U.S. patent application number 16/218922 was filed with the patent office on 2020-06-18 for active noise cancellation device and earphone having acoustic filter.
The applicant listed for this patent is METAL INDUSTRIES RESEARCH&DEVELOPMENT CENTRE. Invention is credited to Tai-Hsin HSU.
Application Number | 20200193955 16/218922 |
Document ID | / |
Family ID | 71071716 |
Filed Date | 2020-06-18 |
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United States Patent
Application |
20200193955 |
Kind Code |
A1 |
HSU; Tai-Hsin |
June 18, 2020 |
ACTIVE NOISE CANCELLATION DEVICE AND EARPHONE HAVING ACOUSTIC
FILTER
Abstract
An active noise cancellation device having an acoustic filter
includes: a casing, an active noise cancellation unit, a speaker, a
noise cancellation processor and an acoustic filter. The casing
includes a first channel and a second channel, wherein a channel
length of the first channel is greater than a channel length of the
second channel. The active noise cancellation unit includes an
external microphone disposed outside the casing. The active noise
cancellation is configured to detect an ambient noise, wherein a
location of the external microphone corresponds to a location of
the first external end of the first channel. The speaker is
disposed at a second external end of the second channel, and is
configured to output a phase-inverted signal of the ambient noise.
The noise cancellation processor electrically couples with the
external microphone and the speaker. The acoustic filter is
disposed inside the first channel.
Inventors: |
HSU; Tai-Hsin; (KAOHSIUNG,
TW) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
METAL INDUSTRIES RESEARCH&DEVELOPMENT CENTRE |
KAOHSIUNG |
|
TW |
|
|
Family ID: |
71071716 |
Appl. No.: |
16/218922 |
Filed: |
December 13, 2018 |
Current U.S.
Class: |
1/1 |
Current CPC
Class: |
G10K 11/17861 20180101;
G10K 11/17854 20180101; G10K 11/17823 20180101; H04R 2460/01
20130101; G10K 11/175 20130101; G10K 2210/3028 20130101; H04R
1/1083 20130101 |
International
Class: |
G10K 11/178 20060101
G10K011/178; H04R 1/10 20060101 H04R001/10 |
Claims
1. An active noise cancellation device having an acoustic filter,
the active noise cancellation device comprising: a casing,
comprising a first channel and a second channel, wherein a channel
length between a first internal end and a first external end of the
first channel is greater than a channel length between a second
internal end and a second external end of the second channel; an
active noise cancellation unit, comprising: an external microphone,
disposed outside the casing, and configured to detect an ambient
noise, wherein a location of the external microphone corresponds to
a location of the first external end; a speaker, disposed at the
second external end, and configured to output a phase-inverted
signal of the ambient noise; and a noise cancellation processor,
electrically coupled to the external microphone and the speaker;
and an acoustic filter, disposed inside the first channel.
2. The active noise cancellation device having an acoustic filter
according to claim 1, wherein the first channel is located on a
side of the second channel.
3. The active noise cancellation device having an acoustic filter
according to claim 1, wherein the first channel comprises a first
external channel, a first internal channel and a second internal
channel, the first external channel is physically connected with
both the first internal channel and the second internal channel,
and the first internal channel and the second internal channel are
located on two sides of the second channel.
4. The active noise cancellation device having an acoustic filter
according to claim 3, wherein the acoustic filter is located inside
the first external channel.
5. The active noise cancellation device having an acoustic filter
according to claim 1, wherein the first channel further comprises a
low pass filter tubular shape, and the low pass filter tubular
shape has a cavity configured to accommodate the acoustic
filter.
6. The active noise cancellation device having an acoustic filter
according to claim 1, wherein the acoustic filter and the active
noise cancellation unit form a band pass filter.
7. The active noise cancellation device having an acoustic filter
according to claim 1, wherein a material of the casing is selected
from the group consisting of silicone, thermoplastic elastomer
(TPE), thermoplastic rubber (TPR), thermoplastic vulcanizate (TPV),
thermoplastic polyurethane (TPU), thermoplastic polyether ester
elastomer (TPEE) and a combination thereof.
8. The active noise cancellation device having an acoustic filter
according to claim 1, wherein the location of the external
microphone is close to the location of the first external end.
9. The active noise cancellation device having an acoustic filter
according to claim 1, wherein the second external end is a closed
end.
10. The active noise cancellation device having an acoustic filter
according to claim 1, wherein the active noise cancellation unit
further comprises an internal microphone, located near an area
outside exits of the first internal end of the first channel and
the second internal end of the second channel.
