 |
Claims  |
|
|
What is claimed is:
1. An echo canceller which repeats operations of: providing a received
signal onto an echo path to obtain therefrom an echo; generating an echo
replica by applying said received signal to estimated echo path means
formed by a digital adaptive filter having an estimated impulse response
as a filter coefficient; subtracting said echo replica by subtracting
means from said echo and outputting the resulting error signal as an
echo-cancelled or echo-free signal; and estimating said filter coefficient
of said estimated echo path means, as its impulse response, by impulse
response estimating means on the basis of said error signal and said
received signal and iteratively adjusting said filter coefficient by a
recursive least-squares (RLS) algorithm;
wherein said impulse response estimating means includes:
adjustment matrix storage means for storing an adjustment matrix
representing an expectation of an impulse response variation of said echo
path; and
adding means for adding said adjustment matrix to a coefficient error
covariance matrix in said RLS logarithm to generate an adjusted
coefficient error covariance matrix.
2. The echo canceller of claim 1 wherein said impulse response estimating
means includes:
gain vector generating means for generating a gain vector on the basis of
said adjusted coefficient error covariance matrix and the vector of said
received signal;
covariance matrix generating means for generating an updated version of
said coefficient error covariance matrix on the basis of said adjusted
coefficient error covariance matrix and said gain vector;
multiplying means for multiplying said gain vector and said error signal to
generate an adjustment coefficient;
coefficient storage means for storing the current filter coefficient; and
coefficient updating means which adds together said adjustment coefficient
and said current filter coefficient from said coefficient storage means to
generate the next filter coefficient and provides it to said estimated
echo path means and updates said filter coefficient in said coefficient
storage means.
3. The echo canceller of claim 1 or 2 wherein said adjustment matrix is a
diagonal matrix having a diagonal component that attenuates at an
exponential attenuation ratio .gamma..
4. The echo canceller of claim 3 wherein said adjustment matrix is a
diagonal matrix having a diagonal component that attenuates in a stepwise
manner which approximates an attenuation curve attenuating at said
exponential attenuation ratio .gamma., in steps smaller in number than the
number of taps of said estimated echo path means.
5. The echo canceller of claim 2 wherein, letting said received signal be
represented by x(n), said echo by y(n), said adjustment matrix by A, said
error signal by e(n), said filter coefficient indicating the impulse
response of said estimated echo path means by h(n+1), said adjusted
coefficient error covariance matrix by P(n+1) and said gain vector by
k(n), said gain vector generating means is a means for calculating
##EQU7##
said covariance matrix generating means is a means for calculating, as
said updated coefficient error covariance matrix,
.nu..sup.- [ P(n)-k(n).x(n).sub.T.P(n)];
said adding means is a means for calculating, as said adjusted coefficient
error covariance matrix,
P(n+1)=.nu..sup.-1 [P(n)-k(n).x(n).sub.T.P(n)]+A;
said multiplying means calculates the product, e(n)k(n), of said gain
vector k(n) and said error signal e(n) as said adjustment coefficient; and
said coefficient updating means calculates
h(n+1)=h(n)+e(n).k(n),
and provides the calculated output, as said filter coefficient, to said
estimated echo path means, while at the same time updating the contents of
said coefficient storage means,
where
##EQU8##
.alpha..sub.i =.alpha..sub.0 .gamma..sup.i-1 for i=1, 2, . . . L,
L: number of taps of said digital adaptive filter forming said estimated
echo path means,
.gamma.: exponential attenuation ratio of the impulse response variation of
said echo path, where 0<.gamma.<1, and
.nu.: forgetting factor, where 0<.nu..ltoreq.1.
