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Claims  |
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We claim:
1. An active noise reduction system comprising:
a noise-cancelling sound generator, a microphone acoustically coupled to
said generator, and a feedback loop connected between said microphone and
said generator, wherein said feedback loop comprises:
loop stabilization means for inverting the phase of microphone signals and
filtering the microphone signals, and means for amplifying the phase
inverted and filtered microphone signals; and
first high pass frequency filter means for filtering out sound energy from
high pressure sound pulses arising from flow frequency buffets, said first
high pass frequency filter means comprising a resistive-capacitive
combination and an amplifier having inverting and non-inverting inputs
with a negative feedback loop, an input of the filter means being provided
on one side of said resistive-capacitive combination and the other side of
said combination being connected to said inverting input and the
non-inverting input being connected to reference potential via a resistive
connection.
2. An active noise reduction system comprising:
a noise-cancelling sound generator, a microphone acoustically coupled to
said generator, and a feedback loop connected between said microphone and
said generator, wherein said feedback loop comprises:
loop stabilization means for inverting the phase of microphone signals and
filtering the microphone signals, and means for amplifying the phase
inverted and filtered signals; and
first high pass frequency filter means for filtering out sound energy from
high pressure sound pulses arising from low frequency buffets, wherein the
first filter means has a gain characteristic which is relatively low in a
first frequency band and then rises continuously to a relatively high
value in a second frequency band, said first filter means introducing a
phase shift which rises to a minimum value in a transitional region of
said gain characteristic of said first high pass frequency filter means.
3. A system according to claim 2, wherein said loop stabilisation means
includes means for limiting the amplitude of the signals in the feedback
loop.
4. A system as claimed in claim 2, including second high pass filter means
coupled between the loop stabilisation means and the amplifying means for
increasing loop gain and/or adjusting phase shift by predetermined amounts
within one or more predetermined frequency bands to compensate for
transfer characteristics of the microphone and generator.
5. A system as claimed in claim 4 wherein the second filter means has a
gain characteristic which is relatively low in a first frequency band and
then rises continuously to a relatively high value in a second frequency
band, the phase shift introduced by the filter rising to a maximum value
in the transitional region of filter gain.
6. A system as claimed in claim 5 wherein the second filter means includes
one or more stages, each stage comprising an amplifier with a negative
resistive feedback loop, and a resistive capacitive path to reference
potential connected to the inverting amplifier input.
7. A system as claimed in claim 4 wherein the functions of the first and
second filters are provided by a single high pass filter means, with the
transfer characteristics selected to filter out sound energy from high
pressure sound pulses and to increase loop gain and/or adjust phase shift
to compensate for transfer characteristics of the microphone and
generator.
8. A system according to claim 2, and further comprising means for
injecting a speech signal into the feedback loop between the further
filter means and the amplifying means.
9. A system according to claim 5, wherein the second high pass filter means
includes one or more stages, each stage including a first order high pass
active filter, the active filter network coupled to the operational
amplifier for providing a high pass characteristic.
10. A system according to claim 2 including a lowpass frequency filter
means, the gain of the filter in the cut-off region decreasing from a
relatively high constant gain region to a second relatively low constant
gain region in a transitional region where the gain decreases continuously
from the high region to the low region.
11. A system as claimed in claim 10, wherein the low pass frequency filter
means comprises a second order transitional filter comprising an
operational amplifier with a resistive-capacitive feedback loop connected
between the output and non-inverting amplifier input, and a resistive
feedback loop connected between the amplifier output and inverting output.
12. A system according to claim 10, wherein the low pass filter means
comprises a second order transitional filter.
13. A system according to claim 12, wherein the transitional filter
comprises a second order Sallen and Key filter configuration and further
including in parallel a positive feedback loop including a
resistive-capacitive combination.
14. A system according to claim 2, wherein the first filter means comprises
one or more stages, each stage comprising a first order high pass active
filter, the active filter including an operational amplifier, and a
resistive-capacitive network coupled to the operational amplifier for
providing a high pass characteristic.
15. A system according to claim 2, wherein the first high pass frequency
means is connected between the microphone and said loop stabilization
means.
