WO2010119528A1 - 能動型振動騒音制御装置 - Google Patents
能動型振動騒音制御装置 Download PDFInfo
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- WO2010119528A1 WO2010119528A1 PCT/JP2009/057592 JP2009057592W WO2010119528A1 WO 2010119528 A1 WO2010119528 A1 WO 2010119528A1 JP 2009057592 W JP2009057592 W JP 2009057592W WO 2010119528 A1 WO2010119528 A1 WO 2010119528A1
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- filter coefficient
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- speakers
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- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10K—SOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
- G10K11/00—Methods or devices for transmitting, conducting or directing sound in general; Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
- G10K11/16—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
- G10K11/175—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general using interference effects; Masking sound
- G10K11/178—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general using interference effects; Masking sound by electro-acoustically regenerating the original acoustic waves in anti-phase
- G10K11/1787—General system configurations
- G10K11/17879—General system configurations using both a reference signal and an error signal
- G10K11/17883—General system configurations using both a reference signal and an error signal the reference signal being derived from a machine operating condition, e.g. engine RPM or vehicle speed
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- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10K—SOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
- G10K11/00—Methods or devices for transmitting, conducting or directing sound in general; Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
- G10K11/16—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
- G10K11/175—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general using interference effects; Masking sound
- G10K11/178—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general using interference effects; Masking sound by electro-acoustically regenerating the original acoustic waves in anti-phase
- G10K11/1785—Methods, e.g. algorithms; Devices
- G10K11/17853—Methods, e.g. algorithms; Devices of the filter
- G10K11/17854—Methods, e.g. algorithms; Devices of the filter the filter being an adaptive filter
-
- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10K—SOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
- G10K11/00—Methods or devices for transmitting, conducting or directing sound in general; Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
- G10K11/16—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
- G10K11/175—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general using interference effects; Masking sound
- G10K11/178—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general using interference effects; Masking sound by electro-acoustically regenerating the original acoustic waves in anti-phase
- G10K11/1785—Methods, e.g. algorithms; Devices
-
- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10K—SOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
- G10K11/00—Methods or devices for transmitting, conducting or directing sound in general; Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
- G10K11/16—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
- G10K11/175—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general using interference effects; Masking sound
- G10K11/178—Methods or devices for protecting against, or for damping, noise or other acoustic waves in general using interference effects; Masking sound by electro-acoustically regenerating the original acoustic waves in anti-phase
- G10K11/1785—Methods, e.g. algorithms; Devices
- G10K11/17857—Geometric disposition, e.g. placement of microphones
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- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10K—SOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
- G10K2210/00—Details of active noise control [ANC] covered by G10K11/178 but not provided for in any of its subgroups
- G10K2210/10—Applications
- G10K2210/128—Vehicles
- G10K2210/1282—Automobiles
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- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10K—SOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
- G10K2210/00—Details of active noise control [ANC] covered by G10K11/178 but not provided for in any of its subgroups
- G10K2210/50—Miscellaneous
- G10K2210/503—Diagnostics; Stability; Alarms; Failsafe
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R2499/00—Aspects covered by H04R or H04S not otherwise provided for in their subgroups
- H04R2499/10—General applications
- H04R2499/13—Acoustic transducers and sound field adaptation in vehicles
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04S—STEREOPHONIC SYSTEMS
- H04S7/00—Indicating arrangements; Control arrangements, e.g. balance control
- H04S7/30—Control circuits for electronic adaptation of the sound field
- H04S7/301—Automatic calibration of stereophonic sound system, e.g. with test microphone
Definitions
- the present invention relates to a technical field in which vibration noise is actively controlled using an adaptive notch filter.
- an active vibration noise control device in which engine sound that can be heard in a vehicle cabin is controlled by control sound output from a speaker, and engine sound is reduced at the occupant's ear position.
- Patent Document 1 focusing on the fact that vibration noise in the vehicle interior is generated in synchronization with the rotation of the output shaft of the engine, the vehicle interior noise having a frequency based on the rotation of the engine output shaft is applied to an adaptive notch filter.
- This adaptive notch filter is a filter based on adaptive control.
- Patent Document 2 and Non-Patent Document 1.
- An object of the present invention is to provide an active vibration noise control device capable of appropriately suppressing the occurrence of a non-uniform sound deadening area and ensuring a wide sound deadening area.
- the active vibration noise control apparatus having a pair of speakers and generating a control sound from the speakers is a reference signal based on a vibration noise frequency generated from a vibration noise source.
- An adaptive notch filter that generates a first control signal to be output to one of the speakers and generates a second control signal to be output to the other of the speaker by using a second filter coefficient for the reference signal.
- a microphone that detects an offset error between the vibration noise and the control sound and outputs an error signal, and a transfer function from the speaker to the microphone.
- Reference signal generating means for generating a reference signal from a reference signal, and based on the error signal and the reference signal, the first filter coefficient and the first filter coefficient used in the adaptive notch filter so that the error signal is minimized.
- Filter coefficient updating means for updating two filter coefficients, and phase difference limiting means for limiting a phase difference between a control sound generated from one of the speakers and a control sound generated from the other of the speakers.
- FIG. 1 is a block diagram showing the configuration of an active vibration noise control apparatus according to a first embodiment. It is a figure for demonstrating concretely the process performed by w limiter. It is a flowchart which shows the process which w limiter performs. It is a figure for demonstrating the effect by the active vibration noise control apparatus in 1st Example.
