Title of Invention

EFFICIENT FILTERING WITH A COMPLEX MODULATED FILTERBANK

Abstract A filter apparatus for filtering a time domain input signal to obtain a time domain output signal, which is a representation of the time domain input signal filtered using a filter characteristic having an non-uniform amplitude/frequency characteristic, comprises a complex analysis filter bank for generating a plurality of complex subband signals from the time domain input signals, a plurality of intermediate filters, wherein at least one of the intermediate filters of the plurality of the intermediate filters has a non-uniform amplitude/frequency characteristic, wherein the plurality of intermediate filters have a shorter impulse response compared to an impulse response of a filter having the filter characteristic, and wherein the non-uniform amplitude/frequency characteristics of the plurality of intermediate filters together represent the non-uniform filter characteristic, and a complex synthesis filter bank for synthesizing the output of the intermediate filters to obtain the time domain output signal.
Full Text EFFICIENT FILTERING WITH A COMPLEX MODULATED FILTERBANK
TECHNICAL FIELD
The present invention relates to a filter apparatus and a
method for filtering a time domain input signal, a filter
generator and a method for generating an intermediate
filter definition signal, especially for the field of
encoding, decoding, manipulating and filtering of audio
signals, e.g. in the field of HRTF (head related transfer
function).
BACKGROUND OF THE INVENTION
It has been shown in [P. Ekstrand, "Bandwidth extension of
audio signals by spectral band replication", Proc. 1st IEEE
Benelux Workshop on Model based Processing and Coding of
Audio (MPCA-2002), pp. 53-58, Leuven, Belgium, 2002], that
a complex-exponential modulated filter bank is an
excellent tool for spectral envelope adjustment of audio
signals. One application of this feature is audio coding
based on Spectral Band Replication (SBR). Other fruitful
applications of a complex filter bank include frequency
selective panning and spatialization for parametric
stereo, see [E. Schuijers, J. Breebart, H. Purnhagen, J.
Engdegard: "Low complexity parametric stereo coding",
Proc. 116th AES convention, 2004, paper 6073] and
parametric multichannel coding, see [J. Herre et al.: "The
reference model architecture for MPEG spatial audio
coding", Proc. 118th AES convention, 2005, paper 6447]. In
those applications the frequency resolution of the complex
filter bank is further enhanced at low frequencies by
means of sub-subband filtering. The combined hybrid filter
bank hereby achieves a frequency resolution that enables
the processing of spatial cues at a spectral resolution

which closely follows the spectral resolution of the
binaural auditory system.
In some applications, however, the resolution of the
filter bank is still insufficient, in the sense that
simple gain modifications in each subband do not suffice
to truthfully model the action of a given filter. For
binaural rendering of multi-channel audio by means of HRTF
(head related transfer function) related filtering, the
intricate phase characteristics of the filters are
important for the perceived audio quality. It is of course
possible to apply fast convolution methods based on the
DFT (Discrete Fourier Transform) as a post-process to the
multi-channel rendering, but if the rendering device
already contains the signals in the subband domain of
complex exponential modulated filter bank, there are
significant advantages in terms of computational
complexity and algorithmic integration in performing the
HRTF derived filtering in the subband domain, which will
be outlined in more detail later. Since HRTF's are
different for each individual and the derived filters
depend on virtual source and/or listener positions which
can for instance be changed by control signals, user
interfaces or by other description signals, it is also
important to be able to efficiently convert a given HRTF
related filter into subband domain filters.
It is therefore the object of the present invention to
provide a filter apparatus for filtering a time domain
input signal, a method for filtering a time domain input
signal, a filter generator or a method for providing an
intermediate filter definition signal, which allow a more
efficient or a more flexible manipulation of a time domain
input signal with a better quality.
This object is achieved by a filter apparatus according to
claim 1, by a method for filtering a time domain input
signal according to claim 41, a filter generator according

to claim 25, a method for providing an intermediate filter
definition according to claim 42, a system according to
claim 40 or by a computer program according to claim 43.
SUMMARY OF THE INVENTION
An embodiment of the present invention relates to a filter
apparatus for filtering a time domain input signal to
obtain a time domain output signal, which is a
representation of the time domain input signal filtered
using a filter characteristic having a non-uniform
amplitude/frequency characteristic comprising a complex
analysis filter bank for generating a plurality of complex
subband signals from the time domain input signal, a
plurality of intermediate filters, wherein one intermediate
filter is provided for each complex subband signal, wherein
at least one of the intermediate filters of the plurality
of intermediate filters has a non-uniform
amplitude/frequency characteristic, wherein the plurality
of intermediate filters have a shorter impulse response
compared to an impulse response of a filter having the
filter characteristic, and wherein the non-uniform
amplitude/frequency characteristic of the plurality of
intermediate filters together represent the non-uniform
filter characteristic, and a complex synthesis filter bank
for synthesizing the output of the intermediate filters to
obtain the time domain output signal.
As a second aspect, a further embodiment of the present
invention is a filter generator for providing an
intermediate filter definition signal comprising a complex
modulated filter bank for filtering an impulse response
signal indicative of an amplitude/frequency filter
characteristic in a time domain to obtain a plurality of
complex valued subband signals as the intermediate filter
definition signal, wherein each complex valued subband
signal of the complex modulated filter bank corresponds to
an impulse response for an intermediate filter for a

subband signal, wherein at least one of the complex valued
subband signals comprises at least two different non-
vanishing values, and wherein each complex valued subband
signal is shorter than the impulse response signal.
Embodiments of the first aspect of the present invention
are based on the finding that a more efficient and/or a
more flexible filtering (or manipulation)of a time domain
input signal can be achieved in the subband domain, which
is sometimes also referred to as QMF domain (quadrature
mirror filter), with a better quality compared to other
manipulation schemes. The gain with respect to efficiency,
especially computational efficiency, is a consequence of
the shorter impulse responses of the intermediate filters
compared to the impulse response of a filter having the
non-uniform filter characteristic in the time domain and
the fact that the subband signals can be processed
independently from one another. Due to the shorter impulse
responses an embodiment of a filter apparatus can process
each complex subband signals output by the complex analysis
filter bank individually. Hence, the filtering can be
carried out parallely, which speeds up the processing of
the time domain input signal dramatically compared to
manipulating the time domain input signal directly due to
the shorter impulse responses.
Embodiments according the first aspect of the present
invention are especially favorable when it comes to
balancing computational efficiency on the one hand and
quality on the other hand. While a direct processing of the
time domain input signal in the time domain can be achieved
by a convolution with the impulse response of a filter
having the non-uniform amplitude/frequency characteristic,
which usually leads to a very good quality, the convolution
requires a high computational effort because of the length
of the impulse response of the filter in the time domain.

On the other hand, transforming an audio signal into the
frequency domain by performing a Fourier transformation
represents the tremendous drawback that other
manipulations, which are necessary in modern acoustical
systems, cannot be efficiently performed in the Fourier
domain with a high quality.
Hence, by employing a plurality of intermediate filters,
each having a shorter impulse response compared to an
impulse response of a filter having the filter
characteristic of a corresponding filter in the time
domain, of which at least one has an impulse response with
at least two non-vanishing values represents a highly
favorable compromise between computational efficiency on
the one hand and quality on the other hand. As a
consequence, embodiments of inventive filter apparatuses
represent an excellent compromise between a direct
processing of the time domain input signal for instance by
means of convoluting the time domain input signal with the
longer impulse response indicative of the non-uniform
filter characteristic, which leads to an enormous
computational effort, and employing a Fourier transform,
which leads to more problems in the further course of
processing the signals.
The advantages of the embodiments of the first aspect of
the present invention unfold especially in the context of
FIR-filters (final impulse response), as each of the
intermediate filters of the plurality of intermediate
filters has a significantly shorter impulse response
compared to the impulse response of the FIR-filter in the
time domain. Hence, by parallely processing the different
subband signals output by the complex analysis filter bank
the computational efficiency can drastically be improved.
This aspect is especially important in the field of filters
having long impulse responses. One field of application, in
which filters with very long impulse responses frequently
occur, are HRTF-related applications (HRTF = head related

transfer function), like for instance down-mixing multiple
channel audio signals for feeding to headphones, other
head-related speaker systems or stereo sound systems.
In many concrete applications the computational efficiency
is even more increased, as the audio signals are already
present in the (complex) subband or QMF domain. Hence, in
many concrete implementations, the complex analysis filter
bank and the complex synthesis filter bank for generating
the plurality of complex subband signals from the time
domain input signal and for synthesizing the time domain
output signal are already present.
With respect to the second aspect, embodiments of the
present invention are based on the finding that a more
flexible and more efficient filtering of the time domain
input signal with a better quality can be achieved by
providing an intermediate filter definition signal, which
can for instance be provided to a filter apparatus
according to the first aspect to define its intermediate
filters.
A significant advantage of embodiments according to the
second aspect of the present invention is that an
intermediate filter definition signal for a set of
intermediate filters is obtained by providing an embodiment
of the inventive filter generator with a filter defining
signal, such as an impulse response signal indicative of an
amplitude/frequency filter characteristic of a filter in
the time domain or other filter definition signals. Hence,
an embodiment of a filter generator provides a filter
definition signal for a set of intermediate filters to
effectively the same filtering as a filter in the time
domain defined by the filter definition signal virtually
without introducing aliasing effects. As a consequence,
embodiments of an inventive filter generator enable a
virtually alias free performance of an arbitrary filter in
the subband domain. By utilizing an embodiment of the

inventive filter generator arbitrary filter characteristics
can be transferred from the time domain to the subband
signal domain, like virtually alias free equalization, low-
pass filter characteristics, high-pass filter
characteristics, band-pass filter characteristics, band-
rejection filter characteristics, resonance filter
characteristics, notch filter characteristics or more
complex filter characteristics. Among the more complex
filter characteristics, a combination of several
characteristics as well as HRTF-related filter
characteristics are important to mention.
Especially in the context of HRTF-related applications in
the field of multi-channel audio systems and other high
quality applications it is important to note that
embodiments of the inventive filter generator enable to
truthfully model an action of a given filter in the time
domain in the subband domain. The virtually alias free
performance, which is especially important in HRTF-related
applications, is made possible as the phase characteristics
of a filter in the time domain is (almost) perfectly
transferred into the subband domain. Examples illustrating
this will be outlined in the further course of the present
application.
Among the advantages of embodiments of the second aspect of
the present invention is especially the significant gain
with respect to the achievable computational efficiency.
The complex modulated filter banks of embodiments of the
inventive filter generator produce a plurality of complex
valued subband signals as the intermediate filter
definition signal, wherein each of the complex valued
subband signal is shorter than the impulse response signal
indicative of the amplitude/frequency filter characteristic
in the time domain. The filter generator, hence, produces
an intermediate filter definition signal comprising the
output of the complex modulated filter bank with its
plurality of short complex valued subband signals, which

does not only enable a fast, efficient and parallel
computation with respect to filtering a time domain input
signal to obtain a time domain output signal in the frame
work of an embodiment of a filter apparatus, but does also
enable a fast, efficient and parallel computation of the
intermediate filter definition signal itself. Compared to a
direct application of the impulse response signal
indicative of the amplitude/frequency filter characteristic
in the time domain by convoluting the impulse response
signal with the time domain input signal, the application
of an embodiment of an inventive filter generator according
to the second aspect of the present invention enables a
simplified, faster and more efficient computation, which
leads to an audibly indistinguishable result compared to
the more complex convolution method.
Furthermore, an embodiment of the inventive filter
generator also offers the advantage of a significantly
enhanced flexibility with respect to the possible filter
characteristics applied in the subband domain. As arbitrary
filter characteristics can be transferred from the time
domain to the subband domain by an embodiment of an
inventive filter generator, an enormous flexibility is
introduced to audio signal processing and manipulation. For
instance, an embodiment of an inventive filter generator is
capable of providing an intermediate filter definition
signal corresponding to an individually altered filter
characteristic of an HRTF-related filter. In the field of
HRTF this offers the opportunity to individually modify the
HRTF filters according to the needs and hearing
capabilities of an individual. Moreover, the source
position as well as the listener position with respect to
each other and with respect to a (simulated or calculated)
environment (e.g. a concert hall, an open space, a stadium)
can be adapted. This offers the great advantage of
providing a listener with a great flexibility with respect
to the acoustic conditions. An embodiment of the inventive
filter generator, hence, provides the possibility to

