BACKGROUND
1. Field
[0001] Disclosed herein is a noise reducing sound reproduction system and, in particular,
a noise reduction system which includes an earphone for allowing a user to enjoy,
for example, reproduced music or the like, with reduced ambient noise.
2. Related Art
[0002] In active noise reduction systems, also known as active noise cancellation/control
(ANC) systems, the same loudspeakers, in particular loudspeakers arranged in the two
earphones of headphones, are often used for both noise reduction and reproduction
of desirable sound such as music or speech. However, there is a significant difference
between the sound impression created by employing active noise reduction and the impression
created by not employing active noise reduction, due to the fact that common noise
reduction systems reduce the desirable sound to a certain degree, as well. Accordingly,
either advanced electrical signal processing is required to compensate for this effect
or the listener has to accept sound impressions that differ, depending on whether
noise reduction is on or off.
GAN W S ET AL: "AN INTEGRATED AUDIO AND ACTIVE NOISE CONTROL HEADSETS", IEEE TRANSACTIONS
ON CONSUMER ELECTRONICS; IEEE SERVICE CENTER, NEW YORK, NY,US, vol. 48, no. 2, 1 May
2002 (2002-05-01), pages 242-247, describes an integrated audio and active noise headset.
US2010/329473A1 discloses detecting a change in power of an output signal of a filter and controlling
the filter dependent thereon.
EP1947642A1 discloses active noise control that employs a reference sound to adapt noise control.
KUO S M ET AL: "ACTIVE NOISE CONTROL; A TUTORIAL REVIEW", PROCEEDINGS OF THE IEEE,
IEEE; NEW YORK, US, vol. 87, no. 6, 1 June 1999, pages 943-973 describes a simple active noise control system. There is a need for an improved noise
reduction system to overcome the drawbacks of known systems. Further noise reduction
audio systems are known from
WO 94/23419 A1 and
WO 01/67434 A1.
SUMMARY OF THE INVENTION
[0003] In a first aspect of the invention, a noise reducing sound reproduction system is
disclosed that comprises: a loudspeaker that is connected to a loudspeaker input path;
a microphone that is acoustically coupled to the loudspeaker via a secondary path
and connected to a microphone output path; a first subtractor that is connected downstream
of the microphone output path and a first useful-signal path; an active noise reduction
filter that is connected downstream of the first subtractor; and a second subtractor
that is connected downstream of the active noise reduction filter, downstream of second
useful-signal path, and upstream of the loudspeaker input path. The secondary path
has a secondary path transfer characteristic. Both useful-signal paths are supplied
with a useful signal to be reproduced and at least one of the useful-signal paths
comprise one or more spectrum shaping filters. At least one of the spectrum shaping
filters has a transfer characteristic that models the secondary path transfer characteristic.
The first useful-signal path comprises the at least one spectrum shaping filter and
the at least one spectrum shaping filter that models the secondary path transfer characteristic
linearizes a microphone signal on the microphone output path with regard to the useful
signal. The at least one spectrum shaping filter that models the secondary path transfer
characteristic comprises at least two sub-filters. One of the sub-filters of the at
least one spectrum shaping filter that models the secondary path transfer characteristic
is a treble cut shelving filter.
[0004] In a second aspect of the invention, a noise reducing sound reproduction method is
disclosed, in which: an input signal is supplied to a loudspeaker by which it is acoustically
radiated; the signal radiated by the loudspeaker is received by a microphone that
is acoustically coupled to the loudspeaker via a secondary path that has a secondary
path transfer characteristic and that provides a microphone output signal; from the
microphone output signal a useful-signal is subtracted to generate a filter input
signal; the filter input signal is filtered in an active noise reduction filter to
generate an error signal; and the useful-signal is subtracted from the error signal
to generate the loudspeaker input signal; and the useful-signal is filtered by one
or more spectrum shaping filters prior to subtraction from the microphone output signal.
At least one of the spectrum shaping filters has a transfer characteristic that models
the secondary path transfer characteristic. The useful signal, prior to subtraction
from the microphone output signal, is filtered with the transfer characteristic of
the at least one spectrum shaping filter that models the secondary path transfer characteristic,
wherein the at least one spectrum shaping filter that models the secondary path transfer
characteristic linearizes a microphone signal on the microphone output path with regard
to the useful signal. The filtering of the useful signal includes treble cut shelving
filtering. The invention thus provides a system according to claim 1 and a method
according to claim 6. Further embodiments are defined by the dependent claims.
BRIEF DESCRIPTION OF THE DRAWINGS
[0005] Various specific embodiments are described in more detail below based on the exemplary
embodiments shown in the figures of the drawing. Unless stated otherwise, similar
or identical components are labeled in all of the figures with the same reference
numbers.