- the block diagram of the configuration of the active vibration noise control apparatus in the second embodiment is shown. It is a flowchart which shows the process which a phase difference limiting part performs.
- an active vibration noise control apparatus that has a set of two speakers and generates a control sound from the speakers generates a reference signal based on a vibration noise frequency generated from a vibration noise source.
- An adaptive notch filter that generates a first control signal to be output to one of the speakers and generates a second control signal to be output to the other of the speakers by using a second filter coefficient for the reference signal; Detecting a cancellation error between the vibration noise and the control sound and outputting the error signal as an error signal; and a transfer function from the speaker to the microphone
- Reference signal generating means for generating a reference signal from a reference signal, and based on the error signal and the reference signal, the first filter coefficient and the first filter coefficient used in the adaptive notch filter so that the error signal is minimized.
- Filter coefficient updating means for updating two filter coefficients
- phase difference limiting means for limiting a phase difference
- the above-described active vibration noise control apparatus has two pairs of speakers, and is preferably used to cancel generated vibration noise from the vibration noise source by generating control sound from the speakers.
- the reference signal generating means generates a reference signal based on the vibration noise frequency generated from the vibration noise source, and the adaptive notch filter outputs the first signal to one of the speakers by using the first filter coefficient for the reference signal.
- a control signal is generated, and a second control signal to be output to the other speaker is generated by using the second filter coefficient with respect to the reference signal.
- the microphone detects the cancellation error between the vibration noise and the control sound and outputs it as an error signal.
- the reference signal generation means generates a reference signal from the reference signal based on the transfer function from the speaker to the microphone, and updates the filter coefficient.
- the means updates the first filter coefficient and the second filter coefficient used in the adaptive notch filter so that the error signal is minimized. Then, the phase difference limiting means performs a process of limiting the phase difference between the control sound generated from one of the speakers and the control sound generated from the other of the speakers.
- the above active vibration and noise control device it is possible to appropriately suppress the occurrence of a non-uniform noise reduction area. Therefore, it is possible to appropriately ensure a uniform and wide range of silence area. Moreover, since the amplitude of the control sound can be prevented from increasing by limiting the phase difference, it is possible to secure a wide range of mute areas with the control sound having a relatively low volume.
- the phase difference limiting unit limits the phase difference so that a sound pressure distribution generated by the control sound from the speaker is uniform. That is, the phase difference limiting unit can limit the phase difference so that the sound pressure distribution generated by the two speakers is not biased.
- the phase difference limiting unit may be configured such that the first filter coefficient and the second filter coefficient updated by the filter coefficient updating unit are on a two-dimensional plane.
- the phase difference limiting means includes the first filter coefficient and the first filter coefficient before being updated by the filter coefficient updating means when the angle difference exceeds the predetermined angle.
- Two filter coefficients can be output to the adaptive notch filter.
- the phase difference limiting unit may set the phase difference between the first control signal and the second control signal generated by the adaptive notch filter within a predetermined value. By limiting, the phase difference between the control sound generated from one of the speakers and the control sound generated from the other of the speakers is limited. This also makes it possible to appropriately limit the phase difference of the control sound between the speakers.
- the phase difference limiting means is configured such that when the phase difference exceeds the predetermined value, the phase of the first control signal or the second control signal is advanced.
- the control signal can be delayed by an amount corresponding to the difference between the phase difference and the predetermined value.
- the speaker is disposed in the vicinity of the vibration noise source.
- the speaker is provided at a position on the front side in the vehicle interior. As a result, it is possible to effectively cancel out the generated vibration noise from the vibration noise source.
- FIG. 1 an active vibration noise control apparatus that has two speakers 10L and 10R and two microphones 11L and 11R and is mounted on the vehicle 1 will be described as an example.
- the speakers 10L and 10R and the microphones 11L and 11R are installed on the front side in the vehicle interior.
- the speakers 10L and 10R are installed on the front door.
- the speakers 10L and 10R are configured in pairs.
- This active vibration noise control apparatus is an apparatus that actively controls vibration noise of an engine that is a vibration noise source by generating a control sound from a speaker based on a frequency according to rotation of an engine output shaft. Specifically, the vibration noise is actively controlled by feeding back an error signal detected by a microphone and minimizing the error using an adaptive notch filter. Basically, in the conventional active vibration noise control apparatus, optimization is performed so that the error is minimized at the microphone point.
- FIG. 2 is a diagram for explaining problems in such a conventional active vibration noise control apparatus.
- FIG. 2 shows an example of a sound pressure distribution in the passenger compartment when a control sound is generated from the speakers 10L and 10R in order to actively control engine vibration noise by a conventional active vibration noise control apparatus. From this, as indicated by the broken line area 71, it can be seen that the sound is increased except for the microphone point, and a non-uniform sound deadening area is generated. Specifically, it can be seen that the sound is increased at the left rear seat.
- FIG. 3 is a diagram for explaining a specific example of the phase difference between the speakers 10L and 10R.
- the control sound sine wave generated from each of the left speaker 10L and the right speaker 10R by the microphone provided at the front seat central position 73 in the vehicle interior.
- sine waves having various frequencies are output from each of the left speaker 10L and the right speaker 10R.
- FIG. 3B shows an example of the relationship between the correlation value for the phase difference (shown on the horizontal axis) and the frequency (shown on the vertical axis) obtained by recording as described above.
- the left direction indicates that the control sound of the left speaker 10L is delayed in phase from the control sound of the right speaker 10R
- the right direction indicates that the control sound of the right speaker 10R is the left speaker 10L. It is assumed that the phase is delayed from the control sound.