11. The active noise cancellation device having an acoustic filter
according to claim 1, wherein the active noise cancellation unit
further comprises a sound signal component electrically coupled the
noise cancellation processor and configured to receive an external
sound signal for providing the external sound signal to the noise
cancellation processor.
12. An in-ear earphone, comprising: an earphone casing; and the
active noise cancellation device having an acoustic filter
according to claim 1, disposed inside the earphone casing.
13. The in-ear earphone according to claim 12, further comprising a
bulge, wherein the bulge is located at an external end of the
earphone casing, and the bulge has a channel configured to enable
acoustic propagation into the earphone casing.
Description
BACKGROUND
Technical Field
[0001] The present invention relates to a noise cancellation
device, and in particular, to an active noise cancellation device,
a circumaural earphone, and an in-ear earphone.
Related Art
[0002] According to a most common conventional noise suppression
technology, noise suppression is implemented in most cases by
passively absorbing noise energy by using various sound absorption
materials. However, in a low frequency status, a wavelength of a
sound is far greater than a thickness of a general sound absorption
material. For example, a sound whose frequency is 100 Hz has a
wavelength about 3.4 meters at sea level and under the normal
atmospheric temperature. Therefore, transmission of a low frequency
sound can be effectively blocked only by using a very thick and
heavy sound absorption material. However, for general application,
this passive noise cancellation technology is not ideal for a
capability of isolating a low-frequency noise. Therefore, during
practical application, according to a passive noise cancellation
method, a balance often needs to be achieved in a problem of
contradiction between effective cancellation of a low-frequency
noise and a sound absorption material, wherein the sound absorption
material may occupy very large space and have a large size and a
high cost.
[0003] To be capable of effectively resolving the foregoing
problem, an active noise control (ANC) theory using an extra sound
source to cancel a noise has been widely studied and developed in
depth for years. A basic principle of an active noise control
system is mainly using a waveform synthesis principle to generate
an anti-noise sound wave having a waveform the same as a waveform
of an original noise, the intensity equal to the intensity of the
original noise, and a phase difference of 180 degrees from the
original noise, so that the anti-noise sound wave has destructive
interference to the original noise, thereby achieving an objective
of reducing noise amplitude. FIG. 1 shows an original-noise
waveform L1, an anti-noise waveform L2, and a residual-noise
waveform L3 formed after a superposition of the original-noise
waveform and the anti-noise waveform.
[0004] Taiwan patent number I609363 discloses an active noise
cancellation correction system and a speaker apparatus. Referring
to FIG. 2, the related art in the patent document shows a structure
of an active noise cancellation system. An external ambient noise
is received by using a microphone 90. After being adjusted by an
active filter 92, this noise source sends suitable frequency
responses, including a suitable amplitude response and phase
response, so that an earphone speaker 94 almost outputs a
phase-inverted signal of the original noise source. This
phase-inverted noise produced by the speaker can be exactly offset
due to a superposition of this phase-inverted noise and the
original noise inside an earphone ear muff 96 of a listener 8. The
offset results in substantial reduction of an external noise heard
by the listener 8. This is a principle of a general active noise
cancellation earphone.
[0005] However, a main noise cancellation range of the general
active noise cancellation earphone is a medium and low frequency
range of 50 Hz to 2 KHz, and a reduction effect for a high
frequency noise is not good. In addition, even if a sound in an
environment can be heard, the related art does not mention that
only some frequency band is heard. Therefore, in a noisy
environment, to filter out most noises and hear a voice or even a
sound in a particular frequency band, usually digital signal
processing needs to be performed. The cost is high for the
protecting a general explosive sound is implemented through
high-speed digital signal processing in circuit designs.
[0006] Therefore, it needs to provide an active noise cancellation
device having an acoustic filter, to resolve the foregoing
problem.
SUMMARY
[0007] An objective of the present invention is to provide an
active noise cancellation device having an acoustic filter, and the
active noise cancellation device combines an active noise
cancellation unit and the acoustic filter.
[0008] To achieve the foregoing objective, the present disclosure
discloses an active noise cancellation device having an acoustic
filter includes: a casing including a first channel and a second
channel, wherein a channel length of the first channel is greater
than a channel length of the second channel; an active noise
cancellation unit including an external microphone, disposed
outside the casing, and configured to detect an ambient noise,
wherein a location of the external microphone corresponds to a
location of the first external end of the first channel; a speaker
disposed at a second external end of the second channel, and
configured to output a phase-inverted signal of the ambient noise;
and a noise cancellation processor electrically coupling to the
external microphone and the speaker; and an acoustic filter,
disposed inside the first channel.