FIG. 1 is a block diagram of a general feedback type active noise reduction system
in which the useful signal is supplied to the loudspeaker signal path;
FIG. 2 is a block diagram of a general feedback type active noise reduction system
in which the useful signal is supplied to the microphone signal path;
FIG. 3 is a block diagram of a general feedback type active noise reduction system
in which the useful signal is supplied to the loudspeaker and microphone signal paths;
FIG. 4 is a block diagram of the active noise reduction system of FIG. 3, in which
the useful signal is supplied via a spectrum shaping filter to the loudspeaker path.
FIG. 5 is a block diagram of the active noise reduction system of FIG. 3, in which
the useful signal is supplied via a spectrum shaping filter to the microphone path;
FIG. 6 is a schematic diagram of an earphone applicable in connection with the active
noise reduction systems of FIGS. 3-6;
FIG. 7 is a block diagram of the active noise reduction system of FIG. 5 in which
the useful signal is supplied via two spectrum shaping filters to the microphone path;
FIG. 8 is a magnitude frequency response diagram representing the transfer characteristics
of shelving filters applicable in the system of FIG. 7;
FIG. 9 is a magnitude frequency response diagram representing the transfer characteristics
of equalizing filters applicable in the system of FIG. 7; and
FIG. 10 is a block diagram of the active noise reduction system of FIG. 5, in which
the useful signal is supplied via spectrum shaping filters to the microphone and loudspeaker
paths.
DETAILED DESCRIPTION
[0006] Feedback ANC systems are intended to reduce or even cancel a disturbing signal, such
as noise, by providing at a listening site a noise reducing signal that ideally has
the same amplitude over time but the opposite phase compared to the noise signal.
By superimposing the noise signal and the noise reducing signal, the resulting signal,
also known as error signal, ideally tends toward zero. The quality of the noise reduction
depends on the quality of a so-called secondary path, i.e., the acoustic path between
a loudspeaker and a microphone representing the listener's ear. The quality of the
noise reduction further depends on the quality of a so-called ANC filter that is connected
between the microphone and the loudspeaker and that filters the error signal provided
by the microphone such that, when the filtered error signal is reproduced by the loudspeaker,
it further reduces the error signal. However, problems occur when additionally to
the filtered error signal a useful signal such as music or speech is provided at the
listening site, in particular by the loudspeaker that also reproduces the filtered
error signal. Then, the useful signal may be deteriorated by the system as previously
mentioned.
[0007] For the sake of simplicity, no distinction is made herein between electrical and
acoustic signals. However, all signals provided by the loudspeaker or received by
the microphone are actually of an acoustic nature. All other signals are electrical
in nature. The loudspeaker and the microphone may be part of an acoustic sub-system
(e.g., a loudspeaker-room-microphone system) having an input stage formed by the loudspeaker
3 and an output stage formed by the microphone; the sub-system being supplied with
an electrical input signal and providing an electrical output signal. "Path" means
in this regard an electrical or acoustical connection that may include further elements
such as signal conducting means, amplifiers, filters, etc. A spectrum shaping filter
is a filter in which the spectra of the input and output signal are different over
frequency.
[0008] Reference is now made to FIG. 1, which is a block diagram illustrating a general
feedback type active noise reduction (ANC) system in which a disturbing signal d[n],
also referred to as noise signal, is transferred (radiated) to a listening site, e.g.,
a listener's ear, via a primary path 1. The primary path 1 has a transfer characteristic
of P(z). Additionally, an input signal v[n] is transferred (radiated) from a loudspeaker
3 to the listening site via a secondary path 2. The secondary path 2 has a transfer
characteristic of S(z).
[0009] A microphone 4 positioned at the listening site receives together with the disturbing
signal d[n] the signals that arise from the loudspeaker 3. The microphone 4 provides
a microphone output signal y[n] that represents the sum of these received signals.
The microphone output signal y[n] is supplied as filter input signal u[n] to an ANC
filter 5 that outputs to an adder 6 an error signal e[n]. The ANC filter 5, which
may be an adaptive filter, has a transfer characteristic of W(z). The adder 6 also
receives an optionally pre-filtered, e.g., with a spectrum shaping filter (not shown
in the drawings) useful signal x[n] such as music or speech and provides an input
signal v[n] to the loudspeaker 3.