- the frequency shown on the vertical axis corresponds to an example of a frequency (50 (Hz) to 150 (Hz)) at which engine vibration noise should be actively controlled.
- FIG. 4 is a diagram for explaining a specific example of the deviation of the sound pressure distribution.
- the frequency of the control sound of the speakers 10L and 10R is fixed to a frequency (108 (Hz)) at which a large phase shift occurs as shown in FIG.
- the filter coefficient used in the adaptive notch filter is repeatedly updated based on the LMS (Least Mean Square) algorithm so that the error signal is minimized at the microphone point.
- the control signal processed with the updated filter coefficient is output to the speakers 10L and 10R. Therefore, when the engine noise that reaches the microphone from the front of the passenger compartment is to be silenced, if there is a phase difference between the speakers 10L and 10R, the acoustic distance of the control sound is made equal by the phase difference. Tend to work.
- the active vibration noise control apparatus appropriately controls the level of the control sound between the speakers 10L and 10R so as to appropriately suppress the generation of the non-uniform noise reduction area and secure a wide noise reduction area.
- the time timing of the sine wave output between the speakers 10L and 10R is adaptively limited.
- the phase difference of the control sound between the speakers 10L and 10R is limited by limiting the filter coefficient used in the adaptive notch filter.
- a filter coefficient used when generating the control signal of the speaker 10L hereinafter referred to as “first filter coefficient”
- first filter coefficient a filter coefficient used when generating the control signal of the speaker 10L
- second filter coefficient An angle formed by a coefficient (hereinafter referred to as “second filter coefficient”) on a two-dimensional plane is limited. That is, the angle difference on the two-dimensional plane between the first filter coefficient and the second filter coefficient is limited to a predetermined angle.
- the first filter coefficient and the second filter coefficient are represented by a two-dimensional vector.
- FIG. 5 is a diagram for explaining the basic concept of the control method of the first embodiment.
- the active vibration noise control apparatus basically filters cosine waves (cos ( ⁇ )) and sine waves (sin ( ⁇ )) with adaptive notch filters 15L and 15R, respectively.
- a control signal is generated by adding the values, and a control sound is generated by outputting the control signal to the speakers 10L and 10R.
- the adaptive notch filter 15L performs processing using the first filter coefficient defined by “wL (1)” and “wL (2)”, and the adaptive notch filter 15R obtains “wR (1)”. Processing is performed with the second filter coefficient defined by “wR (2)”.
- a control sound (sine wave / cosine wave) having a phase difference is generated.
- a control sound as indicated by reference numeral 75 is generated from the speaker 10L
- a control sound as indicated by reference numeral 76 is generated from the speaker 10R.
- the active vibration noise control device includes an adaptive notch filter 15L, such that the phase difference between the control sound generated from the speaker 10L and the control sound generated from the speaker 10R is adaptively limited.
- the angle difference on the two-dimensional plane between the first filter coefficient and the second filter coefficient used in 15R is limited.
- the active vibration noise control apparatus performs processing so that the angle difference on the two-dimensional plane between the first filter coefficient and the second filter coefficient is within a predetermined angle.
- FIG. 6 shows a block diagram of the active vibration noise control apparatus 50 in the first embodiment.
- the active vibration noise control device 50 mainly includes two speakers 10L and 10R, two microphones 11L and 11R, a frequency detection unit 13, a cosine wave generation unit 14a, a sine wave generation unit 14b, and an adaptive notch.
- the filter 15, the reference signal generation unit 16, the w update unit 17, and the w limiter 18 are included.
- the active vibration noise control device 50 is basically a device that actively controls vibration noise generated from an engine using a pair of speakers 10L, 10R and two microphones 11L, 11R. is there. As shown in FIG. 1, the speakers 10L and 10R and the microphones 11L and 11R are installed on the front side of the vehicle interior of the vehicle 1 (for example, the speakers 10L and 10R are installed on the front door).
- the frequency detector 13 receives the engine pulse and detects the frequency ⁇ 0 of the engine pulse. Then, the frequency detector 13 outputs a signal corresponding to the frequency ⁇ 0 to the cosine wave generator 14a and the sine wave generator 14b.
- the cosine wave generator 14a and the sine wave generator 14b generate a reference cosine wave x 0 (n) and a reference sine wave x 1 (n) having the frequency ⁇ 0 detected by the frequency detector 13, respectively.
- the reference cosine wave x 0 (n) and the reference sine wave x 1 (n) as represented by the expression (1) are generated.
- N is a natural number and corresponds to a time (time point) (hereinafter the same).
- A indicates the amplitude
- ⁇ indicates the initial phase.
- the cosine wave generation unit 14a and the sine wave generation unit 14b convert the reference signal corresponding to the generated reference cosine wave x 0 (n) and the reference sine wave x 1 (n) to the adaptive notch filter 15 and the reference signal, respectively. Output to the generator 16.
- the cosine wave generation unit 14a and the sine wave generation unit 14b function as reference signal generation means.
- the adaptive notch filter 15 performs filtering on the reference cosine wave x 0 (n) and the reference sine wave x 1 (n).
- the adaptive notch filter 15L for generating a control signal to be output to the speaker 10L (hereinafter referred to as “first control signal”) is “w 110 ” with respect to the reference cosine wave x 0 (n). + W 210 ”and“ w 111 + w 211 ”for the reference sine wave x 1 (n).
- the two values obtained by multiplication in this way are added and output to the speaker 10L as the first control signal y 1 (n).