6. The echo canceller of claim 1, 2, or 5 wherein said estimated echo path
means, said impulse response estimating means and said subtracting means
are each provided corresponding to N frequency bands, N being an integer
equal to or greater than 2, said echo canceller further including:
first sub-band analysis means which divides said received signal into
sub-band received signals of said N frequency bands and applies them to
said estimated echo path means and said impulse response estimating means
corresponding thereto, said estimated echo path means of each sub-band
outputting a sub-band echo replica;
second sub-band analysis means which divides said echo into sub-band echoes
of said N frequency bands and applies them to said subtracting means
corresponding thereto, said subtracting means for each frequency band
subtracting said sub-band echo replica from the corresponding sub-band
echo to generate a sub-band error signal and providing it to said impulse
response estimating means for the corresponding frequency band; and
sub-band synthesis means which combines said N sub-band error signals into
a composite signal and outputs it as said echo-cancelled signal.
7. An echo cancelling method which repeats steps of: providing a received
signal onto an echo path to obtain therefrom an echo; generating an echo
replica by applying said received signal to estimated echo path means
formed by a digital adaptive filter having an estimated impulse response
as a filter coefficient; subtracting said echo replica from said echo and
outputting the resulting error signal as an echo-cancelled or echo-free
signal; and estimating said filter coefficient of said echo path means as
its impulse response on the basis of said error signal and said received
signal and iteratively adjusting said estimated filter coefficient by
recursive least-squares (RLS) algorithm;
wherein said impulse response estimating step includes:
a step of storing an adjustment matrix representing an expectation of an
impulse response variation of said echo path;
a step of adding said adjustment matrix to a coefficient error covariance
matrix in said RLS algorithm to generate an adjusted coefficient error
covariance matrix;
a step of generating a gain vector from said adjusted coefficient error
covariance matrix and the vector of said received signal;
a step of generating an updated coefficient error covariance matrix from
said adjusted coefficient error covariance matrix and said gain vector;
a step of multiplying said gain vector and said error signal to generate an
adjustment coefficient;
a step of storing the current filter coefficient; and
a step wherein said adjustment coefficient and said filter coefficient
stored in said coefficient storing step are added together to generate the
next filter coefficient and said next filter coefficient is provided to
said estimated echo path means and is used to update said filter
coefficient in said coefficient storage step.
8. The echo cancelling method of claim 7 wherein, letting said received
signal be represented by x(n), said echo by y(t), said adjustment matrix
by A, said error signal by e(n), said filter coefficient expressing the
impulse response of said estimated echo path means by h(n+1), said
adjusted coefficient error covariance matrix by P(n+1) and said gain
vector by k(n),
said gain vector generating step is a step of calculating
##EQU9##
said covariance matrix generating step is a step of calculating, as said
updated coefficient error covariance matrix,
.nu..sup.- [ P(n)-k(n).x(n).sup.T.P(n)];
said adding means is a step of calculating, as said adjusted coefficient
error covariance matrix,
P(n+1)=.nu..sup.-1 [P(n)-k(n).x(n).sup.T.P(n)]+A;
said multiplying step is a step of calculates the product, e(n)k(n), of
said gain vector k(n) and said error signal e(n) as said adjustment
coefficient; and
said coefficient updating step is a step of calculating
h(n+1)=h(n)+e(n).k(n),
and providing the calculated output, as said filter coefficient, to said
estimated echo path means, while at the same time updating said
coefficient stored in said coefficient storage step,
where
##EQU10##
.alpha..sub.i =.alpha..sub.0 .gamma..sup.i-1 for i=1, 2, . . . , L,
L: number of taps of said digital adaptive filter forming said estimated
echo path means,
.gamma.: exponential attenuation ratio of the impulse response variation of
said echo path, where 0<.gamma.<1, and
.nu.: forgetting factor, where 0<.nu..ltoreq.1. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
BACKGROUND OF THE INVENTION
The present invention relates to an echo cancelling method and an echo
canceller for cancelling echoes that cause howling and interfere with
conversation in a teleconferencing system, a hands-free audio terminal and
other similar hands-free telecommunication systems.
