC and outputting a first signal and a second signal; converting the first signal into an analog signal by a first digital analog converter (DAC); converting a signal into an analog signal; outputting, by a first driver unit included in a first speaker unit, a first signal converted into the analog signal; and a second driver unit included in the first speaker unit, converting the analog signal to the analog signal. and outputting a second signal converted into a signal. In the noise canceling on mode, the DSP generates an antiphase signal of the ADC output signal and outputs it as the first signal, processes the audio signal to output the second signal, and noise canceling off In the mode, the DSP processes the audio signal and outputs the first signal and the second signal.

The technology described below improves ANC performance by providing an ANC dedicated DAC, amplifier, and speaker driver unit. Furthermore, the techniques described below also improve basic audio quality by using individual driver units for audio signal output.

1 is an example of a conventional ANC system.
2 is an example of a flowchart for an operation process of an ANC system having a plurality of driver units.
3 is an example of an ANC system having a plurality of driver units.
4 is another example of an ANC system having a plurality of driver units.
5 is another example of an ANC system having a plurality of driver units.
6 is an example of an ANC system operation in an ANC off mode.
7 is another example of an ANC system operation in an ANC off mode.

The technology to be described below can apply various changes and can have various embodiments, and specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the technology described below to specific embodiments, and it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the technology described below.

Terms such as first, second, A, and B may be used to describe various components, but the components are not limited by the above terms, and only for the purpose of distinguishing one component from other components. is used only as For example, a first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component without departing from the scope of the present invention. and/or includes a combination of a plurality of related listed items or any of a plurality of related listed items.

In terms of terms used herein, the singular expression should be understood to include the plural expression unless the context clearly dictates otherwise, and terms such as "comprises" include the described feature, number, step, operation, element. , parts or combinations thereof are to be understood, but not to exclude the possibility of the presence or addition of one or more other features or numbers, step operation components, parts or combinations thereof.

Prior to a detailed description of the drawings, it is intended to clarify that the classification of the constituent parts in the present specification is merely a division according to the main function each constituent unit is responsible for. That is, two or more components to be described below may be combined into one component, or one component may be divided into two or more for each more subdivided function. In addition, each of the constituent units to be described below may additionally perform some or all of the functions of other constituent units in addition to the main function it is responsible for. Of course, it can also be performed by being dedicated to it.

In addition, in performing the method or method of operation, each process constituting the method may occur differently from the specified order unless a specific order is clearly described in context. That is, each process may occur in the same order as specified, may be performed substantially simultaneously, or may be performed in the reverse order.

The technology to be described below relates to an ANC method provided in earphones or headphones. Accordingly, the techniques described below may be applied to devices such as earphones or headphones. Earphones or headphones output a constant audio signal. Here, the audio signal may be a voice of a call party, a reproduction sound of media content, or the like. Media content includes music, video, games, and the like.

Earphones or headphones with ANC function may also be called ANC system. Hereinafter, the ANC system refers to a device that simultaneously provides an ANC function and another audio signal output. The ANC system may be implemented in devices such as earphones or headphones.

1 is an example of a conventional ANC system 100 . The ANC system 100 includes an analog digital converter (ADC) 110 , a digital signal processor (DSP) 120 , a digital analog converter (DAC) 130 , an amplifier (AMP) 140 , and a driver unit 150 .

The ADC 110 receives the ambient noise signal transmitted from the microphone. The ADC 110 converts an analog signal into a digital signal. The ADC 110 outputs a digital signal for ambient noise.

The DSP 120 is a component that uniformly processes an input signal. For example, the DSP 120 may classify an input signal according to a frequency band or a channel. The DSP 120 may adjust the level or gain of the input signal. The DSP 120 may adjust the phase of the input signal.

The DSP 120 may generate an out-of-phase ambient noise signal by changing the phase of the ambient noise output by the ADC 110 by 180 degrees. In addition, the DSP 120 receives an audio signal and processes it uniformly. The audio signal may be transmitted from a device such as a separate sound source reproducing device or a smart device. The DSP 120 may process and output an out-of-phase ambient noise signal and an audio signal, respectively.

The DAC 130 converts the output signal of the DSP 120 into an analog signal. The AMP 140 constantly amplifies the converted analog signal.