- the first filter coefficient is a two-dimensional vector defined by “w 110 + w 210 ” and “w 111 + w 211 ”.
- the adaptive notch filter 15R for generating a control signal to be output to the speaker 10R (hereinafter referred to as “second control signal”) is “w 120 + w 220 ” with respect to the reference cosine wave x 0 (n). And the reference sine wave x 1 (n) is multiplied by “w 121 + w 221 ”. The two values obtained by multiplication in this way are added and output to the speaker 10R as the second control signal y 2 (n).
- These “w 120 + w 220 ” and “w 121 + w 221 ” are updated by the w update unit 17 described later and supplied via the w limiter 18.
- the second filter coefficient described above is a two-dimensional vector defined by “w 120 + w 220 ” and “w 121 + w 221 ”.
- filter coefficient w when the first filter coefficient and the second filter coefficient are used without being distinguished from each other, or when they are used together, they are expressed as “filter coefficient w”.
- the first control signal y 1 (n) and the second control signal y 2 (n) are obtained by an arithmetic expression shown in Expression (2).
- the speakers 10L and 10R generate control sounds corresponding to the input first control signal y 1 (n) and second control signal y 2 (n), respectively.
- the control sound thus generated is transmitted according to a predetermined transfer function in the sound field from the speakers 10L, 10R to the microphones 11L, 11R.
- the transfer function from the speaker 10L to the microphone 11L is represented by “p 11 ”
- the transfer function from the speaker 10L to the microphone 11R is represented by “p 21 ”
- the transfer function from the speaker 10R to the microphone 11L Is represented by “p 12 ”
- the transfer function from the speaker 10R to the microphone 11R is represented by “p 22 ”.
- these transfer functions p 11 , p 21 , p 12 , and p 22 are determined according to the distance from the speakers 10L and 10R to the microphones 11L and 11R, and the like.
- the microphones 11L and 11R detect canceling errors between the vibration noise of the engine and the control sounds generated from the speakers 10L and 10R, respectively, and use them as error signals e 1 (n) and e 2 (n), respectively. 17 output.
- the microphones 11L and 11R include a first control signal y 1 (n) and a second control signal y 2 (n), transfer functions p 11 , p 21 , p 12 and p 22 , and engine vibration. Based on the noises d 1 (n) and d 2 (n), error signals e 1 (n) and e 2 (n) are output.
- the reference signal generator 16 generates a reference signal from the standard cosine wave x 0 (n) and the standard sine wave x 1 (n) based on the transfer functions p 11 , p 21 , p 12 , and p 22 described above.
- the reference signal is output to the w update unit 17.
- the part C 120 and the imaginary part C 121 and the real part C 220 and the imaginary part C 221 of the transfer function p 22 are used.
- the reference signal generator 16 multiplies the standard cosine wave x 0 (n) by the real part C 110 of the transfer function p 11 and the transfer function p for the reference sine wave x 1 (n). 11 and the value obtained by multiplying the imaginary part C 111 and outputs the added value as the reference signal r 110 (n) of the reference signal r 110 (n) "[pi / 2" by delaying the signal a reference signal r 111 (n) is output.
- the reference signal generation unit 16 outputs the reference signals r 210 (n), r 211 (n), r 120 (n), r 121 (n), r 220 (n), r 221 (n). Output.
- the reference signal generator 16 functions as a reference signal generator.
- the w updating unit 17 updates the filter coefficient w used in the adaptive notch filter 15 based on the LMS algorithm, and outputs the updated filter coefficient w to the w limiter 18.
- the w update unit 17 includes the error signals e 1 (n) and e 2 (n) and the reference signals r 110 (n), r 111 (n), r 210 (n), and r 211. Based on (n), r 120 (n), r 121 (n), r 220 (n), r 221 (n), the error signals e 1 (n), e 2 (n) are minimized.
- the adaptive notch filter 15 updates the filter coefficient w used last time.
- the w updating unit 17 determines a predetermined constant, error signals e 1 (n) and e 2 (n), and reference signals r 110 (n), r 111 (n) r 210 (n), and r 211 (n ), R 120 (n), r 121 (n), r 220 (n), r 221 (n), and the value obtained by subtracting the previously used filter coefficient w from Is output as a simple filter coefficient w.
- the updated filter coefficient w is obtained by an arithmetic expression represented by Expression (3).
- the updated filter coefficient w is expressed as “w lm0 (n + 1), w lm1 (n + 1)”, and the pre-updated filter coefficient w is “w lm0 (n), w lm1 (n)”. It is written.
- the above-described w 110 , w 111 , w 120 , w 121 , w 210 , w 211 , w 220 , and w 221 are obtained.
- the w updating unit 17 outputs “w 110 + w 210 ”, “w 111 + w 211 ”, “w 120 + w 220 ”, and “w 121 + w 221 ” to the w limiter 18 as new filter coefficients w.
- the w update unit 17 functions as a filter coefficient update unit.
- the w limiter 18 performs a process of limiting the filter coefficient w updated by the w update unit 17.
- the w limiter 18 includes a first filter coefficient (a two-dimensional vector defined by “w 110 + w 210 ” and “w 111 + w 211 ”) and a second filter coefficient (“w 120 + w 220 ”).
- a process of limiting an angle difference on a two-dimensional plane with a two-dimensional vector defined by “w 121 + w 221 ” is performed.
- the w limiter 18 outputs the filter coefficient w after such restriction to the adaptive notch filter 15.
- the w limiter 18 functions as a phase difference limiting unit.
