1. Field of the Invention
The present invention relates to an active noise control system for canceling out unwanted noise in a vehicle's passenger compartment with secondary noise produced out of phase with the unwanted noise (having 180°-shifted phase with respect to the phase of the unwanted noise in the passenger compartment), and more particularly to an active noise control system for canceling out unwanted noise in a closed space such as a vehicle's passenger compartment based on low-frequency road noise (also referred to as “drumming noise”) in frequencies ranging from 20 to 150 Hz which is produced due to the acoustic resonant characteristics of the closed space.
2. Description of the Related Art
Active noise control systems for attenuating drumming noise in a vehicle's passenger compartment have been based on feed-forward active control as shown in
In
The adaptive digital filter 21, the digital filter 22, and the filter coefficient updating circuit 23 jointly make up a control means for being supplied with a signal highly correlated to a sound from a noise source as a reference signal and generating a noise canceling signal which is exactly out of phase to the noise in the passenger compartment 24. The speaker 25 serves as a canceling sound generating means for generating a noise canceling sound in response to the noise canceling signal outputted from the control means.
When the speaker 25 generates and radiates the noise canceling sound as secondary noise, the radiated secondary noise cancels out the noise in the passenger compartment 24 for thereby suppressing the noise in the passenger compartment 24.
Efforts have also been made to adjust the weight of a certain region of the vehicle body for attenuating noise generated in the passenger compartment by drumming noise.
With the conventional active noise control system, it is necessary to use a microphone for confirming noise cancellation in the passenger compartment and also a reference signal that is highly correlated to the noise in the passenger compartment and satisfies the causality.
For suppressing the noise in the passenger compartment based on low-frequency road noise, it is also necessary to obtain a reference signal that is highly correlated to the noise in the passenger compartment and satisfies the causality. However, it is very difficult to produce such a reference signal.
The difficulty arises out of the fact that the noise in the passenger compartment based on low-frequency road noise is affected more greatly by the acoustic resonant characteristics of the sound field in the vehicle body than by vibrational characteristics of the suspensions and various vehicle body regions.
Japanese laid-open patent publication No. 5-273987 discloses a conventional active noise control system having a microphone for confirming noise cancellation which is mounted on a side of the headrest of a front seat in a passenger compartment. The microphone detects noise in the vicinity of the ears of a passenger seated on the front seat to cancel noise in the passenger compartment. In the disclosed conventional active noise control system, the understanding of transfer characteristics with respect to sounds in the passenger compartment, particularly transfer functions between a speaker as a secondary noise source and the microphone for confirming noise cancellation, has an important effect on the noise cancellation capability of the system.
However, since the front seat with the microphone mounted on the side of the headrest thereof is adjustable in position, when the front seat is moved forward or backward, the position of the microphone is changed in the passenger compartment. When the microphone is changed in position, the relative position between the speaker and the microphone is also changed. As a result, the transfer function between the speaker and the microphone is varied, and the noise in the passenger compartment cannot sufficiently be attenuated.
The above problem also occurs when the angle of the backrest of the front seat is changed.
The approach to adjust the weight of a certain region of the vehicle body for attenuating drumming noise is disadvantageous in that it has to rely upon a process of trial and error and hence is tedious and time-consuming, and the attempt usually brings about an increase in the weight of the vehicle body region.
It is a primary object of the present invention to provide an active noise control system which is capable of canceling out noise in a vehicle's passenger compartment based on low-frequency road noise.
Another object of the present invention is to provide an active noise control system which is capable of easily obtaining a reference signal.
Still another object of the present invention is to provide an active noise control system which is capable of reliably obtaining a noise cancellation confirming signal.
Yet another object of the present invention is to provide an active noise control system which is capable of easily obtaining a detected noise signal.
The above and other objects, features, and advantages of the present invention will become more apparent from the following description when taken in conjunction with the accompanying drawings in which preferred embodiments of the present invention are shown by way of illustrative example.
Like or corresponding parts are denoted by like or corresponding reference characters throughout views.