The driver unit 150 outputs the amplified analog signal. The driver unit 150 outputs both the out-of-phase ambient noise signal and the audio signal.

The ANC system 100 outputs both an out-of-phase ambient noise signal and an audio signal to one driver unit 150 . Since the audio signal and the out-of-phase ambient noise signal share the limited dynamic range of the driver unit 150 , both the ANC performance and the audio reproduction quality of the ANC system 100 may be degraded. In addition, since the out-of-phase ambient noise signal and the audio signal share the same DAC 130 and the AMP 140 , it is difficult to set the gain for the individual signal in the ANC system 100 .

The technology described below assumes an ANC system having a plurality of driver units. The technology described below corresponds to a system having a dedicated DAC, AMP, and driver unit for ANC. In addition, for convenience of description below, the description will be made based on a mono channel. In the case of stereo, the ANC system described below may be individually applied to the left and right channels.

2 is an example of a flowchart for an operation process 200 of an ANC system having a plurality of driver units.

The ANC system receives a selection for the ANC mode ( 210 ). The ANC mode is divided into an ANC on mode and an ANC off mode. The ANC on mode is a mode in which the ANC function operates. The ANC off mode is a mode in which the ANC function does not operate. The user can selectively drive the ANC mode according to the situation. For example, the user may select on or off of the ANC operation through a separate interface. Furthermore, the ANC system may adaptively select on or off of the ANC operation according to the ambient noise environment.

The ANC system determines the ANC mode (220).

Steps 231 to 234 in FIG. 2 are operations according to the ANC on mode. In the ANC On mode (ANC On of 220), the ANC system can separately process the ambient noise signal and the audio signal. The ANC system receives an ambient noise signal from the microphone (231). The ANC system generates a first signal by processing ambient noise using DSP ( 232 ). The first signal is an out-of-phase ambient noise signal. Also, the ANC system receives an audio signal ( 233 ). The ANC system generates a second signal by constantly processing the audio signal using the DSP ( 234 ). The second signal is an audio signal.

Steps 241 to 242 in FIG. 2 are operations according to the ANC off mode. In the ANC off mode (ANC Off of 220), the ANC system processes only the audio signal. The ANC system receives an audio signal (241). The ANC system generates a first signal and a second signal by processing the audio signal using the DSP (242). Both the first signal and the second signal are audio signals. For example, the DSP may generate a first signal and a second signal that are signals of different frequency bands by classifying signals according to frequency bands.

The ANC system has a plurality of driver units. For convenience of description, it is assumed that the ANC system has a first driver unit and a second driver unit. The ANC system outputs a first signal through the first driver unit ( 251 ). The ANC system outputs the second signal through the second driver unit ( 252 ). In the ANC on mode, the first driver unit outputs an out-of-phase ambient noise signal, and the second driver unit outputs an audio signal. In the ANC off mode, the first driver unit and the second driver unit respectively output an audio signal.

The ANC system checks whether the operation of the system is terminated ( 260 ), and if not, the ANC on mode operation or the ANC off mode operation is repeatedly performed in the currently set ANC mode.

Hereinafter, FIGS. 3 to 5 are examples of the ANC system operation in the ANC on mode.

3 is an example of an ANC system 300 having a plurality of driver units. ANC system 300 includes MIC (microphone, 305), ADC 310, DSP 320, first DAC 331, second DAC 332, first AMP 341, second AMP 342 , a first driver unit 351 and a second driver unit 352 .

The MIC 305 receives ambient noise and outputs an analog signal.

The ADC 310 receives an ambient noise signal transmitted from a microphone. The ADC 310 converts an analog signal into a digital signal. ADC 310 outputs a digital signal N for ambient noise.

The DSP 320 is a component that uniformly processes an input signal. For example, the DSP 320 may classify an input signal according to a frequency band or a channel. The DSP 320 may adjust the level or gain of the input signal. The DSP 320 may adjust the phase of the input signal.

The DSP 320 may generate an out-of-phase ambient noise signal N' by changing the phase of the ambient noise output by the ADC 310 by 180 degrees. In addition, the DSP 320 receives the audio signal S and processes it uniformly. The audio signal may be transmitted from a device such as a separate sound source reproducing device or a smart device. The DSP 320 may process the out-of-phase ambient noise signal N and the audio signal S, respectively, and output N' and S'. Unlike FIG. 3 , a DSP for processing ambient noise and a DSP for processing an audio signal may be used separately.