virtually switch from a stadium to a concert hall or an
open field, without employing the necessity to transfer the
audio signals between the time domain, the subband domain
and/or the frequency domain. By employing an embodiment of
an inventive filter generator all these manipulations of
the audio signal can be performed inside the subband domain
with a very high quality, which is perceptually
indistinguishable from a signal processing in the time
domain, but which offers an enormous computational
efficiency improvement.
This flexibility is not only limited to switching from one
environment to another, e.g. switching from a stadium to a
concert hall and visa versa. An embodiment of an inventive
filter generator offers the possibility to alter the filter
characteristics of the plurality of the intermediate
filters in a quasi-continuous fashion. An application in
the field of HRTF is an application of an embodiment of the
filter generator and/or of the filter apparatus in a head
tracking application, in which for instance the position of
the listener with respect to different audio sources varies
in a quasi-continuous way. Possible applications comprise,
for instance, simulations and computer games with a very
high quality.
Another advantage of an embodiment of a filter generator is
that the application of an embodiment of a filter generator
is more efficient with respect to the memory usage, as an
impulse response signal provided to the complex modulated
filter bank of the filter generator is typically a real
valued signal, whereas the intermediate filter definition
signal is a complex valued signal of approximately the same
over-all length. As a consequence, storing the impulse
response signals compared to the intermediate filter
definition signals (or the filter taps of the intermediate
filters) saves memory, roughly speaking, of an order of 2.
Due to the possibility of a fast and efficient parallel
computation, especially in the field of memory-sensitive

applications comprising a great parameter space with
respect to the possible impulse response signals, this
represents a significant advantage.
In one embodiment of in an inventive filter generator the
filter generator is provided with a filter definition
signal, which can comprise for instance the filter taps of
a digital filter in the time domain or by a transfer
function in the frequency domain, which can comprise the
amplitude/frequency characteristic and/or the
phase/frequency characteristic of a filter. In these cases,
an embodiment of the filter generator furthermore comprises
an impulse response signal generator, which provides the
appropriate impulse response signal indicative of the
resulting amplitude/frequency filter characteristic in the
time domain to the complex modulated filter bank of the
filler generator. Hence, the inclusion of an impulse
response signal generator in some embodiments of an
inventive filter generator offers an even more flexibility
with respect to providing the intermediate filter
definition signal, as not only the impulse response signals
in the form of discrete time signals can be provided to an
embodiment of the filter generator but also the filter taps
or the frequency domain description of a filter in the time
domain can be transferred into the subband domain by an
appropriate embodiment of a filter generator.
BRIEF DESCRIPTION OF THE DRAWINGS
The present invention will now be described by way of
illustrative examples, not limiting the scope or spirit of
the invention, with reference to the accompanying
drawings, in which:
Fig. la illustrates the processing of a digital audio
signal by means of subband filtering in a system
comprising a filter generator and a filter apparatus;

Fig. 1b illustrates a possible solution for a complex
analysis bank;
Fig. 1c illustrates a possible solution for a complex
synthesis filter bank;
Fig. 1d illustrates a further possible solution for a
complex synthesis filter bank;
Fig. 1e illustrates an interplay of an embodiment of a
filter generator with a plurality of intermediate filters
of an embodiment of a filter apparatus;
Fig. 2 illustrates the processing of a digital audio
signal by means of direct form filtering;
Fig. 3 illustrates a preferred embodiment of a system with
a filter converter;
Fig. 4 illustrates a given filter impulse response;
Fig. 5 illustrates an impulse response obtained by complex
gain adjustment of subbands;
Fig. 6 illustrates the magnitude response of a given
filter;
Fig. 7 illustrates the magnitude response of a filter
obtained by complex gain adjustment of subbands;
Fig. 8 compares the performance of the present invention
with complex gain adjustment of subbands;
Fig. 9 illustrates a preferred embodiment of a filter
apparatus comprising an optional embodiment of a filter
generator and further components;
Fig. 10 illustrates a filter characteristic along with
several frequency bands for different subbands; and
Fig. 11 illustrates a preferred embodiment of a filter
generator.
DESCRIPTION OF PREFERRED EMBODIMENTS
The below-described embodiments are merely illustrative
for the principles of the present invention of efficient
filtering with a complex modulated filterbank. It is
understood that modifications and variations of the
arrangements and the details described herein will be
apparent to others skilled in the art. It is the intent,

therefore, to be limited only by the scope of the
impending patent claims and not by the specific details
presented by way of description and explanation of the
embodiments herein.
In. the following, objects with the same or similar
functional properties are denoted with the same reference
signs. Unless explicitly noted otherwise, the description
with respect to objects with similar or equal functional
properties can be exchanged with respect to each other.
Figure la illustrates in the form of a system comprising
embodiments of both a filter apparatus and a filter
generator the processing of a digital audio signal by means
of subband filtering according to the present invention.
This signal path can for instance represent a part of a
spatial audio rendering system where the input is a
received audio channel and the output is a component of a
signal to be played back at the right ear. The input signal
(Digital audio signal or time domain input signal) is
analyzed by the complex analysis bank 101 by means of
filtering with a set of L analysis filters followed by
downsampling of a factor L , wherein Lisa positive
integer, preferably larger than 1. Typically the factor L
is a power of 2, preferably L = 64. The analysis filters
are usually obtained by a complex modulation of a prototype
filter p(v), wherein v is a positive integer indicating an
index in an array of data or an index of a value in a
signal not downsampled by factor L. The output of the
filter bank consists of L subband signals that are
processed by a subband filtering 102. This subband
filtering consists of a combination of manipulations such
as subband gain adjustment according to received control
data and application of finite impulse response filters
applied separately in each subband. The filter taps of the
subband filters are obtained from an (inventive) filter
converter 104 as an embodiment of a filter generator which
takes as input a filter described by direct form filter

taps, a frequency domain description or an impulse response
(signal). The complex synthesis bank 103 reconstructs an
output signal by means of upsampling by a factor L,
filtering by L synthesis filters, summation of all the
results, and extraction of the real part. The summation of
all the results and the extraction of the real part can
also be switched with respect to their order, as will be
outlined more closely with respect to Figs, 1c and 1d.
Fig. 1b shows a complex analysis bank 101 in more detail.
The complex analysis bank 101 comprises a plurality of L
intermediate analysis filters 120 for each subband to be
output by complex analysis bank 101. To be more precise,
each of the L intermediate analysis filters 120 is
connected in parallel to a node 130 to which the time
domain input signal to be processed is provided. Each of
the intermediate analysis filters 120 is adapted for
filtering the input signal of the complex analysis bank 101
with respect to a center frequency of each subband.
According to the center frequencies of the different
subbands, each subband is labeled by a subband index or
index n, wherein n is a non-negative integer, typically in
the range from 0 to L-1. The intermediate analysis filters
120 of the complex analysis bank 101 can be derived from a
prototype filter p(v) by a complex modulation according to
the subband index n of the subband to which the
intermediate analysis filter 120 is applied. More details
concerning the complex modulation of a prototype filter are
explained below.
Either directly by the intermediate analysis filters 120 or
by an optional downsampler 140 (denoted by doted line in
Fig. lb) the sampling frequency of the signal output by the
intermediate analysis filter bank 120 is reduced by a
factor L. As mentioned before, the downsamplers 140
supplied to each subband signal output by the corresponding
intermediate analysis filters 120 are optional as,
depending on the concrete implementation, the downsampling

can also be carried out in the frame work of the
intermediate analysis filters 120. In principle,
downsampling the signal output by the intermediate analysis
filters 120 is not required. Nevertheless, the presence of
the explicit or implicit downsamplers 140 is a preferred
option as the amount of data provided by the complex
analysis bank 101 would alternatively be raised by a factor
of L, leading to a significant redundancy of data.
Fig. 1c illustrates a possible solution for a complex
synthesis bank 103. The complex synthesis bank 103
comprises L intermediate synthesis filters to which the L
subband signals from the subband filtering 102 are provided
to. Depending on the concrete implementation of the complex
synthesis bank 103 prior to the filtering in the frame work
of the intermediate synthesis filters 150, the subband
signals are upsampled by L upsampler 160, which reconstruct
the sampled frequency of the subband signals by increasing
the sampling frequency by a factor of L. In other words,
the optional upsampler 160 reconstruct or reform the
subband signals provided to the upsampler 160 in such a way
that the information contained in each of the subband
signals is retained while the sampling frequency is
increased by a factor of L. Nevertheless, as already
explained in the context of Fig. 1b, the upsamplers 160 are
optional components, as the upsampling can also be carried
out in the frame work of the intermediate synthesis filters
150. Hence, the step of upsampling the subband signals
carried out by the upsampler 160 can be simultaneously
processed in the frame work of the intermediate synthesis
filers 150. If, however, the downsamplers 190 are neither
explicitly nor implicitly implemented, the upsamplers 160
do not have to be implemented explicitly or implicitly.
The intermediate synthesis filters 150 are connected via an
output to an adder 170 which sums up the filtered subband
signals output by the L intermediate synthesis filters 150.
The adder 170 is further connected to a real part extractor

180, which extracts or forms a real valued signal or rather
a (real valued) time domain output signal based on the
complex valued signal provided by the adder 170. The real
part extractor 180 can perform this task for instance by
extracting the real part of a complex valued signal
provided by the adder 170, by calculating the absolute
value of the complex valued signal provided by the adder
170 or by another method that forms a real valued output
signal based on a complex valued input signal. In the case
of the system shown in Fig. la, the signal output by the
real part extractor 180 is the time domain output signal
output by the embodiment of the inventive filter apparatus.
The second possible solution for a complex synthesis bank
103 shown in Fig. 1d differs from the first possible
solution shown in Fig. 1c only concerning the real part
extractors 180 and the adder 170. To be more precise, the
outputs of the intermediate synthesis filters 150 are
connected separately from each subband to a real part
extractor 180 extracting or forming a real valued signal
based on the complex valued signal output by the
intermediate synthesis filters 150. The real part extractor
180 are then connected to the adder 170, which sums up the
L real valued signals derived from the L filtered subband
signals to form the real valued output signal provided by
the adder 170, which in the case of the system shown in
Fig. 1a is the time domain output signal.
Fig. 1e shows the subband filtering 102 and its interplay
with the filter converter 104 in more details. The subband
filtering 102 comprises a plurality of intermediate filters
190, wherein one intermediate filter 190 is provided for
each complex valued subband signal provided to the subband
filtering 102. Hence, the subband filtering 102 comprises L
intermediate filters 190.
The filter converter 104 is connected to each of the
intermediate filters 190. As a consequence, the filter