- FIG. 7A is a schematic diagram illustrating processing blocks of the w update unit 17 and the w limiter 18.
- the first filter coefficient and the second filter coefficient before being updated by the w updating unit 17 are expressed as “w_sp1” and “w_sp2”, respectively, and the first filter coefficient after being updated by the w updating unit 17 and
- the second filter coefficients are denoted as “w_sp1 ′” and “w_sp2 ′”, respectively.
- the w updating unit 17 generates the first filter coefficient w_sp1 used when generating the first control signal for the speaker 10L and the second control signal for the speaker 10R based on the LMS algorithm.
- the second filter coefficient w_sp2 used in is updated.
- the w updating unit 17 outputs the updated first filter coefficient w_sp1 'and second filter coefficient w_sp2' to the w limiter 18.
- the w limiter 18 is finally based on the first filter coefficient w_sp1 ′ and the second filter coefficient w_sp2 ′ updated by the w updating unit 17, and the first filter coefficient w_sp1 and the second filter coefficient w_sp2 before the update.
- the first filter coefficient w_sp1_out and the second filter coefficient w_sp2_out for use in the adaptive notch filters 15L and 15R are output.
- FIG. 7B is a diagram for specifically explaining the processing performed by the w limiter 18.
- the horizontal axis represents the real axis
- the vertical axis represents the imaginary axis.
- the first filter coefficients w_sp1 and w_sp1 ′ and the second filter coefficients w_sp2 and w_sp2 ′ are represented by two-dimensional vectors defined by the real part and the imaginary part. ).
- the angle difference on the two-dimensional plane between the first filter coefficient w_sp1 and the second filter coefficient w_sp2 before the update is defined as “ ⁇ ”, and the first filter coefficient w_sp1 ′ after the update and the second filter are updated.
- the angle difference on the two-dimensional plane with the coefficient w_sp2 ′ is defined as “ ⁇ ′”.
- the w limiter 18 indicates that the angle difference between the first filter coefficient w_sp1_out and the second filter coefficient w_sp2_out finally used in the adaptive notch filter 15 is a predetermined angle (hereinafter referred to as “limit angle ⁇ ”).
- the limit angle ⁇ is set based on a range in which the sound pressure distribution generated by the speakers 10L and 10R is not biased. For example, the limit angle ⁇ is obtained in advance for each vehicle by an experiment or a predetermined arithmetic expression. As an example, the limit angle ⁇ is set to “30 (degrees)” in FIG. 4 where the sound pressure distribution is uniform.
- the w limiter 18 when the angle difference ⁇ ′ between the first filter coefficient w_sp1 ′ and the second filter coefficient w_sp2 ′ updated by the w updating unit 17 exceeds the limit angle ⁇ , the w limiter 18 The filter coefficient w_sp1 and the second filter coefficient w_sp2 are output as the first filter coefficient w_sp1_out and the second filter coefficient w_sp2_out. That is, the w limiter 18 does not update the filter coefficient used in the adaptive notch filter 15. In other words, the filter coefficient used last time in the adaptive notch filter 15 is used again.
- the w limiter 18 uses the updated first filter coefficient w_sp1 ′ and second filter coefficient w_sp2 ′ as the first filter coefficient w_sp1_out and the first filter coefficient w_sp1_out. It outputs as 2 filter coefficient w_sp2_out. That is, the w limiter 18 updates the filter coefficient used in the adaptive notch filter 15.
- the w limiter 18 is configured such that the norm of the first filter coefficient w_sp1 ′ is “0” (that is, “
- 0”), or the norm of the second filter coefficient w_sp2 ′ is “0”.
- the updated first filter coefficient w_sp1 ′ and second filter coefficient w_sp2 ′ are used as the first filter coefficient w_sp1_out and the second filter coefficient w_sp2_out. Output.
- the angle difference between the first filter coefficient w_sp1 'and the second filter coefficient w_sp2' cannot be defined.
- the w limiter 18 is limited to determining which of the updated first filter coefficient w_sp1 ′ and second filter coefficient w_sp2 ′ and the first filter coefficient w_sp1 and second filter coefficient w_sp2 before update are to be output. Not done. In another example, such a determination can be made based on “X” defined by the following Expression (4) and “Y” defined by Expression (5). In Expression (4), “
- the w limiter 18 uses the updated first filter coefficient w_sp1 ′ and second filter coefficient w_sp2 ′ as the first filter coefficient w_sp1_out. And the second filter coefficient w_sp2_out.
- the w limiter 18 uses the first filter coefficient w_sp1_out and the first filter coefficient w_sp1 and the second filter coefficient w_sp2 before the update. It outputs as 2nd filter coefficient w_sp2_out.
- the determination is based on the angle difference ⁇ ′ and the norms of the first filter coefficient w_sp1 ′ and the second filter coefficient w_sp2 ′. In comparison, it is possible to make a simple determination.
- FIG. 8 is a flowchart showing the processing performed by the w limiter 18.
- step S101 the w limiter 18 includes the first filter coefficient w_sp1 and the second filter coefficient w_sp2 before being updated by the w updating unit 17, and the first filter coefficient w_sp1 ′ after being updated by the w updating unit 17. And the second filter coefficient w_sp2 ′. Then, the process proceeds to step S102.
- step S102 the w limiter 18 obtains “X” in accordance with the above equation (4) based on the value acquired in step S101. Then, the process proceeds to step S103. In step S103, the w limiter 18 obtains “Y” according to the above equation (5) based on the value acquired in step S101. Then, the process proceeds to step S104.