As satellite communication and audio teleconferencing have now come into
wide use, there is a strong demand for the implementation of a
telecommunication system which gives excellent simultaneous conversation
performance and efficiently suppresses acoustic feedback. To meet this
requirement, there have been proposed echo cancellers. In FIG. 1 there is
shown, as being applied to hands-free telecommunication, a conventional
echo canceller disclosed in Japanese Patent Application Laid-Open No.
220530/89. In a telecommunication system composed of a receiving system
from a receive input terminal 1 for a received signal x(t) to a
loudspeaker 2 and a sending system from a microphone 3 to a send out
terminal 4, the received signal x(t) is sampled by an analog-to-digital
(A/D) converting part 5, and the thus sampled received signal x(n) is
provided onto an estimated echo path 6, from which an echo replica y (n)
is output. 0n the other hand, an echo y(t) input into the microphone 3 is
sampled by an A/D converting part 7 and the thus sampled echo y(n) is
provided to a subtracting part 8, wherein the above-mentioned echo replica
y(n) is subtracted from the sampled echo y(n), thereby cancelling the echo
y(n) which would otherwise be fed to the send out terminal 4.
The estimated echo path 6 needs to follow up temporal variations of the
echo path Pe from the loudspeaker 2 to the microphone 3. The estimated
echo path 6 is formed by a digital finite impulse response (FIR) filter,
for example, and the filter coefficient is iteratively adjusted by an
estimating part 9 using a least-mean-squares (LMS) algorithm, a normalized
LMS (NLMS) algorithm, an ES algorithm, or a recursive least-squares (RLS)
algorithm so that an error, e(n)=y(n)-y(n), which is the output from the
subtracting part 8, may approach zero. With such adjustment of the
estimated echo path 6, optimum echo cancellation takes place at all times.
The echo-cancelled send out signal from the microphone 3 is converted by a
digital-to-analog (D/A) converting part 10 into analog form, thereafter
being fed to the send out terminal 4.
Next, a description will be given of conventional filter coefficient
adjustment schemes. Gradient type adaptive algorithms, such as the LMS
algorithm and the NLMS algorithm, are expressed, in general, as follows:
h(n+1)=h(n)+.alpha.[-.DELTA.(n)] (1)
where
h(n)=(h.sub.1 (n), h.sub.2 (n), . . . , h.sub.L (n)).sup.T : estimated echo
path (FIR filter) coefficient,
.DELTA.(n): (mean) squared error gradient vector,
.alpha.: step size (scalar quantity),
L: number of taps,
T: vector transpose,
n: discrete time.
In the LMS algorithm the gradient vector of the mean squared error is
expressed by
.DELTA.(n)=-e(n).x(n),
and in the NLMS algorithm it is expressed by
##EQU1##
where e(n): error (=y(n)-y(n)),
y(n)=h(n).sup.T.x(n),
x(n)=(x(n), x(n-1), . . . , x(n-L+1)).sup.T : received signal vector.
The ES algorithm is one in which the step size .alpha., conventionally
given as a scalar quantity in Eq. (1), is extended to a diagonal matrix
referred to as a step size matrix A. The ES algorithm is expressed by the
following equation:
h(n+1)=h(n)+A[-.DELTA.(n)] (2)
where
##EQU2##
.alpha..sub.i =.alpha..sub.0 .gamma..sup.i-1 (i=1, 2, . . . , L),
.gamma.: exponential attenuation ratio of an impulse response variation of
the acoustic echo path (0<.gamma.<1).
Where the estimated echo path 6 is formed by a digital FIR filter, its
filter coefficient h(n) is a directly simulated version of a room impulse
response h(n). Hence, the magnitude of adjustment of the filter
coefficient that is needed for each variation of the echo path is the same
as the room impulse response variation. The step size matrix A, which
represents the quantity of adjustment in the filter coefficient adjustment
operation, is weighted by a temporal variation characteristic of the
impulse response. In general, the variation in the room impulse response
is expressed as an exponential function using the attenuation ratio
.gamma.. The diagonal component .alpha..sub.i (i=1, 2, . . . , L) of the
step size matrix A attenuates exponentially from .alpha..sub.0 and
gradually approaches 0 as i increases, with the same slope or gradient as
that of the exponential attenuation characteristic of the impulse
response, as shown in FIG. 2.