converter 104 is capable of providing the filter taps for
each of the intermediate filters 190 of the subband
filtering 102. More details concerning the filtering done
by the intermediate filters 190 will be explained in the
further course of the application. Hence, the filters taps
provided to the different intermediate filters 190 and
output by the filter converter 104 form the intermediate
filter definition signal.
Furthermore, it should be noted that the embodiments,
solutions and implementations can comprise additional
and/or optional delays for delaying any of the signals or a
subset of signals, which have been omitted in Fig. la to 1e
for the sake of simplicity. Also in the Fig. 2 to 11
optional delays have been omitted for the sake of
simplicity. Nevertheless, delays or delayers can be
comprised in elements shown (e.g. filters) or added as
optional elements in all embodiments depending on their
concrete implementation.
Figure 2 illustrates the processing of a digital audio
signal by means of direct form filtering 201. If the same
filter is given as input to the filter converter 104 of
Fig. 1 and the direct filtering 201, a design goal for the
filter converter 104 is that the digital audio output of
103 should be perceptually (or audibly) indistinguishable
frcm the digital audio output of the direct filtering
201, if the digital audio inputs to the complex analysis
bank 101 and the direct filtering 201 are identical and
the processing in the direct filtering 102 consists of
pure stationary subband filtering.
In the embodiment of the system shown in Fig. la to Fig.
le the filter input to the filter converter 104 is given
as a filter definition signal, which can for instance
comprise the filter taps of a corresponding time domain
filter, a frequency domain description
(amplitude/frequency characteristic and/or phase/frequency

characteristic) or an impulse response signal of the
appropriate filter.
In the case of the direct filtering 201 the same filter
definition signal can in principle be used. Depending on
the concrete implementation and the filter definition
signal, the filtering can be carried out by direct
application of the filter taps in the frame work a digital
filter, by a discrete Fourier transform along with a
transfer function or another frequency domain description
or by means of convolution with the impulse response
signal.
Figure 3 illustrates a preferred embodiment of a filter
converter 104 according to the present invention as an
embodiment of a filter generator. The filter is assumed to
be given by its impulse response. Viewing this impulse
response as a discrete time signal, it is analyzed by an
L-band complex analysis (filter) bank 301. The resulting
subband signal outputs are then exactly the impulse
responses of filters to be applied separately in each
subband in the subband filtering 102. In the preferred
embodiment shown in Fig. 3, the filter definition signal
provided to the filter converter 104 and its complex
analysis bank or complex analysis filter bank 301 is the
impulse response signal indicative of the
amplitude/frequency characteristic of a filter, which is
to be transferred into the subband domain. Hence, the
output of the complex analysis (filter) bank 301 of each
of the L subbands represents the impulse response of the
intermediate filters comprised in the subband filtering
102.
The complex analysis bank 301 is in principle derived from
the analysis bank 101 but it has a different prototype
filter and a slightly different modulation structure, the
details of which will be outlined in the following
description. The same fast algorithms that are used for an

implementation of the complex analysis bank 101 can be
reused for complex analysis bank 301, leading to a very
fast and very efficient conversion process.
Moreover, the length of the prototype filter q(v) can be
designed to be only a fraction of the length of the
prototype filter p(v) . Due to the downsampling by a factor
L, the length of subband filters are also a factor of L
smaller than the sum of the lengths of the given time
domain filter and the prototype filter q(v) . The
computational effort is thus reduced in comparison to the
direct form filtering 201 by approximately a factor of
L/4 . The offset factor of 4 is due to the replacement of
real filtering with complex filtering. Another offset is
the computational cost of the complex analysis and
synthesis banks 101 and 103. For efficient implementations
this cost is comparable to the cost of rather short FIR
filters, and hence negligible, as outlined before.
Moreover, this offset of the reduction in computational
cos~ does not exist for systems that already employs these
two filter banks 101 and 103.
Figure 4 illustrates an example of a given filter impulse
response 400. It consists of 192 (= 64.3) nonzero taps. In
other words, the impulse response 400 shown in Fig. 4
comprises 192 non-vanishing values.
In the present application, a non-vanishing tap or value
is a tap or a value which is ideally not equal to zero.
Nevertheless, due to implementation restraints in the
frame work of this application a non-vanishing value or
tap is a real valued or complex valued tap or value with
an absolute value which is larger than a predetermined
threshold, e.g. 10-s or 2-s, wherein s is a positive
integer depending on the requirements of a concrete
implementation. In digital systems this threshold is
preferably defined in the binary system (basis 2), wherein
the integer s has a predetermined value depending on the

specifics of the implementation. Typically, the value s is
4, 5, 6, 7, 8, 10, 12, 14, 16 or 32.
The impulse response 400 of the system of Figure 1 is
indistinguishable from this given impulse response at the
resolution of the image, in a case where a L = 64 band
filterbank with a prototype filter of length 640 (= 64•10)
is applied and a prototype filter of length 192 (= 64•3)
is used for the filter converter 104 of Figure 3. The
corresponding intermediate subband filters have only 5 (=
3+3-1) taps each, as will be explained later.
Figure 5 illustrates the impulse response 410 of the
system of Figure 1 with a 64 band filterbank, in a special
case corresponding to prior art usage for envelope
adjustment and equalization. In this case, the subband
filters or rather intermediate filters 190 are all of one
tap only, so a constant complex gain is applied to each
subband. For each subband, the corresponding gain is
chosen to be equal to the complex frequency response of
the filter of Figure 4 evaluated at the center frequency
of the particular subband. As it can be seen from the
result, there are severe pre-echo artefact and there will
be a significant perceptual difference between the
application of this filter response compared to the target
impulse response 400 of figure 4.
Figure 6 illustrates the magnitude response 420 of the
filter of Figure 4. The frequency scale of Fig. 6 is
adjusted to the resolution of a 64 band filter bank ( L =
64) .
Figure 7 illustrates the magnitude response 430 of the
filter underlying the impulse response 410 shown in
Figure 5. As it can be seen, the usage of only one gain
per subband results in a poor approximation to the desired
frequency response. The main reason for this is the fast
variation of the target phase spectrum. In fact, this

prior art method is better suited at modeling linear phase
responses.
Figure 8 finally compares the performance of an embodiment
of the present invention and of the prior art method of
complex gain adjustment of subbands. The dotted curve is a
redrawing of the target magnitude response 420 of Figure
6. The dashed curve 440 is the magnitude response of the
difference between the complex frequency responses of the
target filter and its approximation by the prior art
method. The solid curve 450 is the magnitude response of
the difference between the complex frequency responses of
the target filter and its approximation by the method
taught by the present invention with the parameters as
discussed during the description of Figure 4. As it can be
seen, the error of the prior art method is small only at
the 64 midpoints of filter bank subbands whereas the
inventive method leads to an approximation quality in the
50 dB range. It should be pointed out that this is also
the level of performance one measures when comparing the
output of the inventive system to the output of the
reference system for an arbitrary input signal.
As the comparison of the two curves 440 and 450 in Fig. 8
shows, an embodiment of an inventive filter apparatus, an
embodiment of a filter generator and a system comprising
both embodiments offer a significant advantage concerning
the quality of the manipulation of an input signal. The
significant difference concerning the quality of filtering
(or manipulation) of the input signal outlined above is a
consequence of the fact that at least one of the
intermediate filters 190 has an impulse response with two
or more non-vanishing values. In other words, at least one
of the intermediate filters 190 comprises at least two non-
vanishing filter taps. Furthermore, it is important to note
that the number of subbands L processed by an embodiment of
a filter apparatus is larger or at least equal to 2.
Nevertheless, the number of subbands L is significantly

smaller than the number of frequency bands required for a
comparable quality in the case of a Fourier transform-based
filtering combined with a filter mainly described by an
amplitude/frequency characteristic and/or a phase/frequency
characteristic as the transfer function of the filter.
Due to the fact that the impulse response of the
intermediate filters 190 are significantly shorter than the
impulse response of the underlying filter characteristic in
the time domain, the computations with respect to each
subband can be carried out significantly faster.
Furthermore, as the different subband signals can be
processed independently, both an embodiment of the filter
apparatus as well as an embodiment of the filter generator
104 can process the respective input signals highly
efficiently in a fast and a parallel manner. Hence, the
processing of both a digital audio input as an input signal
as well as an impulse response indicative of a filter
characteristic can be carried out highly efficiently in a
parallel fashion. As outlined earlier, an embodiment of an
inventive filter apparatus as well as an embodiment of an
inventive filter generator combine the advantages of both a
direct processing of audio signals in the time domain
leading to a very high quality and using a combination of a
Fourier transform along with a transfer function in the
frequency domain offering a high efficiency as each
frequency band is only multiplied with a (complex or real
valued) tap in the process of filtering the signal.
On the other hand, the disadvantages of both, purely
processing the input signals in the time domain, which
leads to an enormous computation effort, and those of a
Fourier transform, can be significantly reduced and
suppressed to a level that the output of an embodiment of a
filter apparatus is perceptually indistinguishable from the
quality of a direct processing in the time domain.

These two advantages offer a great flexibility for
filtering digital signals with varying filtering
characteristics. This is especially important in the field
of HRTF, as HRTF-related filters usually have a very long
impulse response. Hence, an embodiment of an inventive
filter apparatus comprising a complex analysis filter bank
101, a plurality of intermediate filters 190 in the subband
filtering 102 and a complex synthesis filter bank 103
offers especially in the field of HRTF-related applications
significant computational advantages due to the possible
parallel processing of subband signals.
Embodiments of a filter generator and embodiments of
systems comprising both a filter apparatus and a filter
generator offer furthermore the advantage that filters can
easily be adapted to specific environments, parameters or
other specific needs of the application at hand. Especially
in terms of HRTF-related applications, an embodiment of
such a system can be used in head-tracking applications, in
which several sources of sounds and noises as well as the
position of the listener vary over time. Such an embodiment
of a system comprising a filter apparatus and a filter
generator therefore offer a highly efficient and flexible
way to present an audio impression of a three dimensional
arrangement of sound sources with respect to a varying
position and orientation of a hypothetical listener via
headphones or other head-related sound systems (stereo
sound systems).
As this last example illustrates, an embodiment of an
inventive filter apparatus along with an inventive filter
generator offers not only a highly efficient system for
audio manipulation with an excellent quality but also a
very flexible way to introduce altering audio impressions
in an efficient way.

Complex modulated filter banks
In the following, let be the discrete
time Fourier transform of a discrete time signal z(v) . As
before, v is an integer indicating an index or a time index
of a time signal, while ω = 2 n • f is the circular
frequency associated to the frequency f, n is the circular
number (n = 3.1415926...) and is the imaginary
unit.
The complex exponential modulated L-band filterbank is
defined from a real valued prototype filter p(v) of finite
length. For the computations below it will be assumed by
extension with zeros that the prototype filter is defined
for all integers v . Given a real valued discrete time
signal x{v) the analysis filter bank 101 applies, as
already explained, the complex modulated prototype filters
followed by downsampling by a factor L in order to output
the subband signals,

for each subband index n = 0,1,K ,L-1, and integer time index
k . The time index k differs from the time index v with
respect to the fact that k refers to the downsampled
signals, whereas the integer v withers to signals with the
full sample frequency.