- step S104 the w limiter 18 uses the “X” and “Y” obtained in steps S102 and S103 to determine whether the first condition is satisfied or whether the second condition is satisfied. I do.
- the w limiter 18 basically basically limits the angle difference between the first filter coefficient w_sp1_out and the second filter coefficient w_sp2_out used finally in the adaptive notch filter 15 within the limit angle ⁇ .
- the w updating unit 17 determines whether or not the angle difference ⁇ ′ between the updated first filter coefficient w_sp1 ′ and the second filter coefficient w_sp2 ′ is within the limit angle ⁇ .
- step S104 If the first condition is satisfied or the second condition is satisfied (step S104; Yes), the process proceeds to step S105.
- the w limiter 18 outputs the updated first filter coefficient w_sp1 'and second filter coefficient w_sp2' as the first filter coefficient w_sp1_out and the second filter coefficient w_sp2_out. Then, the process ends.
- step S104 when the first condition is not satisfied and the second condition is not satisfied (step S104; No), the process proceeds to step S106.
- the w limiter 18 outputs the first filter coefficient w_sp1 and the second filter coefficient w_sp2 before the update as the first filter coefficient w_sp1_out and the second filter coefficient w_sp2_out. Then, the process ends.
- the speakers 10L and 10R and the microphones 11L and 11R are arranged in the vehicle interior, and control sounds are generated from the speakers 10L and 10R in order to actively control the vibration noise of the engine.
- the sound pressure distribution in other words, area muting volume
- the frequency of the control sound in the speakers 10L and 10R is fixed to a frequency (108 (Hz)) at which a large phase shift occurs as shown in FIG.
- results obtained from a conventional active vibration noise control apparatus are used.
- the conventional active vibration noise control device does not limit the filter coefficient w by the w limiter 18 unlike the active vibration noise control device 50.
- FIG. 9A shows an example of a result obtained by a conventional active vibration noise control apparatus.
- the input signals (corresponding to y 1 (n) and y 2 (n)) of the speakers 10L and 10R are shown on the left side, and the area silence level (dB) in the passenger compartment is shown on the right side. Show. From this, it can be seen that in the conventional active vibration and noise control device, as shown by the broken line area 78, the sound is increased at the left rear seat, and a non-uniform noise reduction area is generated. This is due to the reason described above. That is, because the LMS tries to correct the phase difference at the front seat as shown in FIG. 3, the sound pressure distribution of the control signal is biased at the rear seat as shown in FIG.
- the amplitude of the input signal of speaker 10L, 10R is comparatively large. This is considered to be because the error acquired by the microphone does not decrease due to the occurrence of an area as indicated by the broken line region 78, and the amplitude of the filter coefficient continues to increase.
- FIG. 9B shows an example of a result obtained by the active vibration noise control device 50 in the first embodiment.
- input signals corresponding to y 1 (n) and y 2 (n)
- the area silence level (dB) in the passenger compartment is shown on the right side. Show. From this, it can be seen that in the active vibration noise control device 50 in the first embodiment, a uniform and wide range of noise reduction area is secured. Specifically, it can be seen that the generation of a non-uniform sound-muffling area as indicated by the broken line area 78 in FIG. 9A is suppressed.
- the amplitudes of the input signals of the speakers 10L and 10R are smaller than the amplitude of the input signals by the conventional active vibration noise control device. This is presumably because the active vibration noise control apparatus 50 in the first embodiment limits the update of the filter coefficient w by the w limiter 18.
- the active vibration noise control device 50 in the first embodiment it is possible to appropriately secure a uniform and wide range of muffled areas with a relatively low volume control sound. Therefore, it is possible to secure a wide silencing area with a relatively small number of microphones.
- the level of the control sound between the speakers 10L and 10R is directly limited by directly limiting the phase difference between the first control signal output to the speaker 10L and the second control signal output to the speaker 10R.
- the phase difference is limited.
- the phase difference between the first control signal and the second control signal is limited within a predetermined value.
- FIG. 10 is a block diagram showing the configuration of the active vibration noise control device 51 in the second embodiment.
- the active vibration noise control device 51 is different from the active vibration noise control device 50 (see FIG. 6) in that it includes a phase difference limiting unit 20 instead of the w limiter 18.
- symbol is attached
- the phase difference limiting unit 20 includes a buffer and the like, and receives the first control signal y 1 (n) and the second control signal y 2 (n) after being processed by the adaptive notch filter 15, Processing for limiting the phase difference between the first control signal y 1 (n) and the second control signal y 2 (n) is performed. Specifically, the phase difference limiting unit 20 performs a process of limiting the phase difference between the first control signal y 1 (n) and the second control signal y 2 (n) within a predetermined value. For example, when the phase difference exceeds a predetermined value, the phase difference limiting unit 20 selects the control signal whose phase is advanced among the first control signal y 1 (n) and the second control signal y 2 (n).
- phase difference limiting unit 20 outputs the first control signal y 1 ′ (n) and the second control signal y 2 ′ (n) after such processing to the speakers 10L and 10R, respectively.
- the phase difference limiting unit 20 functions as a phase difference limiting unit.
- FIG. 11 is a flowchart showing processing performed by the phase difference limiting unit 20.
- the phase of the first control signal y 1 (n) is behind the phase of the second control signal y 2 (n) (in other words, the phase of the second control signal y 2 (n) is Take the case where the first control signal y 1 (n) is ahead of the phase).