The step size matrix A that represents the attenuation of the room impulse
response is disclosed in, for example, U.S. patent application Ser. No.
07/756,622, now Makino et al U.S. Pat. No. 5,272,695, by the inventors of
this application. This algorithm is based on an acoustic finding that when
the impulse response is varied by movement of a man or object, the
variation (the difference in the impulse response) attenuates
exponentially at the same attenuation ratio as that of the impulse
response. By adjusting coefficients in an early stage of the impulse
response of great variation with large steps and coefficients in a late
stage of the impulse response of little variation with small steps, it is
possible to obtain an echo canceller of high convergence speed.
By applying the ES algorithm to the NLMS algorithm, the estimated echo path
6 is iteratively adjusted following Eq. (3) given below, with the result
that the impulse response h(n) of the estimated echo path 6 approaches the
impulse response h(n) of the true echo path Pe.
##EQU3##
On the other hand, the RLS algorithm is well-known as an adaptive algorithm
of fast convergence. The RLS algorithm is introduced in detail in a
chapter entitled "Standard Recursive Least-Squares Estimation" in a
textbook "ADAPTIVE FILTER THEORY" by SIMON HAYKIN (Prentice-Hall), for
instance, and it is a significant feature of this algorithm that about the
same convergence speed as that for a white noise is provided for a colored
signal as well. The iterative adjustment equation of the impulse response
h(n) by the RLS algorithm is expressed as follows:
##EQU4##
where k(n): L-th order gain vector,
P(n): L.times.L coefficient error covariance matrix,
.nu.: forgetting factor (0<.nu..ltoreq.1).
The matrix P(n) is defined as an inverse matrix of the covariance matrix of
the input signal and when the impulse response is time-invariant and
expressed as h.sub.0, it can be regarded as a covariance matrix of
coefficient errors as given below.
P(n)=E[{h.sub.0 -h(n)}{h.sub.0 -h(n)}.sup.T ] (7)
where E[.] is statistical expectation. These equations (4) through (7) use
different symbols but are essentially the same as those given in the
aforementioned Simon Haykin's textbook.
FIG. 3 shows an example of the configuration of the estimating part 9 in
FIG. 1 that uses the RLS algorithm involving Eqs. (4) through (7).
The received signal x(n) is fed to a received signal memory part 11,
wherein it is rendered into a received signal vector x(n). The received
signal vector x(n), the coefficient error covariance matrix P(n) from a
coefficient error covariance matrix memory part 12 and the forgetting
factor .nu. from a forgetting factor memory part 13 are provided to a gain
calculating part 14, wherein the calculation of Eq. (5) is conducted. The
thus obtained gain vector k(n) is stored in a gain memory part 15. The
gain vector k(n) and the error e(n) are provided to a multiplying part 16,
wherein the second term on the right-hand side of Eq. (4) is calculated.
The calculated output is supplied to an adding part 17, wherein it is
added to the filter coefficient h(n) from the tap coefficient memory part
18 to obtain h(n+1). The calculated value h(n+1) is provided onto the
estimated echo path 6 in FIG. 1, while at the same time it is provided to
the tap coefficient memory part 18 to update its stored contents.
The coefficient error covariance matrix P(n) from the coefficient error
covariance matrix memory part 12, the gain vector k(n) from the gain
memory part 15, the received signal vector x(n) from the received signal
memory part 11 and the forgetting factor .nu. from the forgetting factor
memory part 13 are provided to an updating part 19, wherein the
calculation of Eq. (6) is conducted to update the value P(n) stored in the
coefficient error covariance matrix memory part 12.
Through the processings described above, the impulse response h(n+1) which
is provided as a filter coefficient onto the estimated echo path 6 in FIG.