The first DAC 331 receives the out-of-phase ambient noise signal N' and converts it into an analog signal. The first DAC 331 outputs the converted out-of-phase ambient noise signal N _{A .}

The first AMP 341 receives the out-of-phase ambient noise signal N _A and amplifies it. The first AMP 341 outputs the amplified anti-phase ambient noise signal N′ _A .

The first driver unit 351 receives the out-of-phase ambient noise signal N' _A and outputs it.

The second DAC 332 receives the audio signal S' and converts it into an analog signal. The second DAC 332 outputs the _{converted audio signal S A .}

The second AMP 342 receives the audio signal S _A and amplifies it. The second AMP 342 outputs the amplified audio signal S' _A.

A second driver unit 352 outputs the received input audio signal S _'A.

The first driver unit 351 and the second driver unit 352 are included in the same speaker device 350 . One speaker device may be a device that transmits an output signal to one ear. For example, the first driver unit 351 and the second driver unit 352 may be disposed on the left or right earphone unit.

As the driver unit, a dynamic moving coil driver, a balanced armature driver, or the like may be used.

The ANC system 300 may include additional components for operation, such as a power supply. 2 does not show a separate power supply device.

The ANC system 300 separately processes the ambient noise signal and the audio signal and outputs them to individual driver units. Accordingly, the ANC system 300 can make the most of the dynamic range of a given hardware. The ANC system 300 has improved ANC performance and improved audio reproduction quality at the same time. Furthermore, individual DACs and AMPs for processing ambient noise signals and audio signals can be used to control each purpose.

The first DAC 331 and the first AMP 341 may be set as optimal parameters for ANC. The ANC system 300 inputs parameters stored in a separate storage medium to the first DAC 331 and/or the first AMP 341 in real time, and the first DAC 331 and/or the first AMP 341 ANC can contribute to optimal performance. That is, the ANC system 300 may perform optimized control for ANC performance in the ANC on mode.

The second DAC 332 and the second AMP 342 may be set as optimal parameters for the audio stream. The ANC system 300 inputs parameters stored in a separate storage medium to the second DAC 332 and/or the second AMP 342 in real time, and the second DAC 332 and/or the second AMP 342 You can optimize the quality of the corresponding audio stream. That is, the ANC system 300 may perform an optimized control for high quality of the audio stream in the ANC on mode.

4 is another example of an ANC system 400 having a plurality of driver units. ANC system 400 is MIC (405), ADC (410), DSP (420), first DAC (431), second DAC (432), first AMP (441), second AMP (442), second It includes a first driver unit 451 , a second driver unit 452 , a third driver unit 461 , and a fourth driver unit 462 .

The MIC 405 receives ambient noise and outputs an analog signal.

The ADC 410 receives the ambient noise signal transmitted from the microphone. The ADC 410 converts an analog signal into a digital signal. ADC 410 outputs a digital signal N for ambient noise.

The DSP 420 is a component that uniformly processes an input signal. For example, the DSP 420 may classify an input signal according to a frequency band or a channel. The DSP 420 may adjust the level or gain of the input signal. The DSP 420 may adjust the phase of the input signal.

The DSP 420 may generate an out-of-phase ambient noise signal N' by changing the phase of the ambient noise output by the ADC 410 by 180 degrees. In addition, the DSP 420 receives the audio signal S and processes it uniformly. The audio signal may be transmitted from a device such as a separate sound source reproducing device or a smart device. The DSP 420 may process the out-of-phase ambient noise signal N and the audio signal S, respectively, and output N' and S'. Unlike FIG. 3 , a DSP for processing ambient noise and a DSP for processing an audio signal may be used separately.

The first DAC 431 receives the out-of-phase ambient noise signal N' and converts it into an analog signal. The first DAC 431 outputs the converted out-of-phase ambient noise signal N _{A .}

The first AMP 441 receives the out-of-phase ambient noise signal N _A and amplifies it. The first AMP 441 outputs the amplified anti-phase ambient noise signal N′ _A .

The first driver unit 451 receives the out-of-phase ambient noise signal N' _A and outputs it.