- step S201 the phase difference limiting unit 20 acquires the first control signal y 1 (n) and the second control signal y 2 (n). Then, the process proceeds to step S202.
- step S202 the phase difference limiting unit 20 stores the first control signal y 1 (n) and the second control signal y 2 (n) acquired in step S201 in the ring buffer. Specifically, the phase difference limiting unit 20 stores the first control signal y 1 (n) in the buffer Buf1, and stores the second control signal y 2 (n) in the buffer Buf2. For example, the phase difference limiting unit 20 stores data of about one wavelength in the sine wave in the buffers Buf1 and Buf2. This is because the phase difference is obtained using the shape of a sine wave. Then, the process proceeds to step S203.
- step S203 the phase difference limiting unit 20 calculates the phase difference ⁇ in the first control signal y 1 (n) and the second control signal y 2 (n) based on the data stored in the buffers Buf1 and Buf2. . Specifically, the phase difference limiting unit 20 calculates the phase difference ⁇ by calculating the correlation value of the data stored in the buffers Buf1 and Buf2 (for example, calculating the inner product). In this case, the phase difference limiting unit 20 obtains the correlation value while shifting the time in the data stored in the buffers Buf1 and Buf2, and adopts the time when the peak value is obtained for the correlation value as the phase difference ⁇ . Then, the process proceeds to step S204.
- step S204 the phase difference limiting unit 20 determines whether or not the phase difference ⁇ obtained in step S203 is equal to or less than a predetermined value ⁇ .
- the predetermined value ⁇ used in this determination is set based on a range in which the sound pressure distribution generated by the speakers 10L and 10R is not biased. For example, the predetermined value ⁇ is obtained in advance for each vehicle by an experiment, a predetermined arithmetic expression, or the like.
- step S204 When the phase difference ⁇ is equal to or smaller than the predetermined value ⁇ (step S204; Yes), the process proceeds to step S205.
- step S205 the phase difference limiting unit 20 does not need to limit the phase difference between the first control signal y 1 (n) and the second control signal y 2 (n), so the original first control signal y 1 (N) and the second control signal y 2 (n) are output as the first control signal y 1 ′ (n) and the second control signal y 2 ′ (n). Then, the process ends.
- step S206 the phase difference limiting unit 20 performs a process for limiting the phase difference between the first control signal y 1 (n) and the second control signal y 2 (n). Specifically, the phase difference limiting unit 20 delays the second control signal y 2 (n) whose phase is advanced by an amount “ ⁇ ” corresponding to the difference between the phase difference ⁇ and the predetermined value ⁇ . Process. Then, the phase difference limiting unit 20 outputs the original first control signal y 1 (n) as the first control signal y 1 ′ (n) and the second control signal y delayed by “ ⁇ ”.
- phase difference limiting unit 20 delays it by “ ⁇ ”.
- the first control signal y 1 (n) is output as the first control signal y 1 ′ (n).
- the control signal whose phase is advanced among the first control signal y 1 (n) and the second control signal y 2 (n) is expressed as “
- the control signal whose phase is delayed among the first control signal y 1 (n) and the second control signal y 2 (n) is“ ⁇ You may advance by “- ⁇ ”.
- an active vibration noise control apparatus is configured using two pairs of speakers
- the present invention is not limited to this.
- an active vibration and noise control apparatus can be configured by using two or more pairs of speakers. That is, for example, an active vibration noise control apparatus can be configured using a total of four speakers, a total of six speakers, and the like.