[0010] The signals x[n], y[n], e[n], u[n] and v[n] are in the discrete time domain. For
the following considerations their spectral representations X(z), Y(z), E(z), U(z)
and V(z) are used. The differential equations describing the system illustrated in
FIG. 1 are as follows:

[0011] In the system of FIG. 1, the useful signal transfer characteristic M(z) = Y(z)/X(z)
is thus

[0013] Assuming W(z) = ∞ then

[0014] As can be seen from equations (4)-(7), the useful signal transfer characteristic
M(z) approaches 0 when the transfer characteristic W(z) of the ANC filter 5 increases,
while the secondary path transfer function S(z) remains neutral, i.e. at levels around
1, i.e., 0[dB]. For this reason, the useful signal x[n] has to be adapted accordingly
to ensure that the useful signal x[n] is apprehended identically by a listener when
ANC is on or off. Furthermore, the useful signal transfer characteristic M(z) also
depends on the transfer characteristic S(z) of the secondary path 2 to the effect
that the adaption of the useful signal x[n] also depends on the transfer characteristic
S(z) and its fluctuations due to aging, temperature, change of listener etc. so that
a certain difference between "on" and "off" will be apparent.
[0015] While in the system of FIG. 1 the useful signal x[n] is supplied to the acoustic
sub-system (loudspeaker, room, microphone) at the adder 6 connected upstream of the
loudspeaker 3, in the system of FIG. 2 the useful signal x[n] is supplied at the microphone
4. Therefore, in the system of FIG. 2, the adder 6 is omitted and an adder 7 is arranged
downstream of microphone 4 to sum up the, e.g., pre-filtered, useful signal x[n] and
the microphone output signal y[n]. Accordingly, the loudspeaker input signal v[n]
is the error signal [e], i.e., v[n] = [e], and the filter input signal u[n] is the
sum of the useful signal x[n] and the microphone output signal y[n], i.e., u[n] =
x[n]+y[n].
[0016] The differential equations describing the system illustrated in FIG. 2 are as follows:

[0018] As can be seen from equations (11)-(13), the useful signal transfer characteristic
M(z) approaches 1 when the open loop transfer characteristic (W(z)·S(z)) increases
or decreases and approaches 0 when the open loop transfer characteristic (W(z)·S(z))
approaches 0. For this reason, the useful signal x[n] has to be adapted additionally
in higher spectral ranges to ensure that the useful signal x[n] is apprehended identically
by a listener when ANC is on or off. Compensation in higher spectral ranges is, however,
quite difficult so that a certain difference between "on" and "off" will be apparent.
On the other hand, the useful signal transfer characteristic M(z) does not depend
on the transfer characteristic S(z) of the secondary path 2 and its fluctuations due
to aging, temperature, change of listener etc.
[0019] FIG. 3 is a block diagram illustrating a general feedback type active noise reduction
system in which the useful signal is supplied to both, the loudspeaker path and the
microphone path. For the sake of simplicity, the primary path 1 is omitted below notwithstanding
that noise (disturbing signal d[n]) is still present. In particular, the system of
FIG. 3 is based on the system of FIG. 1, however, with an additional subtractor 8
that subtracts the useful signal x[n] from the microphone output signal y[n] to form
the ANC filter input signal u[n] and with a subtractor 9 that substitutes adder 6
and subtracts the useful signal x[n] from error signal e[n].
[0020] The differential equations describing the system illustrated in FIG. 3 are as follows:

[0022] It can be seen from equations (17)-(19) that the behavior of the system of FIG. 3
is similar to that of the system of FIG. 2. The only difference is that the useful
signal transfer characteristic M(z) approaches S(z) when the open loop transfer characteristic
(W(z)·S(z)) approaches 0. Like the system of FIG. 1, the system of FIG. 3 depends
on the transfer characteristic S(z) of the secondary path 2 and its fluctuations due
to aging, temperature, change of listener etc.
[0023] In FIG. 4, a system is shown that is based on the system of FIG. 3 and that additionally
includes an equalizing filter 10 connected upstream of the subtractor 9 in order to
filter the useful signal x[n] with the inverse secondary path transfer function 1/S(z).
The differential equations describing the system illustrated in FIG. 4 are as follows:

[0024] The useful signal transfer characteristic M(z) in the system of FIG. 4 is thus

[0025] As can be seen from equation (22), the microphone output signal y[n] is identical
to the useful signal x[n], which means that signal x[n] is not altered by the system
if the equalizer filter is exact the inverse of the secondary path transfer characteristic
S(z). The equalizer filter 10 may be a minimum-phase filter for optimum results, i.e.,
optimum approximation of its actual transfer characteristic to the inverse of, the
ideally minimum phase, secondary path transfer characteristic S(z) and, thus y[n]
= x[n]. This configuration acts as an ideal linearizer, i.e. it compensates for any
deteriorations of the useful signal due to its transfer from the loudspeaker 3 to
the microphone 4 representing the listener's ear. It hence compensates for, or linearizes
the disturbing influence of the secondary path S(z) to the useful signal x[n], such
that the useful signal arrives at the listener as provided by the source, without
any negative effect due to acoustical properties of the headphone, i.e., y[z] = x[z].
As such, with the help of such a linearizing filter it is possible to make a poorly
designed headphone sound like an acoustically perfectly adjusted, i.e. linear one.