The second DAC 432 receives the audio signal S' and converts it into an analog signal. The second DAC 432 outputs the _{converted audio signal S A .}

The second AMP 442 receives the audio signal S _A and amplifies it. The second AMP 442 outputs the amplified audio signal S' _A.

A second driver unit 452 and outputs the received input audio signal S _'A.

The first driver unit 451 and the second driver unit 452 are included in the same speaker device 450 . One speaker device may be a device that transmits an output signal to one ear. For example, the first driver unit 451 and the second driver unit 452 may be disposed in the left earphone unit.

The third driver unit 461 receives the out-of-phase ambient noise signal N' _A and outputs it.

A fourth driver unit 462 and outputs the received input audio signal S _'A.

The third driver unit 461 and the fourth driver unit 462 are included in the same speaker device 460 . For example, the third driver unit 461 and the fourth driver unit 462 may be disposed in the right earphone unit.

The ANC system 400 may include additional components for operation, such as a power supply. 4 does not show a separate power supply device.

The ANC system 400 separately processes the ambient noise signal and the audio signal and outputs them to individual driver units. Accordingly, the ANC system 400 can make the most of the dynamic range of a given hardware. The ANC system 400 has improved ANC performance and, at the same time, improved audio reproduction quality. Furthermore, individual DACs and AMPs for processing ambient noise signals and audio signals can be used to control each purpose.

The first DAC 431 and the first AMP 441 may be set as optimal parameters for ANC. The ANC system 400 inputs parameters stored in a separate storage medium to the first DAC 431 and/or the first AMP 441 in real time, and the first DAC 431 and/or the first AMP 441 ANC can contribute to optimal performance. That is, the ANC system 400 may perform optimized control for ANC performance in the ANC on mode.

The second DAC 432 and the second AMP 442 may be set as optimal parameters for the audio stream. The ANC system 400 inputs parameters stored in a separate storage medium to the second DAC 432 and/or the second AMP 442 in real time, and the second DAC 432 and/or the second AMP 442 You can optimize the quality of the corresponding audio stream. That is, the ANC system 400 may perform optimized control for high quality of the audio stream in the ANC on mode.

5 is another example of an ANC system 500 having a plurality of driver units.

The ANC system 500 includes a first MIC 505 , a second MIC 506 , an ADC 510 , a DSP 520 , a first DAC 531 , a second DAC 532 , and a first AMP 541 ). , a second AMP 542 , a first driver unit 551 , a second driver unit 552 , a third driver unit 561 , and a fourth driver unit 562 . The ANC system 500 uses two microphones.

The first MIC 505 and the second MIC 506 are devices included in one speaker device (eg, a left earphone or headphone). The first MIC 505 and the second MIC 506 are microphones having different directivity, respectively. That is, the first MIC 505 and the second MIC 506 may receive external noise in different directions, respectively.

The first MIC 505 receives the ambient noise in the first direction based on the user reference and outputs an analog signal N ¹ . The first direction means a direction in which noise is input.

^{The second MIC 506 outputs an analog signal N 2} by receiving the ambient noise in the second direction based on the user reference. The second direction means a direction in which noise is input.

The ADC 510 receives an ambient noise signal transmitted from a microphone. The ADC 510 converts an analog signal into a digital signal. ADC (510) and outputs the digital signal N ¹ _D to N ^1. Further, ADC (510) and outputs the digital signal _D N ² to N ^2. The ADC 510 may be configured with two ADCs that individually process ^{N 1} and N ^{2 .}

The DSP 520 is a component that uniformly processes an input signal. For example, the DSP 520 may classify an input signal according to a frequency band or a channel. The DSP 520 may adjust the level or gain of the input signal. The DSP 520 may adjust the phase of the input signal.

DSP 520 changes the phase with respect to the ambient noise output by the ADC 510 by 180 degrees, so that the out-of-phase ambient noise signal N' ¹ _D and N′ ² _D , respectively.

In addition, the DSP 520 receives the audio signal S and processes it uniformly. The audio signal may be transmitted from a device such as a separate sound source reproducing device or a smart device.

The DSP 520 may individually include a DSP for processing ambient noise and a DSP for processing an audio signal. Also, the DSP 520 may separately include a DSP for processing left ambient noise and a DSP for processing right ambient noise.