- the control signal may be generated by a method as described above for each set of speakers.
- an active vibration noise control apparatus is configured using two microphones.
- the present invention is not limited to this, and active vibration noise control is performed using one microphone or three or more microphones.
- An apparatus may be configured.
- the present invention is applied to a closed space such as a room of a moving body having a vibration noise source such as an engine and can be used to actively control vibration noise.
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Abstract
Description
まず、本発明の基本概念について説明する。以下の説明では、図1に示すように、2つのスピーカ10L、10Rと、2つのマイク11L、11Rとを有し、車両1に搭載される能動型振動騒音制御装置を例に挙げる。図示のように、スピーカ10L、10R及びマイク11L、11Rは、車室内のフロント側に設置される。例えば、スピーカ10L、10Rはフロントドアに設置される。また、スピーカ10L、10Rは、2つ1組に構成されている。
第1実施例では、適応ノッチフィルタにおいて用いられるフィルタ係数に対する制限を行うことで、スピーカ10L、10R間の制御音の位相差を制限する。具体的には、第1実施例では、スピーカ10Lの制御信号を生成する際に用いるフィルタ係数(以下、「第1フィルタ係数」と呼ぶ。)とスピーカ10Rの制御信号を生成する際に用いるフィルタ係数(以下、「第2フィルタ係数」と呼ぶ。)とが2次元平面上でなす角を制限する。つまり、第1フィルタ係数と第2フィルタ係数との2次元平面上での角度差を、所定角以内に制限する。なお、第1フィルタ係数及び第2フィルタ係数は2次元のベクトルで表されるものとする。
Y=<w_sp1’,w_sp2’> 式(5)
このような「X」及び「Y」を用いた場合、wリミッタ18は、「X2≠0」且つ「Y≧0」且つ「Y2≧X2・(cosα)2」であるか否か(以下、このような条件を「第1条件」と呼ぶ)、又は「X2=0」であるか否か(以下、このような条件を「第2条件」と呼ぶ)、を判定することで、第1フィルタ係数w_sp1’及び第2フィルタ係数w_sp2’と、第1フィルタ係数w_sp1及び第2フィルタ係数w_sp2とのいずれを出力するかを判定することができる。
次に、第2実施例について説明する。第2実施例では、スピーカ10Lへ出力される第1制御信号とスピーカ10Rへ出力される第2制御信号との位相差を直接的に制限することで、スピーカ10L、10R間の制御音の位相差を制限する点で、第1実施例と異なる。具体的には、第2実施例では、第1制御信号と第2制御信号との位相差を所定値以内に制限する。
上記では、2つ1組のスピーカを用いて能動型振動騒音制御装置を構成する例を示したが、これに限定はされない。他の例では、2つ1組のスピーカを2以上用いて能動型振動騒音制御装置を構成することができる。つまり、例えば計4つのスピーカや計6つのスピーカなどを用いて、能動型振動騒音制御装置を構成することができる。この場合には、1組のスピーカ単位で、前述したような方法により制御信号を生成すれば良い。
11L、11R マイク
13 周波数検出部
14a 余弦波発生部
14b 正弦波発生部
15 適応ノッチフィルタ
16 参照信号生成部
17 w更新部
18 wリミッタ
20 位相差制限部
50、51 能動型振動騒音制御装置
Claims (7)
- 2つ1組のスピーカを有し、前記スピーカから制御音を発生させる能動型振動騒音制御装置であって、
振動騒音源から発生する振動騒音周波数に基づいて、基準信号を生成する基準信号生成手段と、
前記振動騒音源からの発生振動騒音が相殺されるように前記スピーカから前記制御音を発生させるべく、前記基準信号に対して第1フィルタ係数を用いることで、前記スピーカの一方へ出力する第1制御信号を生成すると共に、前記基準信号に対して第2フィルタ係数を用いることで、前記スピーカの他方に対して出力する第2制御信号を生成する適応ノッチフィルタと、
前記振動騒音と前記制御音との相殺誤差を検出して、誤差信号として出力するマイクと、
前記スピーカから前記マイクまでの伝達関数に基づいて、前記基準信号から参照信号を生成する参照信号生成手段と、
前記誤差信号及び前記参照信号に基づいて、前記誤差信号が最小となるように、前記適応ノッチフィルタで用いられる前記第1フィルタ係数及び前記第2フィルタ係数を更新するフィルタ係数更新手段と、
前記スピーカの一方から発生される制御音と前記スピーカの他方から発生される制御音との位相差を制限する位相差制限手段と、を備えることを特徴とする能動型振動騒音制御装置。 - 前記位相差制限手段は、前記スピーカからの前記制御音によって生成される音圧分布が均一になるように、前記位相差を制限することを特徴とする請求項1に記載の能動型振動騒音制御装置。
- 前記位相差制限手段は、前記フィルタ係数更新手段によって更新された前記第1フィルタ係数と前記第2フィルタ係数との2次元平面上での角度差を、所定角以内に制限することで、前記スピーカの一方から発生される制御音と前記スピーカの他方から発生される制御音との位相差を制限することを特徴とする請求項1又は2に記載の能動型振動騒音制御装置。
- 前記位相差制限手段は、前記角度差が前記所定角を越える場合、前記フィルタ係数更新手段によって更新される前の前記第1フィルタ係数及び前記第2フィルタ係数を、前記適応ノッチフィルタに対して出力することを特徴とする請求項3に記載の能動型振動騒音制御装置。
- 前記位相差制限手段は、前記適応ノッチフィルタによって生成された前記第1制御信号と前記第2制御信号との位相差を所定値以内に制限することで、前記スピーカの一方から発生される制御音と前記スピーカの他方から発生される制御音との位相差を制限することを特徴とする請求項1又は2に記載の能動型振動騒音制御装置。
- 前記位相差制限手段は、前記位相差が前記所定値を超える場合、前記第1制御信号及び前記第2制御信号のうち位相が進んでいるほうの制御信号を、前記位相差と前記所定値との差分に相当する量だけ遅延させることを特徴とする請求項5に記載の能動型振動騒音制御装置。
- 前記スピーカは、前記振動騒音源の近傍に配置されることを特徴とする請求項1乃至6のいずれか一項に記載の能動型振動騒音制御装置。
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JP5503023B2 (ja) * | 2011-01-06 | 2014-05-28 | パイオニア株式会社 | 能動型振動騒音制御装置、能動型振動騒音制御方法及び能動型振動騒音制御プログラム |
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JP2017521730A (ja) * | 2014-08-01 | 2017-08-03 | ボーズ・コーポレーションBose Corporation | 雑音減衰のためのマイクロホン配置のシステムおよび方法 |
JP2018518715A (ja) * | 2015-06-25 | 2018-07-12 | ボーズ・コーポレーションBose Corporation | 均一なドライバ場のためにスピーカを配列する雑音消去システム |
JP2018524633A (ja) * | 2015-06-25 | 2018-08-30 | ボーズ・コーポレーションBose Corporation | 能動雑音低減のための配列スピーカ構成と同相スピーカ構成との間の移行 |
Also Published As
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JP5189679B2 (ja) | 2013-04-24 |
EP2420411A1 (en) | 2012-02-22 |
EP2420411B1 (en) | 2020-03-11 |
US8891781B2 (en) | 2014-11-18 |
US20120033821A1 (en) | 2012-02-09 |
CN102387942A (zh) | 2012-03-21 |
JPWO2010119528A1 (ja) | 2012-10-22 |
EP2420411A4 (en) | 2017-05-03 |
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