16. An active noise reduction system comprising:
a noise-cancelling sound generator, a microphone acoustically coupled to
said generator, and a feedback loop connected between said microphone and
said generator, wherein said feedback loop comprises:
loop stabilization means for inverting the phase of microphone signals and
filtering the microphone signals, and means for amplifying the phase
inverted and filtered signals; and
further filter means coupled between the phase inverting means and the
amplifying means for increasing loop gain and/or adjusting phase shift by
predetermined amounts within one or more predetermined frequency bands,
wherein the further filter means has a gain characteristic which is
relatively low in a first frequency band and then rises continuously to a
relatively high value in a second frequency band, the phase shift
introduced by the further filter means rises to a maximum value in the
transitional region of filter gain characteristic.
17. A system as claimed in claim 16 wherein the further filter means
includes one or more stages, each stage comprising an amplifier with a
negative resistive feedback loop, and a resistive capacitive path to
reference potential connected to the amplifier inverting input.
18. A system as claimed in claim 16, and further comprising means for
injecting a speech signal into the feedback loop between the further
filter means and the amplifying means.
19. A system according to claim 16, and further including a low pass
frequency filter means, the gain of the low pass frequency filter means in
the cut-off region, decreasing from a relatively high constant gain region
to a relatively low constant gain region in a transitional region where
the gain decreases continuously from the high region to the low region.
20. A system according to claim 19, wherein the low pass filter frequency
filter means comprises a second order transitional filter comprising an
operational amplifier with a resistive-capacitive feedback loop connected
between the output and the non-inverting amplifier input, and a resistive
feedback loop connected between the amplifier output and inverting input.
21. A system according to claim 16, wherein the further filter means
includes one or more stages, each stage including a first order high pass
active filter, the active filter including an operational amplifier, and a
resistive-capacitive network coupled to the operational amplifier for
proving a high pass characteristic. |
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Claims |
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Description |
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This invention relates to systems for reducing the level of acoustic noise
fields within ear-defenders or earphone structures worn by personnel
(e.g., pilots, vehicle drivers, military personnel) in high noise
environments.
Known active noise reduction (ANR) systems for reducing the acoustic noise
filed in ear-defenders comprise noise pick-up microphones and
noise-cancelling sound generators (usually known as loudspeakers) mounted
within the internal cavities or enclosures of the respective
ear-defenders. The noise pick-up microphones produce electrical signal
outputs in response to the acoustic noise fields within the cavities and
these signal outputs are phase inverted, filtered and amplified in a
feedback loop and fed to the noise-cancelling sound generators which
produce noise-cancelling acoustic signals of substantially the same
amplitude but of opposite phase to the acoustic noise field waveforms. The
design considerations underlying such ANR systems are described in "Some
transducer design considerations for earphone active noise reduction
systems", Twiney et al., Vol. 7, part 2, pp. 95-102, Proc. Spring
Conference, 1985, York, Institute of Acoustics.
Problems arise through inherent imperfections in the pick-up microphones
and sound generators, by way of unwanted phase changes producing signal
enhancement or by way of failure to cope with large amplitude signals in
certain frequency regions.
One problem which occurs is that of large pressure pulses (buffets) which
occur inside an ear-defender or earphone structure due to relative
movement between the human head and the earphone, or propagate to the
earphone from a device that causes a rapid pressure change, e.g. a gun,
helicopter, vehicle, explosive device. These pulses are very high in
amplitude, and create large signals in the feedback loop as a result of
high system loop gain. Due to the inadequacy of the sound generator to
produce enough sound output, drive voltages appear at the sound generators
which are higher than the maximum input voltage, and may overdrive the
sound generator and cause permanent failure.
Another problem which arises is that of signal enhancement at certain
frequencies within the bandwidth of the feedback loop wherein due to
imperfect transfer functions of the noise pickup microphone and sound
generator the ANR will, at certain frequencies be feeding in-phase (i.e.
positive feedback) signals rather than anti-phase (i.e. negative feedback)
signals to the sound generator.