In the equations (1) and (2) θand ψ represent (constant)
phase factors for filtering the real valued discrete time
Given complex valued subband signals dn(k), the synthesis
filter bank 103 applies filtering followed by upsampling by
a factor of L and a real value extraction in order to
output the real valued signals, as already explained, to
obtain the output signal

signal x(v) into complex valued subband signal and for
reconstructing real valued output samples y(v) from
complex valued subband signals dn(k) . It is well known
that a prototype filter and fixed phase factors θand ψ
can be chosen to give perfect reconstruction, y(y) = x(v), in
the case where dn{k) = cn(k), that is when the subband signals
are unaltered. In practice, the perfect reconstruction
property will hold true up to a delay (and/or a sign
change), but in the computations that follow, this detail
will be ignored by allowing the use of an acausal
prototype filter. The present invention is applicable to
the pseudo QMF type of design as taught by PCT/SE02/00626
"Aliasing reduction using complex exponential modulated
filter banks". Here the prototype filter is symmetric
p(-v)-p(v), and its discrete time Fourier transform P(ω)
essentially vanishes outside the interval |ω|≤π/L. The
perfect reconstruction is also replaced by a near-perfect
reconstruction property. For the derivation that follows
it will be assumed for simplicity that both perfect
reconstruction holds and that P(ω)) = 0 for π|L Moreover, the phase factors are assumed to satisfy the
condition that ψ-θ is equal to an integer multiple of 4L .
In a critically sampled filter bank, the alteration of
subband signals prior to synthesis usually leads to the
introduction of aliasing artifacts. This is overcome here
due to the fact that an oversampling by a factor two is
introduced by using complex valued signals. Although the
total sampling rate of the subband samples is identical to
the sampling rate of the discrete time input signal, the
input signal is real valued and the subband samples are
complex valued. As it will be outlined below, the absence
of alias opens the door for efficient time invariant
signal processing.
Subband filtering in a complex modulated filter bank

Consider the modification of subband filtering 102 of each
subband signal obtained by filtering the analysis samples
cn(k) from the complex analysis bank 101 with a filter with
impulse response gn(k) prior to the synthesis (2) performed
5 by the complex synthesis (filter) bank 103



Elementary computations show that given the assumptions on
the frequency response of the prototype filter, the
resulting effect on the reconstructed time signal is that
of a discrete time filtering



where




Here,
is the discrete time Fourier
transform of the filter applied in subband nfor n0and


where * denotes complex conjugation. Observe here that the
special case Gn(ω) = l leads to G(Ω) = L in (5) due to the
assumed special design of the prototype p(v), which implies

Another case of interest is Gn{ω) = exp(-iω) which leads to
G(ω) - exp(-iLω) , so that y{v) = x(v-L).
Approximating a given filter response by subband filtering
Let H(ω) be a given filter (e.g. transfer function) with
real valued impulse response h(v) . This data is considered
as input to the filter converter 104. In view of (5) and

(7), a trivial choice for the subband filters which result
in the desired response G(ω) = H(ω) is given by


with the extension gn=-g-1-n for n with (6). In view of (7), one achieves

The drawback of this formula is that although H(ω) is a
smooth function of ω, the periodized segment of it
defined by (8) will exhibit jumps and the impulse response
of the subband filters will be unnecessarily long. The
prior art usage of the complex pseudo QMF bank for
equalization or envelope adjustment consists of applying a
single gain gn in each subband, which results in the
transfer function
and the transfer function is interpolated between those
frequencies. For target filter responses H(ω) that vary
slowly as a function of the frequency ω, a first method
of approximating the filter is therefore obtained by
choosing

An example of the resulting quality of this procedure is
given in figures 5 and 7.
According to an embodiment of the present invention a
filter generator or a filter converter 104 is used to
teach to convert the filter (defined by its impulse
response) h(v)into intermediate subband filters 190 by
means of the second analysis filter bank 301 which employs
real valued prototype filter q(v),


In terms of Fourier transforms this reads

The advantage of this procedure is that any given filter
h(v) can be efficiently transformed into intermediate
subband filter responses. If q(v) has KQ L taps, a time
domain filter h(v) of KH.L taps is converted into subband
domain filters (12) with KH+KQ-1 taps, wherein KH and KQ
are positive integers. With respect to the exemplary
numbers given in the context of the description of Fig. 4,
KH and KQ are equal to 3 and with a prototype filter length
and an impulse response corresponding to a length of 3 •
64 = 192 (L = 64) each. Hence, each intermediate subband
filter 190 has an impulse response length of only 3 + 3 -
l=5 taps each.

Hence, the condition for G(ω) = H(ω) to hold is that
Design of the prototype filter for the filter converter
Insertion of (13) into (5) yields

whereδ[1] = l for l = 0and δ[l] = 0 for l≠0. A simple solution to
(15) is given by the brick wall filter

This prototype filter corresponds to the choice (8) and
has the disadvantage of having an infinite and slowly
decaying impulse response q(v) . Instead, the present

invention teaches to solve (15) approximately (e.g. in the
least-square sense) with a finite impulse response filter
q(v). The time domain equivalent of (15) is the system of
linear equations for n = 0,1,K,L-1 and for all integers k,

is the autocorrelation of p(v) . For any given support
length the system of linear equations (16) can be solved
in the least squares sense for a prototype filter q(v) . It
is desirable to use a support significantly shorter than
that of the original filter bank prototype filter p(v), and
in that case the linear system (16) is over-determined. A
given quality of approximation can also be traded for
other desirable properties via joint optimization. One
example of such a property is a low pass type of frequency
response Q(ω) .
In the following the determination of a multi-slot QMF
representation (subband domain) of the HRTF filters is
described. The filter conversion from the time domain into
the complex QMF subband domain is performed by an FIR
filter in the filter converter 104 of Fig. la. To be more
precise, the following description outlines a method for
implementing a given FIR filter h(v) of length Nh in the
complex QMF subband domain. The principle of the operation
is illustrated in Fig. 1a in the case of a system also
comprising an embodiment of an inventive filter apparatus.
The subband filtering itself is carried out by a set of or
a plurality of intermediate filters 190 inside the subband
filtering 102. To be more precise, the subband filtering
consist of the separate application of one complex valued
FIR intermediate filter gn (1) for each QMF subband with an

index n = 0,1,..., 63. In other words, in the following
description special references will be made to embodiments
with L = 64 different subband signals. Nevertheless, this
specific number of subband signals is not essential and
the appropriate equations will also be given in a more
general form.
One of the key components of the system shown in Fig. la
is the filter converter 104, which converts the given time
domain FIR filter h(v) into the complex subband domain
filters gn(1). The filter converter 104 comprises a
complex analysis bank 301 similar to the QMF analysis bank
101. The prototype filter of the complex analysis filter
bank 301 of the filter converter 104 q(v) of length 192 (=
3•64) for the specific case of I = 64 subband signals are
created by solving in the least square sense the over
determined system of the equation (16) . The filter
coefficients q(v) or rather the relations they fulfill
will be described in more detail for the case of L = 64
subbands signals later on.
To be more accurate in terms of mathematical description,
an extension with zeros in the time domain FIR filter is
defined by

The resulting intermediate subband domain filters are based
on equation (12) and can be expressed in the general case
as


wherein l0 and v0 are delays, 1 is an integer indicating an
index of the filter taps and Nq (= NQ)is the length of the
impulse response of the prototype filter g(v).
It should be noted, that in the frame work of the present
application under an equation being based on an equation an
introduction of additional delays (cf. l0 and v0) factors,
additional coefficients and an introduction of a window
function or another simple function is understood.
These subdomain filters have a length Lq = Kh + 2, where
In the case L = 64, the expression for the subband domain
filters or intermediate filters 190 becomes


and Nh is the length of the impulse response h(v) of the
filter characteristics to be transferred into the subband
domain.
In this case, the integer n=0, 1, ..., 63 is once again the
index of a subband and 2 = 0, 1, ..., {Kh+1) is an integer
indicating taps of the resulting intermediate filters 190.
The extra addend of (-2) in equation (20) as compared to
equation (12) is there, because equation (12) was developed
without any regard to casualty of filters. Real
implementations will cause always introduce delays. Hence,
depending on the concrete implementation, additional
delayers or delays can be implemented in the embodiments
shown in Figs, 1a to 1e and Figs. 2 to 11, which have been
omitted for the sake of simplicity in Figures mentioned.

As outlined earlier, in many cases the system of linear
equations (16) is over determined. Nevertheless, it can be
solved or approximated in the least square sense with
respect to the prototype filter coefficients g(v). Solving
the system of linear equations (16) in the least square
sense, leads to the filter taps of the prototype filter
g(v) to fulfill the following relations for integers v
from 0 to 191:
-0.204 ≤ q[0] ≤ -0.202
-0.199 ≤ q[l] ≤ -0.197
-0.194 ≤ q[2] ≤ -0.192
-0.189 ≤ q[3] ≤ -0.187
-0.183 ≤ q[4] ≤ -0.181
-0.178 ≤ q[5] ≤ -0.176
-0.172 ≤ q[6] ≤ -0.170
-0.166 ≤ q[7] ≤ -0.164
-0.160 ≤ q[8] ≤ -0.158
-0.154 ≤ q[9] ≤ -0.152
-0.148 ≤ q[10] ≤ -0.146
-0.142 ≤ q[ll] ≤ -0.140
-0.135 ≤ q[12] ≤ -0.133
-0.129 ≤ q[13] ≤ -0.127
-0.122 ≤ q[14] ≤ -0.120
-0.116 ≤ q[15] ≤ -0.114
-0.109 ≤ q[16] ≤ -0.107
-0.102 ≤ q[17] ≤ -0.100
-0.096 ≤ q[18] ≤ -0.094
-0.089 ≤ q[19] ≤ -0.087
-0.082 ≤ q[20] ≤ -0.080
-0.075 ≤ q[21] ≤ -0.073
-0.068 ≤ q[22] ≤ -0.066
-0.061 ≤ q[23] ≤ -0.059
-0.054 ≤ q[24] ≤ -0.052
-0.046 ≤ q[25] ≤ -0.044
-0.039 ≤ q[26] ≤ -0.037
-0.032 ≤ q[27] ≤ -0.030

-0.024 ≤ q[28] ≤ -0.022
-0.017 ≤ q[29] ≤ -0.015
-0.009 ≤ q[30] ≤ -0.007
-0.002 ≤ q[31] ≤ 0.000
0.006 ≤ q[32] ≤ 0.008
0.014 ≤ q[33] ≤ 0.016
0.021 ≤ q[34] ≤ 0.023
0.029 ≤ q[35] ≤ 0.031
0.037 ≤ q[36] ≤ 0.039
0.045 ≤ q[37] ≤ 0.047
0.054 ≤ q[38] ≤ 0.056
0.062 ≤ q[39] ≤ 0.064
0.070 ≤ q[40] ≤ 0.072
0.079 ≤ q[41] ≤ 0.081
0.087 ≤ q[42] ≤ 0.089
0.096 ≤ q[43] ≤ 0.098
0.105 ≤ q[44] ≤ 0.107
0.113 ≤ q[45] ≤ 0.115
0.122 ≤ q[46] ≤ 0.124
0.132 ≤ q[47] ≤ 0.134
0.141 ≤ q[48] ≤ 0.143
0.150 ≤ q[49] ≤ 0.152
0.160 ≤ q[50] ≤ 0.162
0.170 ≤ q[51] ≤ 0.172
0.180 ≤ q[52] ≤ 0.182
0.190 ≤ q[53] ≤ 0.192
0.200 ≤ q[54] ≤ 0.202
0.210 ≤ q[55] ≤ 0.212
0.221 ≤ q[56] ≤ 0.223
0.232 ≤ q[57] ≤ 0.234
0.243 ≤ q[58] ≤ 0.245
0.254 ≤ q[59] ≤ 0.256
0.266 ≤ q[60] ≤ 0.268
0.278 ≤ q[61] ≤ 0.280
0.290 ≤ q[62] ≤ 0.292
0.303 ≤ q[63] ≤ 0.305
0.902 ≤ q[64] ≤ 0.904
0.909 ≤ q[65] ≤ 0.911