[0026] In FIG. 5, a system is shown that is based on the system of FIG. 3 and that additionally
includes an equalizing filter 10 connected upstream of the subtractor 8 in order to
filter the useful signal x[n] with the secondary path transfer function S(z).
[0027] The differential equations describing the system illustrated in FIG. 5 are as follows:

[0028] The useful signal transfer characteristic M(z) in the system of FIG. 5 is thus

[0029] From equation (25) it can be seen that the useful signal transfer characteristic
M(z) is identical with the secondary path transfer characteristic S(Z) when the ANC
system is active. When the ANC system is not active, the useful signal transfer characteristic
M(z) is also identical with the secondary path transfer characteristic S(Z). Thus,
the aural impression of the useful signal for a listener at a location close to the
microphone 4 is the same regardless of whether noise reduction is active or not.
[0030] The ANC filter 5 and the equalizing filters 10 and 11 may be fixed filters with constant
transfer characteristics or adaptive filters with controllable transfer characteristics.
In the drawings, the adaptive structure of a filter per se is indicated by an arrow
underlying the respective block and the optionality of the adaptive structure is indicated
by a broken line.
[0031] The system shown in FIG. 5 is, for example, applicable in headphones in which useful
signals, such as music or speech, are reproduced under different conditions in terms
of noise and the listener may appreciate being able to switch off the ANC system,
in particular when no noise is present, without experiencing any audible difference
between the active and non-active state of the ANC system. However, the systems presented
herein are not applicable in headphones only, but also in all other fields in which
occasional noise reduction is desired.
[0032] FIG. 6 illustrates an exemplary earphone with which the present active noise reduction
systems may be used. The earphone may be, together with another identical earphone,
part of a headphone (not shown) and may be acoustically coupled to a listener's ear
12. In the present example, the ear 12 is exposed via primary path 1 to the disturbing
signal d[n], e.g., ambient noise. The earphone comprises a cup-like housing 14 with
an aperture 15 that may be covered by a sound permeable cover, e.g., a grill, a grid
or any other sound permeable structure or material. The loudspeaker 3 radiates sound
to the ear 12 and is arranged at the aperture 15 of the housing 14, both forming an
earphone cavity 13. The cavity 13 may be airtight or vented by any means, e.g., by
means of a port, vent, opening, etc. The microphone 4 is positioned in front of the
loudspeaker 3. An acoustic path 17 extends from the speaker 3 to the ear 12 and has
a transfer characteristic which is approximated for noise control purposes by the
transfer characteristic of the secondary path 2 which extends from the loudspeaker
3 to the microphone 4.
[0033] In mobile devices such as headphones, the space and energy available for the ANC
system is quite limited. Digital circuitry may be too space and energy consuming and
in mobile devices analog circuitry is often the preferred in the design of ANC systems.
However, analog circuitry allows only for a very limited complexity of the ANC system
and thus it is hard to correctly model the secondary path solely by analog means.
In particular, analog filters used in an ANC system are often fixed filters or very
simple adaptive filters because they are easy to build, have low energy consumption
and require little space. The systems illustrated above with reference to FIGS. 4,
5 and 7 also provide good results when employing analog circuitry as there is a minor
(FIG. 4) or even no
[0034] (FIGS. 5 and 7) dependency on the secondary path behavior. Furthermore, the systems
of FIGS. 5 and 7 allow for a good estimation of the necessary transfer characteristic
of the equalization filter based on the ANC filter transfer characteristic W(z), as
well as on the secondary path filter characteristic S(z), both forming the open loop
transfer characteristic W(z)·S(z), which, in principal, has only minor fluctuations,
and based on the assessment of the acoustic properties of the headphone when attached
to a listener's head.
[0035] The ANC filter 5 will usually have a transfer characteristic that tends to have lower
gain at lower frequencies with an increasing gain over frequency to a maximum gain
followed by a decrease of gain over frequency down to loop gain. With high gain of
the ANC filter 5, the loop inherent in the ANC system keeps the system linear in a
frequency range of, e.g., below 1 kHz and thus renders any equalization redundant
in this frequency range. In the frequency range above 3 kHz, the ANC filter 5 has
almost no boosting or cutting effects and, accordingly, no linearization effects.
As the ANC filter gain in this frequency range is approximately loop gain, the useful
signal transfer characteristic M(z) experiences a boost at higher frequencies that
has to be compensated for by means of a respective filter, e.g. a shelving filter,
additional to an equalizing filter. In the frequency range between 1 kHz and 3 kHz
both, boosts and cuts, may occur. In terms of aural impression, boosts are more disturbing
than cuts and thus it may be sufficient to compensate for boosts in the transfer characteristic
by correspondingly designed cut filters. If the ANC filter gain is 0 dB above 3 kHz,
there is no linearization effect and, therefore, in addition to a first equalization
filter and instead a shelving filter, a second equalizing filter may be used.