[0009] The active noise cancellation device having an acoustic
filter in the present invention combines the active noise
cancellation unit (including the external microphone, the speaker,
and the noise cancellation processor) and the acoustic filter to
form a band pass filter, so that a sound in a particular frequency
domain can pass through the casing to enter the auditory canal of
the listener. For a noise passing through the first channel of the
casing and to the auditory canal, the active noise cancellation
unit evenly reduces noise intensity based on a frequency when the
frequency is less than 1 KHz. In addition, for the noise passing
through the first channel of the casing and to the auditory canal,
the acoustic filter enhances a noise cancellation effect as the
frequency increases while the frequency is greater than 1 KHz.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] FIG. 1 is a comparison diagram of a difference between an
original-noise waveform, an anti-noise waveform, and a
residual-noise waveform in the prior art.
[0011] FIG. 2 is a schematic diagram of a structure of a
conventional active noise cancellation system.
[0012] FIG. 3 is a schematic diagram of a structure of an active
noise cancellation device having an acoustic filter according to a
first embodiment of the present invention.
[0013] FIG. 4 is a schematic diagram of cross sections of an
acoustic filter and a low pass filter tubular shape according to
the present invention.
[0014] FIG. 5 is a schematic diagram of a cross section of a low
pass filter tubular shape according to the present invention.
[0015] FIG. 6 is a schematic diagram of a structure of an active
noise cancellation device having an acoustic filter according to
another embodiment of the present invention.
[0016] FIG. 7 is a schematic diagram of a structure of a
circumaural earphone according to an embodiment of the present
invention.
[0017] FIG. 8 is a schematic diagram of a structure of an in-ear
earphone according to an embodiment of the present invention.
[0018] FIG. 9 is a schematic diagram of a structure of an active
noise cancellation device having an acoustic filter according to a
second embodiment of the present invention.
DETAILED DESCRIPTION
[0019] To make the foregoing objective, feature, and characteristic
of the present invention clearer and easier to be understood,
related embodiments of the present invention are described in
detail in the following with reference to the drawings.
[0020] FIG. 3 is a schematic diagram of a structure of an active
noise cancellation device 1 having an acoustic filter according to
a first embodiment of the present invention. The active noise
cancellation device 1 includes: a casing 10, an active noise
cancellation unit (including an external microphone 111, a speaker
112, and a noise cancellation processor 113), and an acoustic
filter 12. The casing 10 includes a first channel 101 and a second
channel 102, and a channel length between a first internal end 1011
and a first external end 1012 of the first channel 101 is greater
than a channel length between a second internal end 1021 and a
second external end 1022 of the second channel 102. The first
internal end 1011 and the second internal end 1021 refer to ends,
of the channels, close to an auditory canal 81, and the first
external end 1012 and the second external end 1022 refer to other
ends, of the channels, away from the auditory canal 81. In this
embodiment, the first channel 101 is located on a side 1023 of the
second channel 102. A material of the casing 10 can be selected
from the group consisting of silicone, thermoplastic elastomer
(TPE), thermoplastic rubber (TPR), thermoplastic vulcanizate (TPV),
thermoplastic polyurethane (TPU), thermoplastic polyether ester
elastomer (TPEE), and a combination thereof.
[0021] The active noise cancellation unit includes: an external
microphone 111, a speaker 112, and a noise cancellation processor
113. The external microphone 111 is disposed outside the casing 10,
and is configured to detect an ambient noise, wherein a location of
the external microphone 111 corresponds to a location of the first
external end 1012. For example, the location of the external
microphone 111 is close to the location of the first external end
1012. The speaker 112 is disposed at the second external end 1021,
and is configured to output a phase-inverted signal of the ambient
noise, wherein the second external end 1021 is a closed end. The
noise cancellation processor 113 is electrically coupled to the
external microphone 111 and the speaker 112, and is configured to
perform phase-inverted processing on the ambient noise detected by
the external microphone 111, and then transmit the ambient noise to
the speaker 112. The speaker 112 outputs the phase-inverted signal
of the ambient noise through the second channel 102, so that the
ambient noise transmitted into the auditory canal 81 of the
listener 8 through the first channel 101 can be reduced.