0.917 ≤ q[66] ≤ 0.919
0.924 ≤ q[67] ≤ 0.926
0.930 ≤ q[68] ≤ 0.932
0.936 ≤ q[69] ≤ 0.938
0.942 ≤ q[70] ≤ 0.944
0.947 ≤ q[71] ≤ 0.949
0.952 ≤ q[72] ≤ 0.954
0.957 ≤ q[73] ≤ 0.959
0.961 ≤ q[74] ≤ 0.963
0.965 ≤ q[75] ≤ 0.967
0.969 ≤ q[76] ≤ 0.971
0.972 ≤ q[77] ≤ 0.974
0.975 ≤ q[78] ≤ 0.977
0.978 ≤ q[79] ≤ 0.980
0.981 ≤ q[80] ≤ 0.983
0.984 ≤ q[81] ≤ 0.986
0.986 ≤ q[82] ≤ 0.988
0.988 ≤ q[83] ≤ 0.990
0.990 ≤ q[84] ≤ 0.992
0.992 ≤ q[85] ≤ 0.994
0.993 ≤ q[86] ≤ 0.995
0.995 ≤ q[87] ≤ 0.997
0.996 ≤ q[88] ≤ 0.998
0.997 ≤ q[89] ≤ 0.999
0.998 ≤ q[90] ≤ 1.000
0.999 ≤ q[91] ≤ 1.001
0.999 ≤ q[92] ≤ 1.001
1.000 ≤ q[93] ≤ 1.002
1.000 ≤ q[94] ≤ 1.002
1.000 ≤ q[95] ≤ 1.002
1.000 ≤ q[96] ≤ 1.002
1.000 ≤ q[97] ≤ 1.002
0.999 ≤ q[98] ≤ 1.001
0.999 ≤ q[99] ≤ 1.001
0.998 ≤ q[100] ≤ 1.000
0.997 ≤ q[101] ≤ 0.999
0.996 ≤ q[102] ≤ 0.998
0.995 ≤ q[103] ≤ 0.997

0.993 ≤ q[104] ≤ 0.995
0.992 ≤ q[105] ≤ 0.994
0.990 ≤ q[106] ≤ 0.992
0.988 ≤ q[107] ≤ 0.990
0.986 ≤ q[108] ≤ 0.988
0.984 ≤ q[109] ≤ 0.986
0.981 ≤ q[110] ≤ 0.983
0.978 ≤ q[lll] ≤ 0.980
0.975 ≤ q[112] ≤ 0.977
0.972 ≤ q[113] ≤ 0.974
0.969 ≤ q[114] ≤ 0.971
0.965 ≤ q[115] ≤ 0.967
0.961 ≤ q[116] ≤ 0.963
0.957 ≤ q[117] ≤ 0.959
0.952 ≤ q[118] ≤ 0.954
0.947 ≤ q[119] ≤ 0.949
0.942 ≤ q[120] ≤ 0.944
0.936 ≤ q[121] ≤ 0.938
0.930 ≤ q[122] ≤ 0.932
0.924 ≤ q[123] ≤ 0.926
0.917 ≤ q[124] ≤ 0.919
0.909 ≤ q[125] ≤ 0.911
0.902 ≤ q[126] ≤ 0.904
0.893 ≤ q[127] ≤ 0.895
0.290 ≤ q[128] ≤ 0.292
0.278 ≤ q[129] ≤ 0.280
0.266 ≤ q[130] ≤ 0.268
0.254 ≤ q[131] ≤ 0.256
0.243 ≤ q[132] ≤ 0.245
0.232 ≤ q[133] ≤ 0.234
0.221 ≤ q[134] ≤ 0.223
0.210 ≤ q[135] ≤ 0.212
0.200 ≤ q[136] ≤ 0.202
0.190 ≤ q[137] ≤ 0.192
0.180 ≤ q[138] ≤ 0.182
0.170 ≤ q[139] ≤ 0.172
0.160 ≤ q[140] ≤ 0.162
0.150 ≤ q[141] ≤ 0.152

0.141 ≤ q[142] ≤ 0.143
0.132 ≤ q[143] ≤ 0.134
0.122 ≤ q[144] ≤ 0.124
0.113 ≤ q[145] ≤ 0.115
0.105 ≤ q[146] ≤ 0.107
0.096 ≤ q[147] ≤ 0.098
0.087 ≤ q[148] ≤ 0.089
0.079 ≤ q[149] ≤ 0.081
0.070 ≤ q[150] ≤ 0.072
0.062 ≤ q[151] ≤ 0.064
0.054 ≤ q[152] ≤ 0.056
0.045 ≤ q[153] ≤ 0.047
0.037 ≤ q[154] ≤ 0.039
0.029 ≤ q[155] ≤ 0.031
0.021 ≤ q[156] ≤ 0.023
0.014 ≤ q[157] ≤ 0.016
0.006 ≤ q[158] ≤ 0.008
-0.002 ≤ q[159] ≤ 0.000
-0.009 ≤ q[160] ≤ -0.007
-0.017 ≤ q[161] ≤ -0.015
-0.024 ≤ q[162] ≤ -0.022
-0.032 ≤ q[163] ≤ -0.030
-0.039 ≤ q[164] ≤ -0.037
-0.046 ≤ q[165] ≤ -0.044
-0.054 ≤ q[166] ≤ -0.052
-0.061 ≤ q[167] ≤ -0.059
-0.068 ≤ q[168] ≤ -0.066
-0.075 ≤ q[169] ≤ -0.073
-0.082 ≤ q[170] ≤ -0.080
-0.089 ≤ q[171] ≤ -0.087
-0.096 ≤ q[172] ≤ -0.094
-0.102 ≤ q[173] ≤ -0.100
-0.109 ≤ q[174] ≤ -0.107
-0.116 ≤ q[175] ≤ -0.114
-0.122 ≤ q[176] ≤ -0.120
-0.129 ≤ q[177] ≤ -0.127
-0.135 ≤ q[178] ≤ -0.133
-0.142 ≤ q[179] ≤ -0.140

-0.148 ≤ q[180] ≤ -0.146
-0.154 ≤ q[181] ≤ -0.152
-0.160 ≤ q[182] ≤ -0.158
-0.166 ≤ q[183] ≤ -0.164
-0.172 ≤ q[184] ≤ -0.170
-0.178 ≤ qtl85] ≤ -0.176
-0.183 ≤ q[186] ≤ -0.181
-0.189 ≤ q[187] ≤ -0.187
-0.194 ≤ q[188] ≤ -0.192
-0.199 ≤ q[189] ≤ -0.197
-0.204 ≤ q[190] ≤ -0.202
-0.209 ≤ q[191] ≤ -0.207
To be more precise, the filter coefficients g(v) obey the
following relations:
-0.20294 ≤ q[0] ≤ -0.20292
-0.19804 ≤ q[l] ≤ -0.19802
-0.19295 ≤ q[2] ≤ -0.19293
-0.18768 ≤ q[3] ≤ -0.18766
-0.18226 ≤ q[4] ≤ -0.18224
-0.17668 ≤ q[5] ≤ -0.17666
-0.17097 ≤ q[6] ≤ -0.17095
-0.16514 ≤ q[7] ≤ -0.16512
-0.15919 ≤ q[8] ≤ -0.15917
-0.15313 ≤ q[9] ≤ -0.15311
-0.14697 ≤ q[10] ≤ -0.14695
-0.14071 ≤ q[ll] ≤ -0.14069
-0.13437 ≤ q[12] ≤ -0.13435
-0.12794 ≤ q[13] ≤ -0.12792
-0.12144 ≤ q[14] ≤ -0.12142
-0.11486 ≤ q[15] ≤ -0.11484
-0.10821 ≤ q[16] ≤ -0.10819
-0.10149 ≤ q[17] ≤ -0.10147
-0.09471 ≤ q[18] ≤ -0.09469
-0.08786 ≤ q[19] ≤ -0.08784
-0.08095 ≤ q[20] ≤ -0.08093
-0.07397 ≤ q[21] ≤ -0.07395

-0.06694 ≤ q[22] ≤ -0.06692
-0.05984 ≤ q[23] ≤ -0.05982
-0.05269 ≤ q[24] ≤ -0.05267
-0.04547 ≤ q[25] ≤ -0.04545
-0.03819 ≤ q[26] ≤ -0.03817
-0.03085 ≤ q[27] ≤ -0.03083
-0.02345 ≤ q[28] ≤ -0.02343
-0.01598 ≤ q[29] ≤ -0.01596
-0.00845 ≤ q[30] ≤ -0.00843
-0.00084 ≤ q[31] ≤ -0.00082
0.00683 ≤ q[32] ≤ 0.00685
0.01458 ≤ q[33] ≤ 0.01460
0.02240 ≤ q[34] ≤ 0.02242
0.03030 ≤ q[35] ≤ 0.03032
0.03828 ≤ q[36] ≤ 0.03830
0.04635 ≤ q[37] ≤ 0.04637
0.05451 ≤ q[38] ≤ 0.05453
0.06275 ≤ q[39] ≤ 0.06277
0.07110 ≤ q[40] ≤ 0.07112
0.07954 ≤ q[41] ≤ 0.07956
0.08809 ≤ q[42] ≤ 0.08811
0.09675 ≤ q[43] ≤ 0.09677
0.10552 ≤ q[44] ≤ 0.10554
0.11442 ≤ q[45] ≤ 0.11444
0.12344 ≤ q[46] ≤ 0.12346
0.13259 ≤ q[47] ≤ 0.13261
0.14189 ≤ q[48] ≤ 0.14191
0.15132 ≤ q[49] ≤ 0.15134
0.16091 ≤ q[50] ≤ 0.16093
0.17066 ≤ q[51] ≤ 0.17068
0.18058 ≤ q[52] ≤ 0.18060
0.19067 ≤ q[53] ≤ 0.19069
0.20095 ≤ q[54] ≤ 0.20097
0.21143 ≤ q[55] ≤ 0.21145
0.22211 ≤ q[56] ≤ 0.22213
0.23300 ≤ q[57] ≤ 0.23302
0.24412 ≤ q[58] ≤ 0.24414
0.25549 ≤ q[59] ≤ 0.25551

0.26711 ≤ q[60] ≤ 0.26713
0.27899 ≤ q[61] ≤ 0.27901
0.29117 ≤ q[62] ≤ 0.29119
0.30364 ≤ q[63] ≤ 0.30366
0.90252 ≤ q[64] ≤ 0.90254
0.91035 ≤ q[65] ≤ 0.91037
0.91769 ≤ q[66] ≤ 0.91771
0.92457 ≤ q[67] ≤ 0.92459
0.93101 ≤ q[68] ≤ 0.93103
0.93705 ≤ q[69] ≤ 0.93707
0.94270 ≤ q[70] ≤ 0.94272
0.94800 ≤ q[71] ≤ 0.94802
0.95295 ≤ q[72] ≤ 0.95297
0.95758 ≤ q[73] ≤ 0.95760
0.96190 ≤ q[74] ≤ 0.96192
0.96593 ≤ q[75] ≤ 0.96595
0.96968 ≤ q[76] ≤ 0.96970
0.97317 ≤ q[77] ≤ 0.97319
0.97641 ≤ q[78] ≤ 0.97643
0.97940 ≤ q[79] ≤ 0.97942
0.98217 ≤ q[80] ≤ 0.98219
0.98472 ≤ q[81] ≤ 0.98474
0.98706 ≤ q[82] ≤ 0.98708
0.98919 ≤ q[83] ≤ 0.98921
0.99113 ≤ q[84] ≤ 0.99115
0.99288 ≤ q[85] ≤ 0.99290
0.99444 ≤ q[86] ≤ 0.99446
0.99583 ≤ q[87] ≤ 0.99585
0.99704 ≤ q[88] ≤ 0.99706
0.99809 ≤ q[89] ≤ 0.99811
0.99896 ≤ q[90] ≤ 0.99898
0.99967 ≤ q[91] ≤ 0.99969
1.00023 ≤ q[92] ≤ 1.00025
1.00062 ≤ q[93] ≤ 1.00064
1.00086 ≤ q[94] ≤ 1.00088
1.00093 ≤ q[95] ≤ 1.00095
1.00086 ≤ q[96] ≤ 1.00088
1.00062 ≤ q[97] ≤ 1.00064