[0036] As can be seen from the above considerations, at least two filters may be used for
compensation. FIG. 7 shows an exemplary ANC system that employs (at least) two filters
18 and 19 (sub-filters) instead of a single filter 11 as in the system of FIG. 5.
For instance, a treble cut shelving filter (e.g., filter 18) having a transfer characteristic
S
1(z) and a treble cut equalizing filter (e.g., filter 19) having a transfer characteristic
S
2(z), in which S(z) = S
1(z)·S
2(z). Alternatively, a treble boost equalizing filter may be implemented as, e.g.,
filter 18 and a treble cut equalizing filter as, e.g., filter 19. If the useful signal
transfer characteristic M(z) exhibits an even more complex structure, three filters
may be employed, e.g., one treble cut shelving filter and two treble boost/cut equalizing
filters. The number of filters used may depend on many other aspects such as costs,
noise behavior of the filters, acoustic properties of the headphone, delay time of
the system, space available for implementing the system, etc.
[0037] FIG. 8 is a schematic diagram of the transfer characteristics a, b of shelving filters
applicable in the system of FIG. 7. In particular, a first order treble boost (+9
dB) shelving filter (a) and a bass cut (-3 dB) shelving filter (b) are shown. FIG.
9 is a schematic diagram of the transfer characteristics c, d of equalizing filters
applicable in the system of FIG. 7. One (c) of the equalizing filters provides a 9
dB boost at 1 kHz and the other (d) a 6 dB cut at 100 Hz having a higher Q and, thus,
a sharper bandwidth.
[0038] Although the range of spectrum shaping functions is governed by the theory of linear
filters, the adjustment of those functions and the flexibility with which they can
be adjusted varies according to the topology of the circuitry and the requirements
that have to be fulfilled. Shelving filters are usually simple first-order filters
which alter the relative gains between frequencies much higher and much lower than
the corner frequencies. A low or bass shelf is adjusted to affect the gain of lower
frequencies while having no effect well above its corner frequency. A high or treble
shelf adjusts the gain of higher frequencies only. A single equalizer filter, on the
other hand, implements a second-order filter function. This involves three adjustments:
selection of the center frequency, adjustment of the quality (Q) factor, which determines
the sharpness of the bandwidth, and the level or gain which determines how much the
selected center frequency is boosted or cut relative to frequencies (much) above or
below the center frequency.
[0039] FIG. 10 is a combination of the systems shown in FIGS. 4 and 5 in which the useful
signal x[n] is supplied to both, the microphone and the loudspeaker path, each via
a filter 20 having a transfer characteristic S
5(z) or a filter 21 having a transfer characteristic S
6(z), in which, for instance, S(z) = S
5(z)·S
6(z).
[0040] Although various examples of realizing the invention have been disclosed, it will
be apparent to those skilled in the art that various changes and modifications can
be made which will achieve some of the advantages of the invention without departing
from the scope of the invention as defined by the appended claims.
1. A noise reducing sound reproduction system comprising:
a loudspeaker (3)that is connected to a loudspeaker input path;
a microphone (4) that is acoustically coupled to the loudspeaker (3) via a secondary
path (2) and connected to a microphone output path;
a first subtractor (8) that is connected downstream of the microphone output path
and a first useful-signal path;
an active noise reduction filter (5) that is connected downstream of the first subtractor
(8); and
a second subtractor (9) that is connected downstream of the active noise reduction
filter (5), downstream of a second useful-signal path, and upstream of the loudspeaker
input path, wherein:
the secondary path (2) has a secondary path transfer characteristic (S(z));
both useful-signal paths are supplied with a useful signal (x[n]) to be reproduced;
and
at least one of the useful-signal paths comprises one or more spectrum shaping filters
(10, 11, 18, 19, 20), wherein
at least one of the spectrum shaping filters (11) has a transfer characteristic that
models the secondary path transfer characteristic (S(z));
the first useful-signal path comprises the at least one spectrum shaping filter (11)
and the at least one spectrum shaping filter (11) that models the secondary path transfer
characteristic linearizes a microphone signal (y[n]) on the microphone output path
with regard to the useful signal (x[n]) ;
the at least one spectrum shaping filter (11) that models the secondary path transfer
characteristic comprises at least two sub-filters (18, 19); and
one of the sub-filters (18, 19) of the at least one spectrum shaping filter (11) that
models the secondary path transfer characteristic is a treble cut shelving filter.
2. The system of claim 1, in which at least one of the sub-filters (18, 19) of the at
least one spectrum shaping filter (11) that models the secondary path transfer characteristic
is an equalizing filter.
3. The system of one of claims 1 or 2, in which the at least one of the sub-filters (18,
19) of the at least one equalizing filter is a treble cut equalizing filter.