A further problem which occurs is that due to the imperfect transfer
functions of both the microphone and generator, the total bandwidth for
feedback signals having an appropriate phase is limited, being bounded by
regions in which positive feedback occurs. It is usual to employ in
feedback systems in general a lowpass first order filter operating at a
high frequency in order to stabilize the loop. However such first order
low pass filters are not appropriate for filtering out sound energy
frequencies in ANR systems because of the large phase changes which occur
in the cut-off regions which give rise to problems of positive feedback
and signal enhancement.
It was previously thought, as appears from the article referred to above,
that electronic processing to overcome problems in ANR systems had limited
application because of the causal relation between amplitude and phase
response of electronic filters.
Nevertheless it has now been found as a result of careful investigation
into the problems arising in feedback loops of ANR systems, that
electronic processing may be used to advantage.
It is an object of the present invention to overcome one or more of the
above problems.
Accordingly the present invention provides in a first aspect an active
noise reduction system comprising:
a noise-cancelling sound generator, a microphone acoustically coupled to
said generator, a feedback loop connected between the microphone and the
generator, the feedback loop including loop stabilisation means for
filtering and inverting the phase of the microphone signal and means for
amplifying the microphone signal, and the feedback loop further including
high pass frequency filter means for filtering out low frequency sound
energy from high pressure sound pulses arising from buffets at low
frequency.
Thus this aspect of the invention is based on the recognition that the
major part of sound energy in high pressure pulses is present at low
frequencies say below 100 Hz and thus the provision of low frequency
filter means in the feedback loop can reduce a major part of the sound
energy in the pulses. Such further filter means is conveniently preferred
to as an anti-buffet filter (ABF). The amount of ABF correction is limited
because stability of the feedback loop must be maintained, the total loop
gain being kept below unity where the total phase shift may cause
constructive interference.
Said further filter means may be used in conjunction with a voltage
limiting means, which prevents the generator from being overdriven by
amplification of high pressure sound pulses. Such voltage limiting means
may comprise a non-linear amplifier or zener diode arrangement.
It is also an object of the present invention to overcome the problem of
signal enhancement with a simple and effective mechanism.
In a further aspect, the present invention provides an active noise
reduction system comprising:
noise cancelling sound generator, a microphone acoustically coupled to said
generator, and a feedback loop connected between said microphone and said
generator, wherein said feedback loop comprises:
loop stabilisation means for inverting the phase of microphone signals and
filtering the microphone signals, and means for amplifying the phase
inverted and filtered signals; and,
further filter means coupled between the phase inverting means and the
amplifying means for increasing loop gain and/or adjusting phase shift by
predetermined amounts within one or more predetermined frequency bands.
Thus in accordance with the invention, the provision of further filter
means increasing gain or adjusting phase shift, preferably both, prevents
enhancement of the signal in the feedback loop arising from imperfect
transfer functions of the microphone and generator. The further filter
means is conveniently termed an anti-enhancement filter (AEF). The amount
of AEF correction is limited by the need to maintain stability of the
feedback loop (the total loop gain must be kept below unity when the total
phase shift may cause constructive interference).
This further aspect of the invention is based on our discovery that
enhancement problems caused by transducer imperfections arise in a
frequency region centered at about 500 Hz where the gain decreases whereas
the phase lag in this area increases to about 3.pi./2. Thus a high pass
filter which adjusts the gain in this region whilst providing a phase
advance compensating phase shift can significantly reduce the problems of
signal enhancement.
In a particularly preferred form of the invention, it has been discovered
as a result of careful investigation into the operability of ANR systems
that the functions of the ABF and AEF, which operate at different
frequencies and with different transfer functions can be accomplished by
the use of f single high pass filter (ABEF) for attenuating frequencies
below a predetermined frequency, the ABEF having appropriate transfer
characteristics to prevent phase shifts harmful to loop stability.