1 is iteratively adjusted, and thus the impulse response h(n+1) of the
estimated echo path 6 approaches the impulse response h(n+1) of the true
echo path Pe.
When the input is a white noise, the RLS algorithm converges at about the
same speed as the NLMS algorithm, and hence has a disadvantage that the
convergence speed is slow.
SUMMARY OF THE INVENTION
It is therefore an object of the present invention to provide an echo
cancelling method and an echo canceller which permit fast convergence for
a white noise as well as for a speech signal.
According to the present invention, an adjustment matrix A which represents
expected values of the impulse response variation is added to the
coefficient error covariance matrix P(n) contained in the RLS algorithm to
thereby reflect the impulse response variation characteristics of the
acoustic echo path on the RLS algorithm.
With such a configuration, it is possible to obtain an echo canceller which
has a convergence speed twice as fast as that of the conventional echo
canceller employing the RLS algorithm.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a block diagram showing a conventional echo canceller;
FIG. 2 is a graph showing a diagonal component .alpha..sub.i of the
adjustment matrix A;
FIG. 3 is a block diagram illustrating the internal configuration of an
estimating part 9 in FIG. 1;
FIG. 4 is a block diagram illustrating the configuration of the estimating
part 9 that forms the principal part of an embodiment of the present
invention;
FIG. 5 is a simulation graph showing the relationship between the
convergence characteristic of echo return loss enhancement (ERLE) and a
mean value .alpha./R of the diagonal components according to the present
invention;
FIG. 6A is a graph showing the results of simulation of the convergence by
the present invention and the prior art when the input signal is a white
noise;
FIG. 6B is a graph showing the results of simulation of the convergence by
the present invention and the prior art when the input signal is a speech
signal;
FIG. 7 is a block diagram illustrating an embodiment of the present
invention which employs a sub-band scheme; and
FIG. 8 is a graph showing an example of a stepwise approximation of the
diagonal component .alpha..sub.i of the adjustment matrix A.
DESCRIPTION OF THE PREFERRED EMBODIMENT
As described later, the echo canceller of the present invention differs
from the prior art example of FIG. 1 only in the internal configuration of
the estimating part 9 and has the same fundamental functional blocks as
those shown in FIG. 1; hence, the present invention will also be described
in conjunction with FIG. 1.
As described previously, the received signal x(t) at the terminal 1 is
converted by the loudspeaker 2 into an acoustic signal, which is provided
onto an echo path Pe having an impulse response h(t) and then converted by
the microphone 3 into an echo y(t). The echo y(t) is converted by the A/D
converting part 7 into a sampled echo y(n). On the other hand, the
received signal x(t) is converted by the A/D converting part 5 into a
sampled signal x(n), which is provided onto the estimated echo path 6
formed by a digital adaptive filter which performs a convolutional
processing, such as an FIR filter, while at the same time it is applied to
the estimating part 9. An echo replica y(n), which is the output from the
estimated echo path 6, is provided to the subtracting part 8, wherein it
is subtracted from the echo y(n). An error e(n), which is the output from
the subtracting part 8 and provided to the estimating part 9, is converted
by the D/A converting part 10 to an electrical signal e(t), which is
provided to the terminal 4. The estimating part 9 estimates the impulse
response of the echo path on the basis of the error e(n) and the received
signal x(n) and uses the estimated impulse response as a filter
coefficient to control the characteristic of the digital adaptive filter
that forms the estimated echo path 6.
Next, a description will be given of the principle of operation of the
estimating part 9 which is characteristic of the present invention.
As referred to previously, the coefficient error covariance matrix P(n)
used in Eqs. (5) and (6) in the RLS algorithm can be regarded as
statistical expectation that is expressed as follows:
P(n)=E[{h.sub.0 -h(n)}{h.sub.0 -h(n)}.sup.T ]. (8)
Since the impulse response variation of the echo path Pe attenuates
exponentially at the same attenuation ratio as that of the impulse
response, it is desirable that the diagonal component of the coefficient
error covariance matrix P(n) also attenuate exponentially at the same
attenuation ratio as that of the impulse response. To impart such a
characteristic to the matrix P(n), the filter coefficient is adjusted with
the following algorithm added with the adjustment matrix A (a diagonal
matrix) representing the expectation of the impulse response variation.