4. The system of one of the claims 1 to 3, in which the second useful-signal path comprises
another spectrum shaping filter (10) that has a transfer characteristic that is identical
with the inverse secondary path transfer characteristic (1/S(z)).
5. The system of one of claims 1-4, in which at least one of the active noise reduction
filter (5), the at least one spectrum shaping filter (11) that models the secondary
path transfer characteristic, and another spectrum shaping filter (10) is an adaptive
filter.
6. A noise reducing sound reproduction method, in which:
an input signal (v[n]) is supplied to a loudspeaker (3) by which it is acoustically
radiated;
the signal radiated by the loudspeaker (3) is received by a microphone (4) that is
acoustically coupled to the loudspeaker (3) via a secondary path (2) that has a secondary
path transfer characteristic (S(z)) and that provides a microphone output signal (y[n]);
the microphone output signal (y[n]) is subtracted from a useful-signal (x[n]) to generate
a filter input signal (u[n]);
the filter input signal (u[n]) is filtered in an active noise reduction filter (5)
to generate an error signal (e[n]); and
the useful signal (x[n]) is subtracted from the error signal (e[n]) to generate the
loudspeaker input signal (v[n]); and
the useful signal (x[n]) is filtered by one or more spectrum shaping filters (10,
11, 18, 19, 20, 21) prior to subtraction from the microphone output signal (y[n]),
wherein
at least one of the spectrum shaping filters (11) has a transfer characteristic that
models the secondary path transfer characteristic (S(z));
the useful signal (x[n]), prior to subtraction from the microphone output signal (y[n]),
is filtered with the transfer characteristic of the at least one spectrum shaping
filter (11) that models the secondary path transfer characteristic, wherein the at
least one spectrum shaping filter (11) that models the secondary path transfer characteristic
linearizes a microphone signal (y[n]) on the microphone output path with regard to
the useful signal (x[n]);
the filtering of the useful signal (x[n]) includes treble cut shelving filtering.
7. The method of claim 6, in which all spectrum shaping filters (10, 11, 18, 19, 20,
21) model in total the secondary path transfer characteristic (S(z)).
8. The method of claim 6 or 7, in which the filtering of the useful signal (x[n]) includes
equalizing.
9. The method of one of claims 6 to 8, in which the useful signal (x[n]), prior to subtraction
from the loudspeaker input signal (v[n]), is filtered with a transfer characteristic
that is identical with the inverse secondary path transfer characteristic(1/S(z)).
1. Geräuschminderndes Tonwiedergabesystem, umfassend:
einen Lautsprecher (3), der mit einem Lautsprechereingangspfad verbunden ist;
ein Mikrofon (4), das akustisch mit dem Lautsprecher (3) über einen sekundären Pfad
(2) gekoppelt ist und mit einem Mikrofonausgangspfad verbunden ist;
einen ersten Subtrahierer (8), der stromabwärts des Mikrofonausgangspfads und eines
ersten Nutzsignalpfads verbunden ist;
einen aktiven Geräuschminderungsfilter (5), der stromabwärts des ersten Subtrahierers
(8) verbunden ist; und
einen zweiten Subtrahierer (9), der stromabwärts des aktiven Geräuschminderungsfilters
(5), stromabwärts eines zweiten Nutzsignalpfads und stromaufwärts des Lautsprechereingangspfads
verbunden ist, wobei:
der sekundäre Pfad (2) eine Sekundärpfadübertragungscharakteristik (S(z)) aufweist;
beide Nutzsignalpfade mit einem Nutzsignal (x[n]), das wiederzugeben ist, versorgt
werden; und
mindestens einer der Nutzsignalpfade einen oder mehrere spektrumsformende(n) Filter
(10, 11, 18, 19, 20) umfasst, wobei mindestens einer der spektrumsformenden Filter
(11) eine Übertragungscharakteristik aufweist, die die Sekundärpfadübertragungscharakteristik
(S(z)) nachbildet;
der erste Nutzsignalpfad den mindestens einen spektrumsformenden Filter (11) umfasst
und der mindestens eine spektrumsformende Filter (11), der die Sekundärpfadübertragungscharakteristik
nachbildet, ein Mikrofonsignal (y[n]) am Mikrofonausgangspfad in Bezug auf das Nutzsignal
(x[n]) linearisiert;
der mindestens eine spektrumsformende Filter (11), der die Sekundärpfadübertragungscharakteristik
nachbildet, mindestens zwei Unterfilter (18, 19) umfasst; und
einer aus den Unterfiltern (18, 19) des mindestens einen spektrumsformenden Filters
(11), der die Sekundärpfadübertragungscharakteristik nachbildet, ein Tiefpass-Kuhschwanzfilter
ist.