The first DAC 531 is an out-of-phase ambient noise signal N' ¹ _D and N' ² _D are received and converted into an analog signal. The first DAC 531 is a converted out-of-phase ambient noise signal N ¹ _A and N ² _A . The first DAC 531 is N' ¹ _D and separate DACs each processing N′ ² _{D .}

The first AMP 541 is an out-of-phase ambient noise signal N ¹ _A and N ² _A are received and amplified. The first AMP 541 is an amplified anti-phase ambient noise signal N' ¹ _A and N' ² _A . The first AMP 541 is N ¹ _A and individual AMPs that each process ^{N 2} _{A .}

The second DAC 532 receives the audio signal S' and converts it into an analog signal. The second DAC 532 outputs the _{converted audio signal S A .}

The second AMP 542 receives the audio signal S _A and amplifies it. The second AMP 542 outputs the amplified audio signal S' _A.

The first driver unit 551 , the second driver unit 552 , the third driver unit 553 , and the third driver unit 554 may be included in the same speaker device 550 .

The first driver unit 551 receives and outputs the out-of-phase ambient noise signal N′ ¹ _{A .}

A second driver unit 552 outputs the received input audio signal S _'A.

The third driver unit 553 receives and outputs the out-of-phase ambient noise signal N′ ² _{A .}

A fourth driver unit 554 outputs the received input audio signal S _'A.

In some cases, the audio signal S′ _A may be output from only one driver unit 552 or 554 .

Meanwhile, the first driver unit 551 outputs an anti-phase signal with respect to the noise input to the MIC 505 in the first direction, and the third driver unit 553 is input to the MIC 506 in the second direction. Outputs an anti-phase signal for noise. Accordingly, the first driver unit 551 and the third driver unit 553 may have directivity corresponding to the first direction and the second direction, respectively. For example, the first driver unit 551 may output an anti-phase signal in a direction opposite to that of the noise in the first direction. Also, the third driver unit 553 may output an anti-phase signal in a direction opposite to the noise in the second direction.

In addition, unlike FIG. 5, the out-of-phase ambient noise signal N' ¹ _A and the out-of-phase ambient noise signal N′ ² _A may be output from only one driver unit 551 or 553 . In this case, the DSP 520 may process the two anti-phase signals as a combined signal, and output the combined anti-phase signal as one driver unit.

The ANC system 500 may include additional components for operation, such as a power supply. 5 does not show a separate power supply device.

The ANC system 500 separately processes the ambient noise signal and the audio signal and outputs them to individual driver units. Accordingly, the ANC system 500 can make the most of the dynamic range of the given hardware. The ANC system 500 has improved ANC performance and, at the same time, improved audio reproduction quality. Furthermore, individual DACs and AMPs for processing ambient noise signals and audio signals can be used to control each purpose.

The first DAC 531 and the first AMP 541 may be set as optimal parameters for ANC. The ANC system 500 inputs parameters stored in a separate storage medium to the first DAC 531 and/or the first AMP 541 in real time, and the first DAC 531 and/or the first AMP 541 ANC can contribute to optimal performance. That is, the ANC system 500 may perform an optimized control for ANC performance in the ANC on mode.

The second DAC 532 and the second AMP 542 may be set as optimal parameters for the audio stream. The ANC system 500 inputs parameters stored in a separate storage medium to the second DAC 532 and/or the second AMP 542 in real time, and the second DAC 532 and/or the second AMP 542 You can optimize the quality of the corresponding audio stream. That is, the ANC system 500 may perform optimized control for high quality of the audio stream in the ANC on mode.

6 is an example of an ANC system operation in an ANC off mode. 6 is an example illustrating the ANC off mode based on the ANC system 300 .

In ANC off mode, the DSP does not process the ambient noise signal. Since power is not supplied to the MIC 305 and/or the ADC 310, noise signal collection or signal conversion may not be performed.

The DSP 320 is a component that uniformly processes an input signal. For example, the DSP 320 may classify an input signal according to a frequency band or a channel. The DSP 320 may adjust the level or gain of the input signal. The DSP 320 may adjust the phase of the source audio signal. The DSP 320 may set an offset that determines the frequency range according to the frequency response characteristic of the source audio signal. The DSP 320 may adjust or change the signal based on the frequency band of the source audio signal.