As shown in
Microphones 40, 41, 42 as sensors for generating reference signals are positioned respectively near the base of the front seat 31A or 31B, near the center of a roof 34, and within a trunk compartment 35, i.e., respectively at vibrational antinodes of an acoustic normal mode of the passenger compartment 24.
As shown in
The active noise controller 20A operates as follows: An output signal from the microphone 40 is supplied as a reference signal to an adaptive digital filter 21A and a digital filter 22A whose transfer characteristics are made equivalent to the sound field transfer characteristics of the passenger compartment 24. The digital filter 22A supplies its output signal to a filter coefficient updating circuit 23A which calculates filter coefficients of the adaptive digital filter 21A based on an LMS algorithm. The filter coefficients calculated by the filter coefficient updating circuit 23A are set in the adaptive digital filter 21A. An output signal from the adaptive digital filter 21A and output signals from adaptive digital filters 21B, 21C (described later on) are added to each other by an adder 27. The adder 27 applies a sum signal to drive the speaker 25 placed in the passenger compartment 24 which serves as a sound field. The difference between a sound radiation outputted from the speaker 25 and noise in the passenger compartment 24 is detected by the microphone 26 which is provided in the passenger compartment 24 for confirming noise cancellation. An output signal from the microphone 26 is sent as an error signal to the filter coefficient updating circuit 23A, which calculates filter coefficients in order to eliminate the square of the error signal.
The active noise controller 20B comprises an adaptive digital filter 21B and a digital filter 22B which are supplied with an output signal from the microphone 41 as a reference signal, and a filter coefficient updating circuit 23B. Similarly, the active noise controller 20C comprises an adaptive digital filter 21C and a digital filter 22C which are supplied with an output signal from the microphone 42 as a reference signal, and a filter coefficient updating circuit 23C.
The noise in the passenger compartment 24 is canceled out by an output signal from the active noise control system, i.e., the sound radiation outputted from the speaker 25 based on the sum signal outputted from the adder 27. The digital filters 22B, 22C have transfer characteristics that are made equivalent to the sound field transfer characteristics of the passenger compartment 24.
The microphones 40, 41, 42 are positioned respectively near the base of the front seat 31A or 31B, near the center of the roof 34, and within the trunk compartment 35, i.e., respectively at vibrational antinodes of the acoustic normal mode of the passenger compartment 24, for the following reasons:
An analysis of a cavity resonant mode in the passenger compartment 24 including the trunk compartment 35 according to the finite element method indicates that an acoustic normal mode of the passenger compartment 24 at low frequencies comprises a primary mode in the longitudinal direction of the vehicle at a frequency of about 40 Hz, as shown in
Similarly,
In
A comparison between
Since the noise produced in the passenger compartment 24 based on road noise is strongly affected by the acoustic normal mode of the passenger compartment 24, coherence between the noise in the passenger compartment 24 and the error signal is high. Because the noise in the passenger compartment 24 is large, it is easy to detect a reference signal having the frequency the noise of which is to be muffled.
Though the road noise is highly random noise, inasmuch as the noise produced in the passenger compartment 24 based on road noise is strongly affected by the acoustic normal mode of the passenger compartment 24, the noise in the passenger compartment 24 is periodic, and it is not necessary to pay much attention to the causality as is the case with active noise control for periodic noise.
By positioning the microphones 40, 41, 42 respectively at vibrational antinodes of the acoustic normal mode of the passenger compartment 24 and using their output signals as reference signals, the active noise control system is capable of canceling out noise in the passenger compartment 24 based on low-frequency road noise.
Specifically, in the active noise control system according to the first embodiment, the microphones 40, 41, 42 are positioned in the passenger compartment 24 at vibrational antinodes of the primary or secondary acoustic normal mode of the passenger compartment 24. The microphones 40, 41, 42 produce respective output signals as reference signals when they detect noise at 40 Hz or 80 Hz in the passenger compartment 24, and the noise is suppressed on the basis of the reference signals. As a result, the noise at the positions of the microphones 40, 41, 42 is attenuated. Accordingly, the active noise control system is capable of suppressing not only the noise at the positions of the microphones 40, 41, 42, but also noise in a low frequency range including drumming noise in the entire passenger compartment 24.