2. System nach Anspruch 1, wobei mindestens einer der Unterfilter (18, 19) des mindestens
einen spektrumsformenden Filters (11), der die Sekundärpfadübertragungscharakteristik
nachbildet, ein Entzerrerfilter ist.
3. System nach einem der Ansprüche 1 oder 2, wobei der mindestens eine der Unterfilter
(18, 19) des mindestens einen Entzerrerfilters ein Tiefpass-Entzerrerfilter ist.
4. System nach einem der Ansprüche 1 bis 3, wobei der zweite Nutzsignalpfad einen weiteren
spektrumsformenden Filter (10) umfasst, der eine Übertragungscharakteristik aufweist,
die mit der umgekehrten Sekundärpfadübertragungscharakteristik (1/S(z)) identisch
ist.
5. System nach einem der Ansprüche 1-4, wobei mindestens einer aus dem aktiven Geräuschminderungsfilter
(5), dem mindestens einen spektrumsformenden Filter (11), der die Sekundärpfadübertragungscharakteristik
nachbildet, und dem anderen spektrumsformenden Filter (10) ein adaptiver Filter ist.
6. Verfahren zur geräuschmindernden Tonwiedergabe, wobei:
ein Eingangssignal (v[n]) an einen Lautsprecher (3) geliefert wird, durch den es akustisch
abgestrahlt wird;
das Signal, das von dem Lautsprecher (3) abgestrahlt wird, von einem Mikrofon (4)
empfangen wird, das akustisch mit dem Lautsprecher (3) über einen Sekundärpfad (2)
gekoppelt ist, der eine Sekundärpfadübertragungscharakteristik (S(z)) aufweist und
der ein Mikrofonausgangssignal (y[n]) bereitstellt;
das Mikrofonausgangssignal (y[n]) von einem Nutzsignal (x[n]) subtrahiert wird, um
ein Filtereingangssignal (u[n]) zu erzeugen;
das Filtereingangssignal (u[n]) in einem aktiven Geräuschminderungsfilter (5) gefiltert
wird, um ein Fehlersignal (e[n]) zu erzeugen; und
das Nutzsignal (x[n]) von dem Fehlersignal (e[n]) subtrahiert wird, um das Lautsprechereingangssignal
(v[n]) zu erzeugen; und
das Nutzsignal (x[n]) von einem oder mehreren spektrumsformenden Filtern (10, 11,
18, 19, 20, 21) vor der Subtraktion vom Mikrofonausgangssignal (y[n]) gefiltert wird,
wobei mindestens einer der spektrumsformenden Filter (11) eine Übertragungscharakteristik
aufweist, die die Sekundärpfadübertragungscharakteristik (S(z)) nachbildet;
das Nutzsignal (x[n]) vor der Subtraktion von dem Mikrofonausgangssignal (y[n]) mit
der Übertragungscharakteristik des mindestens einen spektrumsformenden Filters (11),
der die Sekundärpfadübertragungscharakteristik nachbildet, gefiltert wird, wobei der
mindestens eine spektrumsformende Filter (11), der die Sekundärpfadübertragungscharakteristik
nachbildet, ein Mikrofonsignal (y[n]) an dem Mikrofonausgangspfad in Bezug auf das
Nutzsignal (x[n]) linearisiert;
das Filtern des Nutzsignals (x[n]) ein Tiefpass-Kuhschwanzfiltern beinhaltet.
7. Verfahren nach Anspruch 6, wobei alle spektrumsformenden Filter (10, 11, 18, 19, 20,
21) insgesamt die Sekundärpfadübertragungscharakteristik (S(z)) nachbilden.
8. Verfahren nach Anspruch 6 oder 7, wobei das Filtern des Nutzsignals (x[n]) ein Entzerren
beinhaltet.
9. Verfahren nach einem der Ansprüche 6 bis 8, wobei das Nutzsignal (x[n]) vor der Subtraktion
vom Lautsprechereingangssignal (v[n]) mit einer Übertragungscharakteristik gefiltert
wird, die mit der umgekehrten Sekundärpfadübertragungscharakteristik (1/S(z)) identisch
ist.