##EQU5##
.alpha..sub.i =.alpha..sub.0 .gamma..sup.i-1 (i=1, 2, . . . , L)(12)
.gamma.: exponential attenuation ratio of the impulse response variation of
the echo path (0<.gamma.<1).
The forgetting factor .nu. may be set to 1. Eqs. (9), (10) and (11) show
the algorithm of the present invention. Eqs. (9) and (10) are identical
with Eqs. (4) and (5) of the RLS algorithm but Eq. (11) differs from Eq.
(6) in that the former is added with the adjustment matrix A. The method
of the present invention based on Eqs. (9), (10) and (11) will hereinafter
be referred to as an ES-RLS algorithm. Incidentally, when A=0, the
algorithm of the present invention agrees with the conventional RLS
algorithm.
FIG. 4 illustrates an example of the internal configuration of the
estimating part 9 which is the principal part of the present invention,
the parts corresponding to those in FIG. 3 being identified by the same
reference numerals.
The received signal x(n) is rendered into a received signal vector x(n) in
the received signal memory part 11. The received signal vector x(n), the
coefficient error covariance matrix P(n) from the coefficient error
covariance matrix memory part 12 and the forgetting factor .nu. from the
forgetting factor memory part 13 are supplied to the gain calculating part
14, in which the calculation of Eq. (10) is performed to obtain a gain
vector k(n), which is stored in the gain memory part 15. The gain vector
k(n) and the error e(n) from the subtracting part 8 are provided to the
multiplying part 16, wherein the second term on the right-hand side of Eq.
(9) is calculated. The calculated output is provided to the adding part
17, wherein it is added to the filter coefficient, h(n), of the estimated
echo path 6 from the tap coefficient memory part 18 to obtain h(n+1). The
result of calculation, h(n+1), is provided to the estimated echo path 6 in
FIG. 1, while at the same time it is provided to the tap coefficient
memory part 18 to update its stored value.
The coefficient error covariance matrix P(n) from the coefficient error
covariance matrix memory part 12, the gain vector k(n) from the gain
memory part 15, the received signal vector from the gain memory part 15,
the received signal vector x(n) from the received signal memory part 11
and the forgetting factor .nu. from the forgetting factor memory part 13
are provided to the updating part 19, wherein the first term on the
right-hand side of Eq. (11) is calculated.
In an adjustment generating part 21 there is prestored the adjustment
matrix A (a diagonal matrix) which is precalculated. The output from the
updating part 19 and the adjustment matrix A from the adjustment matrix
generating part 21 are fed to an adding part 22, wherein Eq. (11) is
calculated to update the value of the coefficient error covariance matrix
memory part 12.
In the case where the estimated echo path 6 in FIG. 1 is formed by a
digital FIR filter, its filter coefficient h(n) is a directly simulated
version of the impulse response h(n) of the echo path Pe. Hence, the
coefficient error immediately after the variation of the echo path Pe
coincides with the variation of the impulse response h(n). Then, by adding
the diagonal component of the coefficient error covariance matrix P(n)
with the adjustment matrix A (a diagonal matrix) representing the
expectation of the impulse response variation, it is possible to reflect
the impulse response variation characteristic of the echo path. In
general, the room impulse response variation is expressed as an
exponential function using the attenuation ratio .gamma.. The diagonal
component .alpha..sub.i (i=1, 2, . . . , L) of the adjustment matrix A
attenuates exponentially from .alpha..sub.0 and gradually approaches 0 as
i increases, with the same slope or gradient as that of the exponential
attenuation characteristic of the impulse response, as shown in FIG. 2.