It is assumed that the DSP 320 performs a digital crossover for dividing an input signal into a desired frequency band.

The DSP 320 may output signals S1' and S2' for different frequency bands. For convenience of description, it is assumed that S1' is a signal of a first band and S2' is a signal of a second band.

The first DAC 331 receives the signal S1' of the first band and converts it into an analog signal. The first DAC 331 outputs the _{converted audio signal S1 A .}

The first AMP 341 receives and amplifies _{S1 A of the first band.} The first AMP 341 outputs the amplified signal S1′ _A of the first band.

The first driver unit 351 receives S1' _A and outputs it.

The second DAC 332 receives the signal S2' of the second band and converts it into an analog signal. The second DAC 332 outputs the _{converted audio signal S2 A .}

The second AMP 342 receives and amplifies _{S2 A of the second band.} The second AMP 342 outputs the amplified signal S2′ _A of the second band.

The first driver unit 351 receives and outputs _{S1' A of the first band.} For example, the first band may be a low frequency band.

The second driver unit 352 receives and outputs _{S2' A of the second band.} For example, the second band may be a high frequency band.

The first driver unit 351 and the second driver unit 352 are included in the same speaker device 350 . One speaker device may be a device that transmits an output signal to one ear. For example, the first driver unit 351 and the second driver unit 352 may be disposed on the left or right earphone unit.

7 is another example of an ANC system operation in an ANC off mode. 7 is an example illustrating the ANC off mode based on the ANC system 300 .

In ANC off mode, the DSP does not process the ambient noise signal. Since power is not supplied to the MIC 305 and/or the ADC 310, noise signal collection or signal conversion may not be performed.

The DSP 320 is a component that uniformly processes an input signal. For example, the DSP 320 may classify an input signal according to a frequency band or a channel. The DSP 320 may adjust the level or gain of the input signal. The DSP 320 may adjust the phase of the source audio signal. The DSP 320 may set an offset that determines the frequency range according to the frequency response characteristic of the source audio signal. The DSP 320 may adjust or change the signal based on the frequency band of the source audio signal.

It is assumed that the DSP 320 performs cross-feed for dividing the input signal into desired channels. Crossfeed is a technology that gives the same effect as hearing from a regular speaker placed in a room. Crossfeed is a function that mixes sound from both channels to one earphone.

DSP 320 may output signals S1' and S2' for different channels. For convenience of description, it is assumed that S1' is a signal of a first channel and S2' is a signal of a second channel.

The first DAC 331 receives the signal S1' of the first channel and converts it into an analog signal. The first DAC 331 outputs the _{converted audio signal S1 A .}

The first AMP 341 receives and amplifies _{S1 A of the first channel.} The first AMP 341 outputs the amplified signal S1′ _A of the first channel.

The first driver unit 351 receives S1' _A and outputs it.

The second DAC 332 receives the signal S2' of the second channel and converts it into an analog signal. The second DAC 332 outputs the _{converted audio signal S2 A .}

The second AMP 342 receives and amplifies _{S2 A of the second channel.} The second AMP 342 outputs the amplified signal S2′ _A of the second channel.

The first driver unit 351 receives and outputs _{S1' A of the first channel.} For example, the first channel may be a left channel.

The second driver unit 352 receives and outputs _{S2' A of the second channel.} For example, the second channel may be a right channel.

Among the left channel and the right channel, a sub channel other than the main channel may be output at a level lower than that of the main channel.

The first driver unit 351 and the second driver unit 352 are included in the same speaker device 350 . One speaker device may be a device that transmits an output signal to one ear. For example, the first driver unit 351 and the second driver unit 352 may be disposed on the left or right earphone unit.

In addition, the audio signal processing method and the active noise canceling method as described above may be implemented as a program (or application) including an executable algorithm that can be executed in a computer. The program may be provided by being stored in a temporary or non-transitory computer readable medium.

The non-transitory readable medium refers to a medium that stores data semi-permanently, rather than a medium that stores data for a short moment, such as a register, cache, memory, and the like, and can be read by a device. Specifically, the various applications or programs described above are CD, DVD, hard disk, Blu-ray disk, USB, memory card, ROM (read-only memory), PROM (programmable read only memory), EPROM (Erasable PROM, EPROM) Alternatively, it may be provided by being stored in a non-transitory readable medium such as an EEPROM (Electrically EPROM) or flash memory.