1. Système de reproduction de son réduisant le bruit comprenant :
un haut-parleur (3) qui est connecté à une voie d'entrée de haut-parleur ;
un microphone (4) qui est couplé acoustiquement au haut-parleur (3) via une voie secondaire
(2) et connecté à une voie de sortie de microphone ;
un premier soustracteur (8) qui est connecté en aval de la voie de sortie de microphone
et d'une première voie de signal utile ;
un filtre de réduction de bruit actif (5) qui est connecté en aval du premier soustracteur
(8) ; et
un second soustracteur (9) qui est connecté en aval du filtre de réduction de bruit
actif (5), en aval d'une seconde voie de signal utile, et en amont de la voie d'entrée
de haut-parleur,
dans lequel :
la voie secondaire (2) a une caractéristique de transfert de voie secondaire (S(z))
;
les deux voies de signal utile sont alimentées avec un signal utile (x[n]) à reproduire
; et
au moins l'une des voies de signal utile comprend un ou plusieurs filtres de conformation
de spectre (10, 11, 18, 19, 20), dans lequel au moins l'un des filtres de conformation
de spectre (11) a une caractéristique de transfert qui modélise la caractéristique
de transfert de voie secondaire (S(z)) ;
la première voie de signal utile comprend l'au moins un filtre de conformation de
spectre (11) et l'au moins un filtre de conformation de spectre (11) qui modélise
la caractéristique de transfert de voie secondaire linéarise un signal de microphone
(y[n]) sur la voie de sortie de microphone concernant le signal utile (x[n]) ;
l'au moins un filtre de conformation de spectre (11) qui modélise la caractéristique
de transfert de voie secondaire comprend au moins deux sous-filtres (18, 19) ; et
l'un des sous-filtres (18, 19) de l'au moins un filtre de conformation de spectre
(11) qui modélise la caractéristique de transfert de voie secondaire est un filtre
de dégradé de réduction des aigus.
2. Système selon la revendication 1, dans lequel au moins l'un des sous-filtres (18,
19) de l'au moins un filtre de conformation de spectre (11) qui modélise la caractéristique
de transfert de voie secondaire est un filtre d'égalisation.
3. Système selon l'une des revendications 1 ou 2, dans lequel l'au moins un des sous-filtres
(18, 19) de l'au moins un filtre d'égalisation est un filtre d'égalisation de réduction
des aigus.
4. Système selon l'une des revendications 1 à 3, dans lequel la seconde voie de signal
utile comprend un autre filtre de conformation de spectre (10) qui a une caractéristique
de transfert qui est identique à la caractéristique de transfert de voie secondaire
inverse (1/S(z)).
5. Système selon l'une des revendications 1 à 4, dans lequel au moins l'un du filtre
de réduction de bruit actif (5), de l'au moins un filtre de conformation de spectre
(11) qui modélise la caractéristique de transfert de voie secondaire, et d'un autre
filtre de conformation de spectre (10) est un filtre adaptatif.
6. Procédé de reproduction de son réduisant le bruit, dans lequel :
un signal d'entrée (v[n]) est délivré à un haut-parleur (3) grâce auquel il est émis
acoustiquement ;
le signal émis par le haut-parleur (3) est reçu par un microphone (4) qui est couplé
acoustiquement au haut-parleur (3) via une voie secondaire (2) qui a une caractéristique
de transfert de voie secondaire (S(z)) et qui fournit un signal de sortie de microphone
(y[n]) ;
le signal de sortie de microphone (y[n]) est soustrait d'un signal utile (x[n]) pour
générer un signal d'entrée de filtre (u[n]) ;
le signal d'entrée de filtre (u[n]) est filtré dans un filtre de réduction de bruit
actif (5) pour générer un signal d'erreur (e[n]) ; et
le signal utile (x[n]) est soustrait du signal d'erreur (e[n]) pour générer le signal
d'entrée de haut-parleur (v[n]) ; et
le signal utile (x[n]) est filtré par un ou plusieurs filtres de conformation de spectre
(10, 11, 18, 19, 20, 21) avant soustraction du signal de sortie de microphone (y[n]),
dans lequel au moins l'un des filtres de conformation de spectre (11) a une caractéristique
de transfert qui modélise la caractéristique de transfert de voie secondaire (S(z))
;
le signal utile (x[n]), avant soustraction du signal de sortie de microphone (y[n]),
est filtré avec la caractéristique de transfert de l'au moins un filtre de conformation
de spectre (11) qui modélise la caractéristique de transfert de voie secondaire, dans
lequel l'au moins un filtre de conformation de spectre (11) qui modélise la caractéristique
de transfert de voie secondaire linéarise un signal de microphone (y[n]) sur la voie
de sortie de microphone concernant le signal utile (x[n]) ;
le filtrage du signal utile (x[n]) comporte un filtrage de dégradé de réduction des
aigus.
7. Procédé selon la revendication 6, dans lequel tous les filtres de conformation de
spectre (10, 11, 18, 19, 20, 21) modélisent en totalité la caractéristique de transfert
de voie secondaire (S(z)).
8. Procédé selon la revendication 6 ou 7, dans lequel le filtrage du signal utile (x[n])
comporte une égalisation.
9. Procédé selon l'une des revendications 6 à 8, dans lequel le signal utile (x[n]),
avant soustraction du signal d'entrée de haut-parleur (v[n]), est filtré avec une
caractéristique de transfert qui est identique à la caractéristique de transfert de
voie secondaire inverse (1/S(z)).