[0022] For example, the channel length of the first channel 101 is
greater than the channel length of the second channel 102, and the
location of the external microphone 111 is close to the location of
the first external end 1012. Therefore, the noise cancellation
processor 113 can perform signal and phase adjustment based on a
difference between a time taken by the phase-inverted signal of the
ambient noise output by the speaker 112 to pass through the second
channel 102 and a time taken by the ambient noise to pass through
the first channel 101. In this way, a preferable superposition
effect is achieved for the ambient noise and the phase-inverted
signal of the ambient noise in an area outside exits of the first
internal end 1011 of the first channel 101 and the second internal
end 1021 of the second channel 102, thereby achieving a preferable
effect of noise cancellation.
[0023] The acoustic filter 12 is disposed inside the first channel
101. Referring to FIG. 4 and FIG. 5, the first channel 101 further
includes a low pass filter tubular shape 1013. The low pass filter
tubular shape 1013 has a cavity 1014, and the cavity 1014 is
configured to accommodate the acoustic filter 12. The low pass
filter tubular shape 1013 further has a first caliber S1, a second
caliber S2, a third caliber S3, and a cavity length LL. The second
caliber S2 is greater than the first caliber Si and the third
caliber S3, and the cavity length LL and the second caliber S2 form
the cavity 1014. The low pass filter tubular shape 1013 can enhance
an effect of a low pass filter.
[0024] For example, the acoustic filter 12 includes a thin film
therein, and the thin film can attenuate intensity of an incoming
sound. The acoustic filter 12 can apparently enhance an attenuation
effect for an over 1 KHz high-frequency noise passing through the
first channel 101 of the casing 10 and to the auditory canal 81 of
the listener 8.
[0025] Therefore, the active noise cancellation device 1 having an
acoustic filter in the present invention combines the active noise
cancellation unit (including the external microphone 111, the
speaker 112, and the noise cancellation processor 113) and the
acoustic filter 12 to form a band pass filter, so that a sound in a
particular frequency domain can pass through the casing to enter
the auditory canal 81 of the listener 8. For a noise passing
through the first channel 101 of the casing 10 and to the auditory
canal 81, the active noise cancellation unit evenly reduces noise
intensity based on a frequency when the frequency is less than 1
KHz. In addition, for the noise passing through the first channel
101 of the casing 10 and to the auditory canal 81, the acoustic
filter 12 enhances a noise cancellation effect as the frequency
increases while the frequency is greater than 1 KHz.
[0026] In particular, the active noise cancellation unit can have a
relatively low noise cancellation effect in a range of 80 Hz to 520
Hz, enabling a main frequency of a voice of a person to pass
through the active noise cancellation unit. If a noise whose
frequency is over 1 KHz is greatly reduced by using the acoustic
filter together, loudness of the voice of the person can be
highlighted when a design is performed in coordination with an
equal loudness contour (for example, ISO 226).
[0027] The active noise cancellation device having an acoustic
filter in the present invention combines the active noise
cancellation unit and the acoustic filter, so that a degree of
freedom for adjusting a noise cancellation curve is increased,
reducing development costs of processing software and hardware of
the active noise cancellation. For a general active noise
cancellation unit, noise cancellation processing in a low frequency
domain is easy, but noise cancellation processing in a high
frequency domain is difficult. However, for a general acoustic
filter, a sound filtering effect is relatively good at the high
frequency. Therefore, a band pass filter can be formed by combining
the two, to allow a voice or an alarm sound to pass through in a
noisy environment.
[0028] Referring to FIG. 6, in another embodiment, the active noise
cancellation unit 11 further includes an internal microphone 114,
located near an area outside exits of the first internal end 1011
of the first channel 101 and the second internal end 1021 of the
second channel 102. The internal microphone 114 is a microphone
receiving an error signal. The internal microphone 114 is
electrically coupled to the noise cancellation processor 113, and
is configured to transmit the error signal to the noise
cancellation processor 113. The external microphone 111 is a
microphone for receiving a reference signal, and the external
microphone 111 is also configured to transmit the reference signal
to the noise cancellation processor 113. For example, by using an
architecture of the active noise cancellation technology, the
external microphone 111 receives a reference signal, and then the
internal microphone 114 receives a reduced ambient noise (error
signal). The error signal is fed back to the noise cancellation
processor 113. The noise cancellation processor 113 can
automatically adjust a parameter of a digital filter, such as a
digital finite impulse response filter (Digital FIR Filter). The
speaker 112 is equipped with a built-in amplifier, such as a
class-D amplifier, being capable of receiving a signal of the noise
cancellation processor 113 and converting the signal into an audio
signal. The objective is to suppress a noise transmitted into the
auditory canal 81 to the minimum.