1.00023 ≤ q[98] ≤ 1.00025
0.99967 ≤ q[99] ≤ 0.99969
0.99896 ≤ q[100] ≤ 0.99898
0.99809 ≤ q[101] ≤ 0.99811
0.99704 ≤ q[102] ≤ 0.99706
0.99583 ≤ q[103] ≤ 0.99585
0.99444 ≤ q[104] ≤ 0.99446
0.99288 ≤ q[105] ≤ 0.99290
0.99113 ≤ q[106] ≤ 0.99115
0.98919 ≤ q[107] ≤ 0.98921
0.98706 ≤ q[108] ≤ 0.98708
0.98472 ≤ q[109] ≤ 0.98474
0.98217 ≤ q[110] ≤ 0.98219
0.97940 ≤ q[lll] ≤ 0.97942
0.97641 ≤ q[112] ≤ 0.97643
0.97317 ≤ q[113] ≤ 0.97319
0.96968 ≤ q[114] ≤ 0.96970
0.96593 ≤ q[115] ≤ 0.96595
0.96190 ≤ q[116] ≤ 0.96192
0.95758 ≤ q[117] ≤ 0.95760
0.95295 ≤ q[118] ≤ 0.95297
0.94800 ≤ q[119] ≤ 0.94802
0.94270 ≤ q[120] ≤ 0.94272
0.93705 ≤ q[121] ≤ 0.93707
0.93101 ≤ q[122] ≤ 0.93103
0.92457 ≤ q[123] ≤ 0.92459
0.91769 ≤ q[124] ≤ 0.91771
0.91035 ≤ q[125] ≤ 0.91037
0.90252 ≤ q[126] ≤ 0.90254
0.89416 ≤ q[127] ≤ 0.89418
0.29117 ≤ q[128] ≤ 0.29119
0.27899 ≤ q[129] ≤ 0.27901
0.26711 ≤ q[130] ≤ 0.26713
0.25549 ≤ q[131] ≤ 0.25551
0.24412 ≤ q[132] ≤ 0.24414
0.23300 ≤ q[133] ≤ 0.23302
0.22211 ≤ q[134] ≤ 0.22213
0.21143 ≤ q[135] ≤ 0.21145

0.20095 ≤ q[136] ≤ 0.20097
0.19067 ≤ q[137] ≤ 0.19069
0.18058 ≤ q[138] ≤ 0.18060
0.17066 ≤ q[139] ≤ 0.17068
0.16091 ≤ q[140] ≤ 0.16093
0.15132 ≤ q[141] ≤ 0.15134
0.14189 ≤ q[142] ≤ 0.14191
0.13259 ≤ q[143] ≤ 0.13261
0.12344 ≤ q[144] ≤ 0.12346
0.11442 ≤ q[145] ≤ 0.11444
0.10552 ≤ q[146] ≤ 0.10554
0.09675 ≤ q[147] ≤ 0.09677
0.08809 ≤ q[148] ≤ 0.08811
0.07954 ≤ q[149] ≤ 0.07956
0.07110 ≤ q[150] ≤ 0.07112
0.06275 ≤ q[151] ≤ 0.06277
0.05451 ≤ q[152] ≤ 0.05453
0.04635 ≤ q[153] ≤ 0.04637
0.03828 ≤ q[154] ≤ 0.03830
0.03030 ≤ q[155] ≤ 0.03032
0.02240 ≤ q[156] ≤ 0.02242
0.01458 ≤ q[157] ≤ 0.01460
0.00683 ≤ q[158] ≤ 0.00685
-0.00084 ≤ q[159] ≤ -0.00082
-0.00845 ≤ q[160] ≤ -0.00843
-0.01598 ≤ q[161] ≤ -0.01596
-0.02345 ≤ q[162] ≤ -0.02343
-0.03085 ≤ q[163] ≤ -0.03083
-0.03819 ≤ q[164] ≤ -0.03817
-0.04547 ≤ q[165] ≤ -0.04545
-0.05269 ≤ q[166] ≤ -0.05267
-0.05984 ≤ q[167] ≤ -0.05982
-0.06694 ≤ q[168] ≤ -0.06692
-0.07397 ≤ q[169] ≤ -0.07395
-0.08095 ≤ q[170] ≤ -0.08093
-0.08786 ≤ q[171] ≤ -0.08784
-0.09471 ≤ q[172] ≤ -0.09469
-0.10149 ≤ q[173] ≤ -0.10147

-0.10821 ≤ q[174] ≤ -0.10819
-0.11486 ≤ q[175] ≤ -0.11484
-0.12144 ≤ q[176] ≤ -0.12142
-0.12794 ≤ q[177] ≤ -0.12792
-0.13437 ≤ q[178] ≤ -0.13435
-0.14071 ≤ q[179] ≤ -0.14069
-0.14697 ≤ q[180] ≤ -0.14695
-0.15313 ≤ q[181] ≤ -0.15311
-0.15919 ≤ q[182] ≤ -0.15917
-0.16514 ≤ q[183] ≤ -0.16512
-0.17097 ≤ q[184] ≤ -0.17095
-0.17668 ≤ q[185] ≤ -0.17666
-0.18226 ≤ q[186] ≤ -0.18224
-0.18768 ≤ q[187] ≤ -0.18766
-0.19295 ≤ q[188] ≤ -0.19293
-0.19804 ≤ q[189] ≤ -0.19802
-0.20294 ≤ q[190] ≤ -0.20292
-0.20764 ≤ q[191] ≤ -0.20762
Even more accurately, the filter coefficients g(v) can be
expressed by the following equations for the integer v in
the range between 0 and 191, wherein according to the
requirements and specifications of special
implementations, the prototype filter coefficients may
deviate from the following equations either individually
or from the maximum absolute value typically by 10%, 5% or
2% and preferably by 1% or 0.1%:
q[0] = -0.2029343380
q[l] = -0.1980331588
q[2] = -0.1929411519
q[3] = -0.1876744222
q[4] = -0.1822474011
q[5] = -0.1766730202
q[6] = -0.1709628636
q[7] = -0.1651273005
q[8] = -0.1591756024
q[9] = -0.1531160455

q[10] = -0.1469560005
q[ll] = -0.1407020132
q[12] = -0.1343598738
q[13] = -0.1279346790
q[14] = -0.1214308876
q[15] = -0.1148523686
q[16] = -0.1082024454
q[17] = -0.1014839341
q[18] = -0.0946991783
q[19] = -0.0878500799
q[20] = -0.0809381268
q[21] = -0.0739644174
q[22] = -0.0669296831
q[23] = -0.0598343081
q[24] = -0.0526783466
q[25] = -0.0454615388
q[26] = -0.0381833249
q[27] = -0.0308428572
q[28] = -0.0234390115
q[29] = -0.0159703957
q[30] = -0.0084353584
q[31] = -0.0008319956
q[32] = 0.0068418435
q[33] = 0.0145885527
q[34] = 0.0224107648
q[35] = 0.0303113495
q[36] = 0.0382934126
q[37] = 0.0463602959
q[38] = 0.0545155789
q[39] = 0.0627630810
q[40] = 0.0711068657
q[41] = 0.0795512453
q[42] = 0.0881007879
q[43] = 0.0967603259
q[44] = 0.1055349658
q[45] = 0.1144301000
q[46] = 0.1234514222
q[47] = 0.1326049434

q[48] = 0.1418970123
q[49] = 0.1513343370
q[50] = 0.1609240126
q[51] = 0.1706735517
q[52] = 0.1805909194
q[53] = 0.1906845753
q[54] = 0.2009635191
q[55] = 0.2114373458
q[56] = 0.2221163080
q[57] = 0.2330113868
q[58] = 0.2441343742
q[59] = 0.2554979664
q[60] = 0.2671158700
q[61] = 0.2790029236
q[62] = 0.2911752349
q[63] = 0.3036503350
q[64] = 0.9025275713
q[65] = 0.9103585196
q[66] = 0.9176977825
q[67] = 0.9245760683
q[68] = 0.9310214581
q[69] = 0.9370596739
q[70] = 0.9427143143
q[71] = 0.9480070606
q[72] = 0.9529578566
q[73] = 0.9575850672
q[74] = 0.9619056158
q[75] = 0.9659351065
q[76] = 0.9696879297
q[77] = 0.9731773547
q[78] = 0.9764156119
q[79] = 0.9794139640
q[80] = 0.9821827692
q[81] = 0.9847315377
q[82] = 0.9870689790
q[83] = 0.9892030462
q[84] = 0.9911409728
q[85] = 0.9928893067

q[86] = 0.9944539395
q[87] = 0.9958401318
q[88] = 0.9970525352
q[89] = 0.9980952118
q[90] = 0.9989716504
q[91] = 0.9996847806
q[92] = 1.0002369837
q[93] = 1.0006301028
q[94] = 1.0008654482
q[95] = 1.0009438063
q[96] = 1.0008654482
q[97] = 1.0006301028
q[98] = 1.0002369837
q[99] = 0.9996847806
q[100] = 0.9989716504
q[101] = 0.9980952118
q[102] = 0.9970525352
q[103] = 0.9958401318
q[104] = 0.9944539395
q[105] = 0.9928893067
q[106] = 0.9911409728
q[107] = 0.9892030462
q[108] = 0.9870689790
q[109] = 0.9847315377
q[110] = 0.9821827692
q[lll] = 0.9794139640
q[112] = 0.9764156119
q[113] = 0.9731773547
q[114] = 0.9696879297
q[115] = 0.9659351065
q[116] = 0.9619056158
q[117] = 0.9575850672
q[118] = 0.9529578566
q[119] = 0.9480070606
q[120] = 0.9427143143
q[121] = 0.9370596739
q[122] = 0.9310214581
q[123] = 0.9245760683

q[124] = 0.9176977825
q[125] = 0.9103585196
q[126] = 0.9025275713
q[127] = 0.8941712974
q[128] = 0.2911752349
q[129] = 0.2790029236
q[130] = 0.2671158700
q[131] = 0.2554979664
q[132] = 0.2441343742
q[133] = 0.2330113868
q[134] = 0.2221163080
q[135] = 0.2114373458
q[136] = 0.2009635191
q[137] = 0.1906845753
q[138] = 0.1805909194
q[139] = 0.1706735517
q[140] = 0.1609240126
q[141] = 0.1513343370
q[142] = 0.1418970123
q[143] = 0.1326049434
q[144] = 0.1234514222
q[145] = 0.1144301000
q[146] = 0.1055349658
q[147] = 0.0967603259
q[148] = 0.0881007879
q[149] = 0.0795512453
q[150] = 0.0711068657
q[151] = 0.0627630810
q[152] = 0.0545155789
q[153] = 0.0463602959
q[154] = 0.0382934126
q[155] = 0.0303113495
q[156] = 0.0224107648
q[157] = 0.0145885527
q[158] = 0.0068418435
q[159] = -0.0008319956
q[160] = -0.0084353584
q[161] = -0.0159703957

q[162] = -0.0234390115
q[163] = -0.0308428572
q[164] = -0.0381833249
q[165] = -0.0454615388
q[166] = -0.0526783466
q[167] = -0.0598343081
q[168] = -0.0669296831
q[169] = -0.0739644174
q[170] = -0.0809381268
q[171] = -0.0878500799
q[172] = -0.0946991783
q[173] = -0.1014839341
q[174] = -0.1082024454
q[175] = -0.1148523686
q[176] = -0.1214308876
q[177] = -0.1279346790
q[178] = -0.1343598738
q[179] = -0.1407020132
q[180] = -0.1469560005
q[181] = -0.1531160455
q[182] = -0.1591756024
q[183] = -0.1651273005
q[184] = -0.1709628636
q[185] = -0.1766730202
q[186] = -0.1822474011
q[187] = -0.1876744222
q[188] = -0.1929411519
q[189] = -0.1980331588
q[190] = -0.2029343380
q[191] = -0.2076267137
Hence, the present invention relates to the application of
an arbitrary filter to a signal which is available in the
transform domain of a complex exponential modulated filter
bank, when this filter bank is designed to give virtually
alias free performance of operations like equalization,
spectral envelope adjustment, frequency selective panning,
or frequency selective spatialization of audio signals.