The noise at 40 Hz and the noise 80 Hz behaves as a standing wave in the passenger compartment 24. The active noise control system according to the first embodiment operates to change the standing wave in the passenger compartment 24 in order to lower the sound pressures of the antinodes of the standing wave where the microphones 40, 41, 42 are located. In some cases, the active noise control system can cancel out the standing wave in order to suppress the noise in the entire passenger compartment 24.
As described above, in order to cancel out noise in the passenger compartment based on road noise, it is effective to position the microphones 40, 41, 42 respectively near the base of the front seat 31A or 31B, near the center of the roof 34, and within the trunk compartment 35, as shown in
As shown in
The active noise control system according to the first embodiment as described above has three microphones for generating reference signals. However, the active noise control system may have only one microphone positioned in either one of the regions indicated by the dot-and-dash lines and the region indicated by the two-dot-and-dash line. The modified active noise control system is advantageous in that it has a smaller number of microphones.
In
Therefore, the principles of the present invention are applicable to vehicles of different shapes, irrespective whether they are sedans or station wagons.
As described above, the active noise control system according to the first embodiment has microphones located at respective antinodes of the acoustic normal mode of the passenger compartment and uses output signals from the microphones as reference signals for providing a large noise cancellation effect in a desired frequency range.
The active noise control system according to the first embodiment is greatly reduced in cost because the microphones are much more inexpensive than conventional acceleration sensors for detecting vibrations whose output signals are used as reference signals.
An active noise control system according to a second embodiment of the present invention will be described below.
In the active noise control system according to the second embodiment, a speaker 25 as a secondary noise source which serves as a canceling sound generating means is mounted on a rear tray 33, for example, of the vehicle 10A, and microphones 43, 44 for confirming noise cancellation are positioned near respective left and right roof rails 30A, 30B of the vehicle 10A which confront the respective ears 38A, 38B of occupants who are seated on front seats.
As shown in
The installed position of the microphones 43, 44 will be described below with reference to
As shown in
The active noise control system which includes the microphones 43, 44 is shown in block form in
Similarly, the reference signal is applied to the adaptive digital filter 21B and the digital filter 22B whose transfer functions are made equivalent to the transfer functions between the speaker 25 and the microphone 44 with respect to noise in the passenger compartment 24. An output signal from the digital filter 22B is applied to the filter coefficient updating circuit 23B, and a detected noise signal produced by the microphone 44 is applied as an error signal to the filter coefficient updating circuit 23B. The filter coefficient updating circuit 23B calculates filter coefficients w1b, w2b, w3b, . . . , wib based on an LMS algorithm in order to substantially eliminate the square of the error signal. The calculated filter coefficients w1b, w2b, w3b, . . . , wib are set in the adaptive digital filter 21B.
An output signal from the adaptive digital filter 21A in which the calculated filter coefficients have been set and an output signal from the adaptive digital filter 21B in which the calculated filter coefficients have been set are supplied to the adder 21D and added to each other thereby. The adder 21D applies a sum signal to drive the speaker 25 for thereby attenuating noise at the microphones 43, 44.
The microphones 43, 44 are positioned respectively near the roof rails 30A, 30B which confront the ears 38A, 38B of the occupants who are seated on the front seats in the vehicle 10A for the following reasons:
Since the microphones 43, 44 for confirming noise cancellation are positioned respectively near the roof rails 30A, 30B which confront the ears 38A, 38B of the occupants who are seated on the front seats in the vehicle 10A, the microphones 43, 44 are fixed in their relative positions, and hence the speaker 25 and the microphones 43, 44 are also fixed in their relative positions. The transfer function between speaker 25 and the microphones 43, 44 with respect to noise in the passenger compartment 24 is not varied even when the front seats are changed in position.