As mentioned above, it is normal to employ in ANR systems loop
stabilisation filters which include low pass filters for reducing the gain
at high frequencies to prevent loop instability. It has now been
discovered that the problem of low pass filters producing unduly large
phase changes at the high end of the feedback loop bandwidth can be
avoided and the present invention provides in a further aspect an active
noise reduction system comprising:
a noise-cancelling sound generator, a microphone acoustically coupled to
said generator, a feedback loop connected between the microphone and the
generator, the feedback loop including loop stabilisation means for
filtering and inverting the phase of the microphone signal and means for
amplifying the microphone signal, and the feedback loop further including
low pass frequency filter means for filtering out high frequency sound
energy, the gain of the filter in the cut-off region having a step shape,
decreasing from a relatively high constant gain region to a relatively low
constant gain region in a transitional region where the gain decreases
continuously from the high region to the low region.
By providing a cut-off filter characteristic having a step function in the
cut-off region, the phase change will be kept much smaller than that which
should occur with a first order low pass filter and by careful application
the ANR bandwidth can be increased whilst signal enhancement kept to
acceptable levels.
As preferred speech signals are injected at a single point in the feedback
loop between the AEF and the amplifying means, in order that the speech
signals are substantially uncoloured by the AEF and other filters. It will
be understood that the speech signals are in a frequency range which is
for the most part above the frequency range in which is for the most part
above the frequency range in which the ANR is operative and the speech
signals are not therefore reduced. They may however be affected by higher
frequency filters in the feedback loop.
A preferred embodiment of the invention will now be described with
reference to the accompanying drawing wherein:
FIG. 1 is a schematic diagram of an active noise reduction system according
to the present invention;
FIG. 2 is a circuit diagram of a preferred anti-buffet (ABF) filter;
FIG. 3 is a graph of the ABF characteristics;
FIG. 4 is a circuit diagram of a preferred anti-enhancement filter (AEF),
and FIG. 5 is a graph of the filter characteristics;
FIG. 6 is a circuit diagram of a low pass filter for defining an upper
limit of the feedback loop bandwidth;
FIG. 7 is a graph of the low pass filter characteristics;
FIG. 8 is a circuit diagram of an ABEF combining both AEF and ABF
characteristics;
FIG. 9 is a graph of the transfer functions of the ABEF of FIG. 8.
Referring to FIG. 1 of the Drawings, the active noise reduction system
illustrated comprises a generally cup-shaped circumaural earphone
structure 1 arranged to enclose the wearer's ear 2. The rim of the
structure 1 is cushioned against the side of the wearer's head 3 by means
of a compliant ring cushion 4. The earphone structure 1 embodies a small
noise pick-up microphone 5, which detects the noise within the earphone
adjacent to the wearer's ear 2 and provides an electrical output dependent
upon the detected noise. This output signal from the microphone is passed
through an anti-buffet filter 6, a loop stabilisation unit 7, a low-pass
filter 8, an anti-enhancement filter 10 and amplifier 12, to noise
cancelling sound generator (loudspeaker) 14 which is mounted on a baffle
16 within structure 1. Loop stabilisation unit 7 includes a phase inverter
72, a loop stabilizing filter 74 (which may be incorporated in low-pass
filter 8 as in FIG. 6) for filtering out very high frequencies, and a
voltage limiting circuit 76 comprising a zener diode switching arrangement
for limiting high amplitude input signals. Filter 6 is placed first in the
feedback loop in order to minimise signal values in the loop. The effect
of the anti-enhancement filter is to reduce noise effects arising from
imperfect transfer functions of microphone 5 and generator 14.
A speech signal is injected between anti-enhancement filter 10 and
amplifier 12 at an input node 18. The introduction of the speech signal at
this point allows the speech signal to be substantially uncoloured by the
loop filters. If desired the speech signals may be pre-emphasised by
amplification where they may be attenuated by the ANR system.
Referring to FIG. 2, the ABF 6 comprises an amplifier 20 having a negative
feedback loop with a resistor R1 connected to its inverting input, which
receives an input signal from a resistive/capacitive network R2, R3, C1.
The non-inverting input of the amplifier is connected through a resistor
R4 to ground.
The characteristics of ABF 6 are shown in FIG. 3, whence it may be seen
that the filter has a loss factor of about 8 db up to about 100 Hz at
which frequency the loss reduces continuously until at about 500 Hz the
filter exhibits a small gain factor.