Through the above-described processing the estimated echo path 6 in FIG. 1
is iteratively adjusted and its impulse response h(n) approaches the
impulse response h(n) of the true echo path.
The adjustment matrix A is the same as the step size matrix in Eq. (2)
according to the ES algorithm and can be determined in the following
fashion as described in the aforementioned Makino et al U.S. patent.
At first, a proper initial value, for example, .alpha..sub.i =1 (i=1, 2, .
. . , L), is given to the adjustment matrix A and, for example, a white
noise is applied as the received signal x(t) to the terminal 1 (FIG. 1) to
obtain the echo y(t) in the microphone 3. On the basis of these signals
the echo replica y(n) and the error e(n) are obtained, and the error and
the received signal are used to obtain the impulse response h of the
estimated echo path 6. By repeating these operations an adaptive operation
is conducted to minimize the error e(n), converging the impulse response h
of the estimated echo path 6 on the impulse response h of the true echo
path. As described previously with respect to the prior art shown in FIGS.
1 through 3, since the variation of the impulse response h of the echo
path Pe attenuates at the same exponential attenuation ratio as that of
the impulse response itself, the attenuation ratio .gamma. of the impulse
response h thus estimated is obtained as the exponential attenuation ratio
.gamma. of the variation of the impulse response h of the echo path Pe.
The exponential attenuation ratio .gamma. could be derived from the
impulse response h by approximately solving an equation composed of L
equalities that are obtainable by substituting values of respective
components h.sub.1, h.sub.2, . . . , h.sub.L of the impulse response h
into the following equation:
.vertline.h.sub.i .vertline.=.vertline.h.sub.0 .gamma..sup.i-1.
Alternatively, the above equation is transformed into the following linear
equation concerning i, in which the ratio .gamma. could be derived from
its gradient .gamma..
log.vertline.h.sub.i .vertline.=log.vertline.h.sub.0
.vertline.+(i-1)log.gamma.
The exponential attenuation ratio is determined in the adjustment matrix
generating part 21. The adjustment matrix A thus determined need not be
updated unless the sound field (a conference room, for instance) is
changed to a different one.
The exponential attenuation ratio .gamma. thus determined corresponding to
the attenuation ratio of the room impulse response is substituted into Eq.
(12) to calculate the diagonal component .alpha..sub.i. In this instance,
however, the diagonal component .alpha..sub.i is selected so that the mean
value .alpha. or the diagonal component .alpha..sub.i, for example, may be
a desired value. To this end, in the FIG. 4 embodiment a matrix A/R is
used in place of the adjustment matrix A; that is, the mean value of the
diagonal component is expressed by .alpha./R and a desired convergence
characteristic is obtained by properly changing R.
FIG. 5 shows the results of computer simulation of the convergence
characteristic of the echo return loss enhancement (ERLE) in the cases
where the above-said mean value .alpha./R is 10.sup.-4, 10.sup.-5 and
10.sup.-6. The received signal x(t) is a white noise, the number of taps L
is 64 and the impulse response is changed at time n=1000. As depicted in
FIG. 5, an increase in the mean value .alpha./R increases the convergence
speed but decreases the steady-state echo return loss enhancement. Hence,
taking into account the tradeoff between the steady-state echo return loss
enhancement and the convergence speed, for example, when room or ambient
steady-state noise is large, R is selected large to increase the
steady-state echo return loss enhancement.