The present invention permits to efficiently transform a
given finite impulse response (FIR) filter in the time
domain into a set of shorter FIR filters, to be applied
with one filter for each subband of the filter bank.
The present invention also teaches how to convert a given
discrete time domain filter into to a set of subband domain
filters. The result is that any given filter can be
implemented with a high degree of accuracy in the subband
domain of a complex exponential modulated filter bank. In a
preferred embodiment, the filter converter consists of a
second complex exponential modulated analysis filter bank.
For the special case of filters that implement a pure
delay, the methods of the present invention coincides with
that of PCT/EP2004/004607 "Advanced processing based on a
complex-exponential modulated filterbank and adaptive time
framing".
Furthermore, the present invention comprises the following
features:
- A method for obtaining a high quality approximation to
the filtering of a discrete-time input signal with a
given filter, comprising the steps of
- analyzing the input signal with a downsampled complex
analysis filter bank in order to obtain a multitude
of subband signals,
- filtering each subband signal with a subband filter,
where the multitude of subband filters are obtained
from the given filter by means of a filter converter,
- synthesizing an output signal from the filtered
subband signals with a downsampled complex synthesis
filter bank.
- A method according to the above where the filter
converter consists of a downsampled complex analysis
filter bank.

- An apparatus for performing a method for obtaining a high
quality approximation to the filtering of a discrete-time
input signal with a given filter, the method comprising
the steps of
analyzing the input signal with a downsampled
complex analysis filter bank in order to obtain a
multitude of subband signals,
- filtering each subband signal with a subband filter,
where the multitude of subband filters are obtained
from the given filter by means of a filter
converter,
synthesizing an output signal from the filtered
subband signals with a downsampled complex
synthesis filter bank.
- A computer program having instructions for performing,
when running on a computer, a method for obtaining a high
quality approximation to the filtering of a discrete-time
input signal with a given filter, the method comprising
the steps of
analyzing the input signal with a downsampled
complex analysis filter bank in order to obtain a
multitude of subband signals,
- filtering each subband signal with a subband filter,
where the multitude of subband filters are obtained
from the given filter by means of a filter
converter,
synthesizing an output signal from the filtered
subband signals with a downsampled complex synthesis
filter bank.
Adaptation for real cosine modulated filter banks
Whereas the above derivation is based on complex modulated
filter banks, a note can be made here for the critically
sampled real representation obtained by a cosine modulated
filter bank defined by taking the real part of the subband

samples (1) for an appropriate phase factor θ. In this
case it is no longer feasible to use the in-band subband
filtering method (3) to obtain a good approximation to a
given filter. However, due to the assumptions made on the
prototype filter response, a generalization to a multiband
filter of the type

will be applicable, (with obvious modifications for the
first and last subbands) . Due to the critical sampling
there is much less freedom in the construction of the
filter mask grn(1) . One has to do the following, which is
obvious for those skilled in the art. For each
m=0,1,K, ,L-1 , use the elementary subband signal
dn{k)=δ[n-m]δ[k] as input to the real synthesis bank, and
filter the resulting output y(v) with the filter h(v)to get
the filtered synthesis waveform z(y) . Now use this filtered
waveform as input to the real analysis bank. The resulting
subband signal carries the coefficients of the masks grn(l)
for n+r=m . Some reduction in work necessary for the
filter is obtained by observing that the three cases
m = 3κ + ε for ε = 0,1,2 can be processed in parallel by feeding
the first synthesis bank with all the corresponding
elementary subband signals for each case. Thus the real
valued filter converter comprises three real synthesis and
three real analysis bank operations. This parallel
computation represents an implementation short cut for real
valued filter converter for the case of a QMF band with
good side lope suppression.
Fig. 9 illustrates an embodiment of an inventive filter
apparatus for filtering a time domain input signal of an
inventive filter apparatus to obtain a time domain output
signal. As already mentioned in the context of Fig. la, the
filter apparatus of Fig. 9 comprises a complex analysis
filter bank 101, a subband filtering 102 and a complex

synthesis filter bank 103, which outputs the time domain
output signal.
While Fig. 1 shows a system comprising an embodiment of an
inventive filter apparatus along with an embodiment of a
filter generator 104, the filter apparatus shown in Fig. 9
comprises only as an option a filter converter 104, which
provides the subband filtering 102 with the intermediate
filter definition signal, for instance in the form of the
filter taps or the impulse response for each of the
intermediate filters 190 of the subband filtering 102. The
filter apparatus shown in Fig. 9, comprises additional
optional components, which can provide the subband
filtering 102 with the filter taps for the plurality of
intermediate filters 190 of the subband filtering 102.
As an example, the filter taps can also be taken from an
optional data base 500, which is connected to the subband
filtering 102. In one embodiment, the data base 500
comprises the complex valued filter taps of the
intermediate filters 190. The data base can be implemented
as a memory system, for instance in the form of a non-
volatile memory system or volatile memory system depending
on the concrete implementation. Hence, memory solutions for
the data base 500 comprise ROM (ROM = read only memory) ,
RAM (RAM = random access memory) , flash memory, magnetical
memory, optical memory or other memory systems.
Depending on the concrete implementation, a processor or a
CPU (CPU = central processing unit) 510 can access the data
base and provide the filter taps to the subband filtering
102 or can also access the data base to provide the
corresponding filter taps to the intermediate filters of
the subband filtering 102. Hence, such an embodiment
comprises a data base 500 from which the filter taps for
the subband filtering 102 can be taken.

In a further embodiment of an inventive filter apparatus,
which is also depicted as an option in Fig. 9, the CPU 510
is capable of on-line calculating the filter taps. In such
an embodiment, the CPU 510 accesses the data base 500
according to a set of parameters provided by the user
and/or according to a set of parameters, which are based on
further circumstances, reads one or more sets of filter
taps for the intermediate filters of the subband filtering
102 and calculates, optionally accompanied by an
interpolation scheme or another estimation scheme, the
desired intermediate filter taps and provides them to the
subband filtering 102. In a further embodiment, the CPU 510
or another processor or computer system provides the filter
taps of the intermediate filters 190 to the subband
filtering 102 without accessing a data base 500. In such an
embodiment, the CPU 510 or another processor calculates the
filter taps and provides them to the subband filtering 102.
Examples for such an embodiment will be explained more
closely with respect to Fig. 10.
In a further embodiment depicted in Fig. 9, the CPU 510
accesses a further data base 520, reads one or more filter
definition signals (e.g. in the form of impulse response
signals corresponding to filter characteristic in the time
domain) , calculates an effective filter definition signal,
for instance an appropriate impulse response, and provides
the results of this computation to the filter converter
104. In this embodiment, the filter converter 104 then
provides the subband filtering 102 with the appropriate
filter taps for the intermediate filters 190. Hence, in
this embodiment, the filter converter 104 generates the
effective subband filters or intermediate filters applied
to each individual subband filters of each individual
subband signal inside the subband filtering 102 leading to
a filtering effect audibly indistinguishable from a
corresponding filter applied to the time domain input
signal (input signal). As consequence, this embodiment is

also capable of on-line calculating the filter taps via the
filter converter 104.
An example might for instance be a device, which calculates
the taps of the intermediate filters 190 of the subband
filtering 102 according to a set of parameters for instance
provided by the user, wherein the parameter basis is so
large, that an effective predetermination of the filter
taps, optionally accompanied by some sort of interpolation
scheme, would not lead to the desired results.
A more concrete application comes for instance of the field
of dynamic chance of HRTF filters in one domain to be
converted to the subband or QMF domain. As mentioned
before, this is for instance relevant in applications
involving a head-tracker in which the data base 520 is an
HRTF data base comprising the time impulse responses of the
HRTF filters. As the HRTF filters usually have very long
impulse responses, the use of such a scheme is especially
interesting, as the taps for the intermediate filters 190
or the QMF taps are complex. Storing the data base in this
domain would roughly double the memory requirements
compared to the memory requirement of storing the impulse
responses in the time domain. However, the advantage of the
reduced memory requirement can also be employed without
having a CPU 510 which calculates the impulse response
provided to the filter converter 504. Instead, the data
base 520 can be simply be prompted to output the
corresponding definition signal, which might be an impulse
response in the time domain to the filter converter 104.
In Fig. 10, an amplitude/frequency characteristic 550 is
illustrated in the frequency domain. In some applications,
as explained before, the filter coefficients or filter taps
are the intermediate filters 190 of the subband filtering
102 can be stored in the data base like the data base 500
of Fig. 9. Alternatively or additionally, for some
applications, the filter taps of the intermediate filters

can also be calculated by the CPU 510 of Fig. 9. In the
case of a special effect filtering or a lower quality
signal processing, in which aliasing effects might become
tolerable (at least to some extend), the filter taps of the
intermediate filters 190 after subband filtering 102 can be
estimated without a filter converter 104 or another
embodiment of a filter generator. Possible applications
especially comprise voice transmission over low quality
lines, like telephones or small band radio communications.
Hence, in these applications a determination of the filter
taps corresponding the transfer function 550 of Fig. 10 or
another amplitude/frequency characteristic into several
subbands 560 with different subband frequencies can be
carried out without employing an inventive filter
converter.
Fig. 11 shows an embodiment of an inventive filter
converter 104. As previously outlined in the context of
Fig. 3, the filter converter 104 comprises a complex
analysis filter bank 301 to which a (real valued) impulse
response signal indicative of an amplitude/frequency filter
characteristic can be supplied via an input 104a and via an
optional switch 600. As outlined before, the complex
analysis filter bank 301 converts the impulse response
signal into a plurality of complex valued subband signals
and the intermediate filter definition signal output at an
output 104b of the filter converter. As indicated in Fig.
la and Fig. 9, the output 104b of the filter converter 104
can be connected to a subband filtering 102.
As already mentioned earlier, each of the complex valued
subband signals of the complex modulated filter bank 301
corresponds to an impulse response for one of the
intermediate filters 190 for a subband signal in the
subband filtering 102 shown in Fig. la and 9. Typically,
the complex valued subband signals are significantly
shorter than the impulse response signal of the filter
characteristic provided at the input 104a in the time

domain. Furthermore, typically at least one of the complex
valued subband signals output at the output 104b comprises
at least two different non-vanishing values. Especially the
last feature distinguishes the output of the filter
converter 104 from a simple gain adjustment in the frame
work of filtering using a direct Fourier transform
procedure.
If, however, the filter converter 104 is not provided with
an impulse response signal indicative of an
amplitude/frequency filter characteristic, but a filter
definition signal, which comprises at least one of an
amplitude/frequency filter characteristic, a
phase/frequency filter characteristic or the filter taps in
the time domain or another domain of a filter, the filter
converter 104 comprises an impulse response generator 610
for converting the filter definition signal into the
impulse response signal, which is then provided via the
optional switch 600 to the complex analysis filter bank
301. In a concrete implementation, the impulse response
generator 610 can for instance calculate the impulse
response signal provided to the complex analysis filter
bank 301 by superposition of real valued oscillations
(Fourier synthesis), wherein the amplitude characteristics
and the phase characteristics of the intended filter to be
transferred into the complex subband domain are regarded as
defined by the definition signal provided to the input
104c. In other words, if at least one of an
amplitude/frequency characteristic and a phase/frequency
characteristic is applied to the impulse response generator
610, an impulse response signal can be computed by the
impulse response generator 610 by supposition of (harmonic)
oscillations considering the amplitude and phase relations
as defined by the filter definition signal.
Possible applications of both embodiments of the filter
apparatus and the filter generator and especially in the
field of high quality audio coding and decoding.