[0029] In still another embodiment, the active noise cancellation
unit 11 further includes a sound signal component 115. The sound
signal component 115 (such as a wireless signal receiver) is
electrically coupled the noise cancellation processor 113, and is
configured to receive an external sound signal (such as music or a
voice) and provide the external sound signal to the noise
cancellation processor 113.
[0030] FIG. 7 is a schematic diagram of a structure of a
circumaural earphone according to an embodiment of the present
invention. The circumaural earphone 2 includes: an ear muff 21, and
the active noise cancellation device 1 having an acoustic filter in
the present invention. The active noise cancellation device 1
having an acoustic filter can be disposed inside the ear muff 21 of
the circumaural earphone 2.
[0031] FIG. 8 is a schematic diagram of a structure of an in-ear
earphone according to an embodiment of the present invention. The
in-ear earphone 3 includes: an earphone casing 31, and the active
noise cancellation device 1 having an acoustic filter in the
present invention. The active noise cancellation device 1 having an
acoustic filter can be disposed inside the earphone casing 31. A
casing of the active noise cancellation device 1 having an acoustic
filter and the earphone casing 31 are manufactured by integral
formation and made of the same material. For example, the material
of the casing of the active noise cancellation device 1 having an
acoustic filter and the earphone casing 31 can be selected from the
group consisting of silicone, TPE, TPR, TPV, TPU, TPEE, and a
combination thereof. The in-ear earphone 3 further includes a bulge
32, located at an external end 312 of the earphone casing 31. After
the in-ear earphone 3 is inserted into an auditory canal of a
listener, the listener can conveniently catch hold of the bulge 32
and easily pull out the in-ear earphone 3. The bulge 32 has a
channel 33, which is configured to enable acoustic propagation into
the earphone casing 31.
[0032] FIG. 9 is a schematic diagram of a structure of an active
noise cancellation device 1' having an acoustic filter according to
a second embodiment of the present invention. The active noise
cancellation device 1' having an acoustic filter in the second
embodiment is substantially similar to the active noise
cancellation device 1 having an acoustic filter in the first
embodiment, and similar components are represented by using similar
reference numbers. A main difference between the two is: A first
channel 101' of a casing 10' of the active noise cancellation
device 1' having an acoustic filter includes a first external
channel 101a, a first internal channel 101b, and a second internal
channel 101c; the first external channel 101a is physically
connected (e.g., communicated) with both the first internal channel
101b and the second internal channel 101c; and the first internal
channel 101b and the second internal channel 101c are located on
two sides 1023, 1024 of the second channel 102, wherein the
acoustic filter 12 is located inside the external channel 101a of
the first channel 101.
[0033] Similarly, the active noise cancellation device having an
acoustic filter in the present invention combines the active noise
cancellation unit (including the external microphone 111, the
speaker 112, and the noise cancellation processor 113) and the
acoustic filter 12 to form a band pass filter, so that a sound in a
particular frequency domain can pass through the casing to enter
the auditory canal 81 of the listener 8. For a noise passing
through the first channel 101' of the casing 10 and to the auditory
canal 81, the active noise cancellation unit evenly reduces noise
intensity based on a frequency when the frequency is less than 1
KHz. In addition, for the noise passing through the first channel
101' of the casing 10 and to the auditory canal 81, the acoustic
filter 12 enhances a noise cancellation effect as the frequency
increases when the frequency is greater than 1 KHz.
[0034] The active noise cancellation device having an acoustic
filter in the present invention combines the active noise
cancellation unit and the acoustic filter, so that a degree of
freedom for adjusting a noise cancellation curve is increased,
reducing development costs of processing software and hardware of
the active noise cancellation. For a general active noise
cancellation unit, noise cancellation processing in a low frequency
domain is easy, but noise cancellation processing in a high
frequency domain is difficult. However, for a general acoustic
filter, a sound filtering effect is relatively good at the high
frequency. Therefore, a band pass filter can be formed by combining
the two, to allow a voice or an alarm sound to pass through in a
noisy environment.
[0035] The active noise cancellation device 1' having an acoustic
filter in the second embodiment of the present invention can
alternatively be applied to the circumaural earphone or the in-ear
earphone.
[0036] The foregoing descriptions are only preferred
implementations or embodiments for presenting technical means used
for resolving a problem in the present invention, and are not used
for limiting the implementation scope of the patent in the present
invention. In other words, all equivalent changes and modifications
complying with a literal meaning of the patent application scope of
the present invention or performed based on the patent scope of the
present invention fall within the patent scope of the present
invention.
* * * * *