The transfer characteristics with respect to noise in the passenger compartment from the speaker 25 to positions near the roof rails 30A, 30B which confront the ears 38A, 38B of the occupants who are seated on the front seats, and the transfer characteristics with respect to noise in the passenger compartment from the speaker 25 to positions near the ears 38A, 38B of the occupants who are seated on the front seats are indicated respectively by the solid- and broken-line curves in
Sound pressure levels of noise in the passenger compartment from the speaker 25 to positions near the roof rails 30A, 30B which confront the ears 38A, 38B of the occupants who are seated on the front seats while the vehicle 10A is running, and sound pressure levels of noise in the passenger compartment from the speaker 25 to positions near the ears 38A, 38B of the occupants who are seated on the front seats while the vehicle 10A is running are indicated respectively by the solid- and broken-line curves in
As described above, since the transfer characteristics with respect to noise in the passenger compartment from the speaker 25 to positions near the roof rails 30A, 30B which confront the ears 38A, 38B of the occupants who are seated on the front seats, and the transfer characteristics with respect to noise in the passenger compartment from the speaker 25 to positions near the ears 38A, 38B of the occupants who are seated on the front seats are in substantial agreement with each other, and the sound pressure levels of noise in the passenger compartment from the speaker 25 to positions near the roof rails 30A, 30B which confront the ears 38A, 38B of the occupants who are seated on the front seats, and the sound pressure level of noise in the passenger compartment from the speaker 25 to positions near the ears 38A, 38B of the occupants who are seated on the front seats are in substantial agreement with each other, the microphones 43, 44 are positioned respectively near the roof rails 30A, 30B which confront the ears 38A, 38B of the occupants who are seated on the front seats in the vehicle 10A.
An analysts of a cavity resonant mode in the passenger compartment 24 including the trunk compartment 35 according to the finite element method indicates that an acoustic normal mode of the passenger compartment 24 at low frequencies comprises a primary mode in the longitudinal direction of the vehicle at a frequency of about 40 Hz, as shown in
Similarly,
In
A comparison between
While low-frequency sounds in the passenger compartment undergo large sound pressure variations in the longitudinal direction of the passenger compartment 24, i.e., the direction in which the vehicle runs, they exhibit a relatively uniform sound pressure distribution in lateral and vertical directions of the passenger compartment 24. This is the basis for the reasons why the transfer characteristics with respect to noise in the passenger compartment from the speaker 25 to positions near the roof rails 30A, 30B which confront the ears 38A, 38B of the occupants who are seated on the front seats, and the transfer characteristics with respect to noise in the passenger compartment from the speaker 25 to positions near the ears 38A, 38B of the occupants who are seated on the front seats are in substantial agreement with each other at almost all frequencies, and there is no substantial difference between the sound pressure of sounds in the passenger compartment from the speaker 25 to positions near the roof rails 30A, 30B which confront the ears 38A, 38B of the occupants who are seated on the front seats while the vehicle is running, and the sound pressure of sounds in the passenger compartment from the speaker 25 to positions near the ears 38A, 38B of the occupants who are seated on the front seats while the vehicle is running. Consequently, noise in the vicinity of the ears of the occupants seated on the front seats 31A, 31B is suppressed.
Inasmuch as the microphones 43, 44 for confirming noise cancellation are positioned near the roof rails 30A, 30B facing the ears of the occupants seated on the front seats and output signals from the microphones 43, 44 are used as error signals, the active noise control system according to the second embodiment is capable of effectively canceling out noise in the passenger compartment based on low-frequency road noise.
Because the microphones 43, 44 for confirming noise cancellation are positioned near the roof rails 30A, 30B facing the ears of the occupants seated on the front seats in the vehicle 10A, the positions of the microphones 43, 44 are fixed, and the heads of the driver and the passenger who are seated on the front seats are disposed between the microphones 43, 44, it is possible to provide a wide noise cancellation area in lateral directions at the height of the heads, i.e., in lateral directions perpendicularly to the direction in which the vehicle travels.
With the microphone 45 added, the active noise control system additionally includes, as shown in
Specifically, noise in a plane formed between the microphones 43, 44, 45 and shown hatched in
The microphones 46A, 46B are thus positioned because the sound pressure level of noise in the passenger compartment centrally between the left and right roof rails 30A, 30B of the vehicle 10A and at the position facing the ear, on the compartment side of the occupant seated on the front seat is substantially equal to the sound pressure level of noise in the passenger compartment centrally between the left and right roof rails 30A, 30B of the vehicle 10A and at the position facing the ear, on the compartment side of the occupant seated on the rear seat. Since the microphones 46A, 46B are thus positioned centrally between the left and right roof rails 30A, 30B of the vehicle 10A and respectively at the position facing the ear, on the compartment side of the occupant seated on the front seat and at the position facing the ear, on the compartment side of the occupant seated on the rear seat, the active noise control system can attenuate noise in the passenger compartment at the ears on the compartment side of the occupants where the sound pressure of the noise is relatively high.