The phase shift introduced by the filter is an advance with increasing
frequency rising in the transitional region from the base level of
substantially 180.degree. (the filter includes an inverting amplifier) to
a maximum at about 200 Hz of about 215.degree.. This phase shift must be
taken into account when considering the overall loop stability. The effect
of the ABF 6 on the overall feedback loop transfer function is to
attenuate the low frequency end of the function whereby noise in the
frequency range up to 200 Hz is severely attenuated.
The preferred form of AEF is shown in FIG. 4 as comprising two cascaded
stages 21, 22, each stage comprising an amplifier 24 with a resistor R1 in
a negative feedback loop and with the inverting amplifier input being
connected to ground via the series combination of a resistor R2 and
capacitor C1. The filter characteristics are shown in FIG. 5 with the gain
having an step for, being roughly 0 db up to 100 Hz and then rising to 10
db gain at 1 kHz. The phase shift, a phase advance with increasing
frequency, rises in the region in which the gain changes, from a base
level of substantially 0.degree. to a maximum value of 25.degree. at
roughly 500 Hz.
Because of the precise transfer functions of the microphone and generator,
the gain reduces to a minimum value at about 500 Hz whereas the phase
shift in this area rises to a maximum of about more than 3.pi./2. By
providing AEF, the transfer functions are modified in this area to reduce
phase shift and increase gain, thereby reducing signal enhancement.
A circuit diagram of low pass filter 8 is shown in FIG. 6 as comprising a
transitional second order filter including an amplifier 60 having a
non-inverting input connected to a filter input via resistors R1, R2 and a
capacitor C1 coupled between the amplifier input and ground. Two feedback
loops are provided from the amplifier output to the non-inverting input: a
first loop including a capacitor C2 and a second loop comprising resistors
R3, R4, R5 and a capacitor C3 in series with a resistor R9 connected
between resistors R4, R5 and ground. A further feedback loop is provided
comprising a resistor R7 connected between the amplifier output and the
inverting amplifier input. A further resistor R8 is connected between
resistor R7 and ground.
The characteristics of the filter are shown in FIG. 7 where the gain is
close to 0 db up to about 1000 Hz and is about -30 db around 10,000 hz.
The gain decreases between these regions relatively quickly in a cut-off
region.
The phase shift across the filter is roughly 150.degree. (the filter
includes a non-inverting amplifier) in the region below 1,000 Hz and above
10,000 Hz, but decreases to a minimum (a phase lag with increasing
frequency) of about 45.degree. in the center of the cut-off region. Such a
phase change of roughly 105.degree. is acceptable and is much smaller than
180 degrees resulting from a conventional second order low-pass filter.
Although a second order filter is shown, the filter could be a higher or
lower order if desired.
Referring now to FIG. 8, there is shown a high pass filter which combines
the functions of the AEF and ABF and is herein referred to as an ABEF. The
filter is a second order filter comprising tow filter sections connected
in cascade, the filter sections being identical. (If desired a first order
filter could be employed). Each filter section comprises an input port 80
coupled to the inverting input of an amplifier 82 through a resistance R1
connected in parallel with a capacitance C1 and a resistance R2. The
non-inverting input of the amplifier is connected to ground via a
resistance R3, and the output of the amplifier 86 is connected in a
negative feedback loop to the inverting input of the amplifier via a
resistor R4.
Referring now to FIG. 9, the characteristics of the filter of FIG. 8 are
shown where the gain is slightly greater than 0 db up to about 500 Hz and
then rises to about 10 db at a frequency of 2 kHz in a transitional region
between 500 Hz-2 kHz. The phase shift changes from a constant level of
about 0.degree. to a maximum value of substantially 60.degree. at about 1
kHz.
It will be appreciated that although the particular embodiment specifically
described is applied to a circumaural earphone structure, the invention
may also be applied to other earphone structures such as the supra-aural
type.
It will also be appreciated that the filters shown may be replaced by
digital filters, and the elements of the feedback loop may be digitised by
employing a micro-computer with appropriate routines. The invention
claimed is intended to cover both analog and digital systems.
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Description |
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