In FIGS. 6A and 6B, computer simulation results on ERLE convergence
characteristics of the echo canceller using the ES-RLS algorithm according
to the present invention are shown in comparison with similar computer
simulation results on the conventional echo canceller using the RLS
algorithm. The simulations used an exponentially attenuating impulse
response (64 taps) created by the computer. The received signals used were
a white noise and a speech signal and a near-end or ambient noise was
added to the echo to provide a steady-state ERLE of 30 dB. The impulse
response was changed at time n=1000. The convergence curves shown are each
a mean value of 50 trials. To give a steady-state ERLE of 30 dB or so, the
forgetting factor .nu. of the RLS algorithm and the mean value .alpha./R
of the diagonal component of the adjustment matrix A according to the
present invention are set as follows:
##EQU6##
It will be seen that when the input signal is a white noise (FIG. 6A) the
convergence speeds by the ES-RLS algorithm according to the present
invention at which echo return loss enhancements (ERLE) of 10 dB and 20 dB
are reached are about 2.6 times and about 2.2 times faster than the
convergence speeds by the conventional RLS algorithm, and that when the
input signal is a speech signal (FIG. 6B) the convergence speeds by the
ES-RLS algorithm at which the echo return loss enhancements (ERLE) of 10
dB and 20 dB are reached are about 3.4 times and 1.7 times faster than the
convergence speeds by the RLS algorithm.
The sub-band scheme disclosed in the aforementioned Makino et al U.S.
patent may also be applied to the present invention shown in FIG. 4. As
depicted in FIG. 7, the received signal x(t) is divided by a sub-band
analysis part 25 into N frequency bands to generate sub-sampled received
signals x.sub.1 (n) through x.sub.N (n.sub.). Similarly, the echo replica
y(t) is also divided by a sub-band analysis part 26 into N frequency bands
to generate sub-sampled echo replicas y.sub.1 (n) through y.sub.N (n).
Estimated echo paths 6.sub.1 through 6.sub.N and estimating parts 9.sub.1
through 9.sub.N, which are identical in configuration to the estimated
echo path 6 in FIG. 1 and the estimating part 9 in FIG. 4, respectively,
are provided for the respective sub-bands. The estimating parts 9.sub.1
through 9.sub.N predetermined adjustment matrixes A.sub.1 to A.sub.N of
the respective sub-bands in the same manner as described previously in
connection with FIG. 4 and use them to calculate impulse responses h.sub.1
through h.sub.N, which are fed as filter coefficients to the corresponding
estimated echo paths 6.sub.1 to 6.sub.N, respectively. The echo replicas
y.sub.1 (n) through y.sub.N (n), which are outputs from the estimated echo
paths, are provided to subtracting parts 8.sub.1 through 8.sub.N, wherein
they are subtracted from the echoes y.sub.1 (n) through y.sub.N (n) to
obtain errors e.sub.1 (n) through e.sub.N (n), which are provided to the
corresponding estimating parts 9.sub.1 through 9.sub.N, while at the same
time the errors are synthesized in a sub-band synthesis part 27, the
output of which is provided to the terminal 4 after being converted to
analog form. Thus, the application of the sub-band scheme to the present
invention permits reduction of the computational quantity involved.
In each of the embodiments described above, the exponential attenuation
curve of the diagonal component .alpha..sub.i can also be approximated
with steps smaller in number than the number of taps L as shown in FIG. 8.
This also permits reduction of the computational quantity and storage
capacity needed. While the present invention has been described in
connection with the case where the room impulse response variation has an
exponential attenuation characteristic, the invention is also applicable
in the cases of other arbitrary variation characteristics. Moreover, the
digital adaptive filter has been described to be an FIR filter, but it may
also replaced with other arbitrary digital adaptive filters.
As described above, according to the present invention, the adjustment
matrix A (a diagonal matrix), which represents the expectation of the
impulse response variation of the echo path, is added to the coefficient
error covariance matrix P(n) to thereby reflect the variation
characteristic of the impulse response of the acoustic echo path on the
conventional RLS algorithm--this makes it possible to obtain an echo
canceller that converges about twice as fast as the conventional echo
canceller using the RLS algorithm. In the hands-free telecommunication
system the echo path frequently varies owing to movements of persons, for
instance, and a quick response to such a variation improves the speech
quality accordingly.
It will be apparent that many modifications and variations may be effected
without departing from the scope of the novel concepts of the present
invention.
* * * * *
|
|
|
|
|
|
|
Description |
|