Temporarily readable media include Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDR SDRAM), Enhanced SDRAM (Enhanced) SDRAM, ESDRAM), Synchronous DRAM (Synclink DRAM, SLDRAM) and Direct Rambus RAM (Direct Rambus RAM, DRRAM) refers to a variety of RAM.

This embodiment and the drawings attached to this specification only clearly show a part of the technical idea included in the above-described technology, and within the scope of the technical idea included in the specification and drawings of the aforementioned technology, those skilled in the art can easily It will be said that it is obvious that all inferred modified examples and specific embodiments are included in the scope of the above-described technology.

Claims (9)

a first microphone receiving ambient noise;
a first ADC (Analog Digital Converter) for converting a signal output from the first microphone;
DSP (digital signal) for processing the output signal and the audio signal of the first ADC and outputting the first signal and the second signal, respectively, or outputting only the audio signal as the first signal and the second signal according to the noise canceling mode processor);
a first digital analog converter (DAC) for converting the first signal;
a second DAC for converting the second signal;
a first amplifier amplifying the output of the first DAC;
a second amplifier amplifying the output of the second DAC;
a first driver unit for outputting an output signal of the first amplifier; and
a second driver unit for outputting an output signal of the second amplifier,
The first driver unit and the second driver unit are included in one first speaker device,
In the noise canceling on mode, the DSP generates an out-of-phase signal of the first ADC output signal and outputs it as the first signal, processes the audio signal and outputs it as the second signal,
In a noise canceling off mode, the DSP processes the audio signal and outputs the first signal and the second signal,
a second microphone for receiving ambient noise; and
Further comprising a second ADC for converting the signal output from the second microphone,
In the noise canceling-on mode, the DSP further generates an anti-phase signal of the second ADC output signal, and combines an anti-phase signal of the first ADC output signal and an anti-phase signal of the second ADC output signal to obtain the second ADC output signal. An active noise canceling system comprising a plurality of driver units outputting one signal. According to claim 1,
In the noise canceling off mode
The DSP divides the audio signal into a first band and a second band according to a frequency band, outputs a signal of the first band as the first signal, and outputs a signal of the second band as the second signal An active noise canceling system comprising a plurality of driver units. According to claim 1,
In the noise canceling off mode
The DSP divides the audio signal into a first channel and a second channel according to channels, outputs a signal of the first channel as the first signal, and outputs a signal of the second channel as the second signal An active noise canceling system comprising a plurality of driver units. delete delete A first analog digital converter (ADC) converting a signal of a first microphone that receives and outputs ambient noise into a digital signal;
converting, by a second ADC, a signal of a second microphone outputted by receiving ambient noise as a digital signal;
A digital signal processor (DSP) processes the output signal and the audio signal of the first ADC respectively according to the noise canceling mode to output the first signal and the second signal, or only the audio signal to the first signal and the second signal outputting as;
converting the first signal into an analog signal by a first digital analog converter (DAC);
converting the second signal into an analog signal by a second DAC;
outputting, by a first driver unit included in a first speaker unit, a first signal converted into the analog signal; and
Comprising the step of outputting, by a second driver unit included in the first speaker unit, a second signal converted into the analog signal,
In a noise canceling on mode, the DSP generates an anti-phase signal of the first ADC output signal and an anti-phase signal of the second ADC output signal, and an anti-phase signal of the first ADC output signal and the second Combining the anti-phase signal of the ADC output signal and outputting it as the first signal, processing the audio signal and outputting it as the second signal,
In a noise canceling off mode, the DSP processes the audio signal and outputs the first signal and the second signal as an active noise canceling method using a plurality of driver units. 7. The method of claim 6,
In the noise canceling off mode
The DSP divides the audio signal into a first band and a second band according to a frequency band, outputs a signal of the first band as the first signal, and outputs a signal of the second band as the second signal An active noise canceling method using a plurality of driver units. 7. The method of claim 6,
In the noise canceling off mode
The DSP divides the audio signal into a first channel and a second channel according to channels, outputs a signal of the first channel as the first signal, and outputs a signal of the second channel as the second signal An active noise canceling method using a plurality of driver units. delete

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