As described above, the active noise control system according to the second embodiment is capable of providing the same noise cancellation effect in the vicinity of the ears of occupants as the noise cancellation effect produced at the positions of microphones for confirming noise cancellation.
An active noise control system according to a third embodiment of the present invention will be described below.
The active noise control system according to the third embodiment employs the microphone 40 in the active noise control system according to the first embodiment as a microphone for detecting noise, and has a feedback control circuit for controlling noise.
Specifically, the microphone 40 shown in
The feedback control circuit 50 serves as an adjusting circuit for adjusting the amplitude and phase of the output signal from the microphone 40 based on the output signal from the microphone 40. The feedback control circuit 50 generates a cancellation signal which is of the same amplitude as, but out of phase to, noise at the microphone 40, and drives the speaker 25 with the cancellation signal.
As shown in
As shown in
The amplitude compensator 52 and the phase compensator 53 serve as the adjusting circuit.
The feedback control circuit 50 will be described in more specific detail. As shown in
The inverting amplifier 57 comprises an operational amplifier 60, a resistor 58, a resistor 59, and a resistor 61. The phase compensator 62 comprises a capacitor 63, a resistor 64, and a resistor 65.
The output signal from the microphone 40 is inverted and amplified by the inverting amplifier 57 to the same amplitude as the noise at the microphone 40. The inverted and amplified signal is advanced in phase by the phase compensator 62, which outputs a signal which is of the same amplitude as, but out of phase to, the noise. The output signal from the phase compensator 62 is applied to drive the speaker 25 to eliminate output signal from the microphone 40 for thereby canceling out the noise in the passenger compartment 24.
In
Specifically, the noise detected at 40 Hz and 80 Hz by the microphone 40 that is located at an antinode in the primary or secondary acoustic normal mode of the passenger compartment 24 behaves as a standing wave. The active noise control system according to the third embodiment operates to change the standing wave in the passenger compartment 24 in order to lower the sound pressure of the antinode of the standing wave where the microphone 40 is located. In some cases, the active noise control system can cancel out the standing wave in order to suppress the noise in the entire passenger compartment 24.
The active noise control system according to the third embodiment comprises the feedback control circuit 50 of simple construction which comprises the amplitude compensator 52 and the phase compensator 53 for noise cancellation. Therefore, the active noise control system may be smaller in size and more inexpensive than an active noise control system based on feed-forward control principles, and is less costly than a system for canceling out noise by adjusting the weight of a certain region of the vehicle body.
The feedback control circuit 50 may be arranged in a small size and combined with the microphone 40.
Since the storage box 68 is positioned beneath the base of the driver seat, i.e., the base of the front seat 31A, or the base of the front seat 31B, the storage box 68 cannot easily be touched by occupants, who are thus inhibited to touch the microphone 40. Because the microphone 40 and the feedback control circuit 50 are essentially integral with each other, the length of the microphone cord can be reduced, resulting in a reduced cost. Furthermore, the microphone 40 housed in the storage box 68 is prevented from being subject to an air flow that is produced when an occupant is seated on the front seat 31A or 31B.
As described above, the active noise control system according to the third embodiment is capable of canceling out noise in the passenger compartment based on low-frequency road noise and drumming noise with the simple arrangement that is composed of the microphone for detecting noise and the feedback control circuit.
Although certain preferred embodiments of the present invention have been shown and described in detail, it should be understood that various changes and modifications may be made therein without departing from the scope of the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
11-61908 | Mar 1999 | JP | national |
11-87149 | Mar 1999 | JP | national |
2000-24095 | Feb 2000 | JP | national |
Number | Date | Country | |
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Parent | 09522178 | Mar 2000 | US |
Child | 11407247 | Apr 2006 | US |