Recent developments in audio coding have provided means to
obtain a multi-channel signal impression over stereo
headphones. This is commonly done by downmixing a multi-
channel signal to stereo using the original multi-channel
signal and HRTF filters. It has been shown in prior art
that the parametric multi-channel audio decoder can be
combined with a binaural downmix algorithm making it
possible to render a multi-channel signal over headphones
without the need for first re-creating the multi-channel
signal from the transmitted downmix signal, and
subsequently downmixing it again by means of the HRTF
filters. However, this requires that the parameters for
recreating the multi-channel signal (e.g. IID, CLD
parameters) are combined with the HRTF filters, which in
turn requires a parameterization of the HRTF filters. This
requirement for a parameterization of the HRTF filters
imposes high limitation on the system, since HRTF filters
can be long and thus very hard to correctly model with a
parametric approach. This limitation makes it impossible to
use long HRTF filters for combined parametric multi-channel
and binaural downmix decoders. The crucial algorithmic
component required to obtain a proper combination of multi-
channel parameters and HRTF filters is to have access to a
representation of the given HRTF filters in the subband
domain assumed by the spatial parameters. This is exactly
what is offered by the embodiments of the present
invention. Once this representation is available, the HRTF
filters can be combined into 2N filters as a function of
the parametric multi-channel representation. This gives a
significant advantage in terms of computational complexity
over the method that first recreates the M channels and
then applies 2M filtering operations.
An example of a different application of the method
employed by embodiments of the current invention is the
efficient compensation for non-perfect audio rendering
devices for audio content coded in the MPEG HE-AAC format

[ISO/IEC 14496-3:2001/AMDl:2003]. Such advanced filtering
steps, possibly including cross talk cancellation, can be
applied directly in the subband domain prior to the time
domain synthesis.
Other developments in audio coding has made methods
available to recreate a multi-channel representation of an
audio signal based on a stereo (or mono) signal and
corresponding control data. These methods differ
substantially from older matrix based solution such as
Dolby® Prologic, since additional control data is
transmitted to control the re-creation, also referred to as
up-mix, of the surround channels based on the transmitted
mono or stereo channels.
Hence, such a parametric multi-channel audio decoder, e.g.
MPEG Surround reconstructs N channels based on M
transmitted channels, where N>M, and the additional
control data. The additional control data represents a
significantly lower data rate than that required for
transmission of all N channels, making the coding very
efficient while at the same time ensuring compatibility
with both M channel devices and N channel devices. [J.
Breebaart et al. "MPEG spatial audio coding / MPEG
Surround: overview and current status", Proc. 119th AES
convention, New York, USA, October 2005, Preprint 6447].
These parametric surround coding methods usually comprise a
parameterization of the surround signal based on Channel
Level Difference (CLD) and Inter-channel coherence/cross-
correlation (ICC). These parameters describe power ratios
and correlation between channel pairs in the up-mix
process. Further Channel Prediction Coefficients (CPC) are
also used in prior art to predict intermediate or output
channels during the up-mix procedure.
Depending on certain implementation requirements of the
inventive methods, the inventive methods can be implemented

in hardware or in software. The implementation can be
performed using a digital storage medium, in particular a
disc, CD or a DVD having an electronically readable control
signal stop thereon, which cooperates with a programmable
computer system in such that an embodiment of the inventive
methods is performed. Generally, an embodiment of the
present invention is, therefore, a computer program product
with a program code stored on an machine-readable carrier,
the program code being operative for performing the
inventive methods when the computer program product runs on
a computer or a processor. In other words, embodiments of
the inventive methods are, therefore, a computer program
having a program code for performing at least one of the
inventive methods when the computer program runs of a
computer.
While the foregoing has been particularly shown and
described with references to particular embodiments
thereof, it will be understood by those skilled in the art
that various other changes in the form and details maybe
made without departing from the spiritual scope thereof.
It is to be understood that various changes may be made in
adapting to different embodiments without departing from
the broader concept disclosed herein and comprehend by the
claims that follows.

CLAIMS
1. Filter apparatus for filtering a time domain input
signal to obtain a time domain output signal, which is
a representation of the time domain input signal
filtered using a filter characteristic having an non-
uniform amplitude/frequency characteristic,
comprising:
a complex analysis filter bank (101) for generating L
complex subband signals from the time domain input
signal;
a plurality of intermediate filters (190), each
intermediate filter (190) having a finite impulse
response comprising (KH + KQ - 1) filter taps, wherein
one intermediate filter is provided for each complex
subband signal;
a complex synthesis filter bank (103) for synthesizing
the output of the intermediate filters (190) to obtain
the time domain output signal,
a filter tap generator (104) comprising a complex
modulated filter bank (301) based on a prototype
filter comprising KQ • L taps for filtering a finite
impulse response signal indicative of the
amplitude/frequency filter characteristic in the time
domain and comprising KH . L filter taps to obtain L
complex valued subband signals as an intermediate
filter definition signal,
wherein each complex valued subband signal of the
complex modulated filter bank of the filter tap
generator corresponds to an impulse response for one
intermediate filter (190) comprising (KH + KQ - 1)
filter taps;

wherein at least one of the complex valued subband
signals of the complex modulated filter bank of the
filter tap generator comprises at least two different
non-vanishing values;
wherein each complex valued subband signal of the
modulated filter bank of the filter tap generator
comprising (KH + KQ - 1) filter taps is shorter than
the impulse response signal comprising KH • L filter
taps provided to the filter tap generator;
wherein the plurality of intermediate filters is
operative to receive the intermediate filter
definition signal from the filter tap generator (104);
wherein each intermediate filter (190) of the
plurality of intermediate filters is operative to have
an impulse response depending on the intermediate
filter definition signal;
wherein at least one of the intermediate filters (190)
of the plurality of the intermediate filters (190) has
a non-uniform amplitude/frequency characteristic;
wherein the non-uniform amplitude/frequency
characteristics of the plurality of intermediate
filters together represent the non-uniform filter
characteristic; and
wherein L, KQ and KH are positive integers.
2. Filter apparatus according to claim 1, wherein at
least one of the immediate filters (190) has a low
pass filter characteristic, a high pass filter
characteristic, a band pass filter characteristic, a
band rejection filter characteristic or a notch filter
characteristic.

3. Filter apparatus according to any of the preceding
claims, wherein the intermediate filters (190) of the
plurality of intermediate filters (190) are finite
impulse response filters.
4. Filter apparatus according to any of the preceding
claims, wherein the plurality of intermediate filter
(190) is operative to receive the intermediate filter
definition signal from a data base (500) or from a
processor (510).
5. Filter apparatus according to any of the preceding
claims, wherein the complex analysis filter bank (101)
is operative to output L complex subband signals,
wherein the plurality of intermediate filters (190)
comprises L intermediate filters (190), wherein the
complex synthesis filter bank (103) is operative to
synthesize the output of the L intermediate filters
(190), and wherein L is a positive integer greater
than 1.
6. Filter apparatus according to claim 5, wherein the
complex analysis filter bank (101) , the plurality of
intermediate filters (190) and the complex synthesis
filter bank (103) is operative to have L = 64.
7. Filter apparatus according to any of the claims 5 or
6, wherein the plurality of intermediate filters (190)
is operative to filter the complex subband signals
based on the equation

wherein n is an integer in the range from 0 to (L-1)
indicating an index of the subband signals, wherein L
and k are integers, wherein dn(k) is the output of the
intermediate filter (190) of the subband signal with

the index n, wherein cn(k) is the subband signal with
the index n, and wherein gn(1) is the impulse response
of the intermediate filter (190) for the subband
signal with the index n.
8. Filter apparatus according to any of the claims 5 to
7, wherein the intermediate filter (190) with an index
n has an impulse response gn(k), which is based on the
equation

wherein n is an integer in the range from 0 to (L-1)
indicating the index of the subband signal, wherein k
and v are integers, wherein h(v) is the response of a
filter having the filter characteristic, wherein n =
3.1415926... is the circular number, wherein i = V-1 is
the complex unit, and wherein q(v) are filter taps of
a real valued prototype filter.
9. Filter apparatus according to any of the claims 5 to
8, wherein at least one of the intermediate filters
(190) with an index n has an impulse response gn(k),
which is based on the equation

wherein Nh is the length of the impulse response h(u)
of a filter having the filter characteristic, wherein
n = 3.1415926... is the circular number, wherein i =
is the complex unit, and wherein q(v) are filter
taps of a real valued prototype filter.

10. Filter apparatus according to any of the claims 8 or
9, wherein the intermediate filters (190) are adapted
so that the prototype filter taps q(v) fulfil for
integers v from 0 to 191 the relations:
-0.204 ≤ q[0] ≤ -0.202
-0.199 ≤ q[l] ≤ -0.197
-0.194 ≤ q[2] ≤ -0.192
-0.189 ≤ q[3] ≤ -0.187
-0.183 ≤ q[4] ≤ -0.181
-0.178 ≤ q[5] ≤ -0.176
-0.172 ≤ q[6] ≤ -0.170
-0.166 ≤ q[7] ≤ -0.164
-0.160 ≤ q[8] ≤ -0.158
-0.154 ≤ q[9] ≤ -0.152
-0.148 ≤ q[10] ≤ -0.146
-0.142 ≤ q[ll] ≤ -0.140
-0.135 ≤ q[12] ≤ -0.133
-0.129 ≤ q[13] ≤ -0.127
-0.122 ≤ q[14] ≤ -0.120
-0.116 ≤ q[15] ≤ -0.114
-0.109 ≤ q[16] ≤ -0.107
-0.102 ≤ q[17] ≤ -0.100
-0.096 ≤ q[18] ≤ -0.094
-0.089 ≤ q[19] ≤ -0.087
-0.082 ≤ q[20] ≤ -0.080
-0.075 ≤ q[21] ≤ -0.073
-0.068 ≤ q[22] ≤ -0.066
-0.061 ≤ q[23] ≤ -0.059
-0.054 ≤ q[24] ≤ -0.052
-0.046 ≤ q[25] ≤ -0.044
-0.039 ≤ q[26] ≤ -0.037
-0.032 ≤ q[27] ≤ -0.030
-0.024 ≤ q[28] ≤ -0.022
-0.017 ≤ q[29] ≤ -0.015
-0.009 ≤ q[30] ≤ -0.007
-0.002 ≤ q[31] ≤ 0.000
0.006 ≤ q[32] ≤ 0.008

0.014 ≤ q[33] ≤ 0.016
0.021 ≤ q[34] ≤ 0.023
0.029 ≤ q[35] ≤ 0.031
0.037 ≤ q[36] ≤ 0.039
0.045 ≤ q[37] ≤ 0.047
0.054 ≤ q[38] ≤ 0.056
0.062 ≤ q[39] ≤ 0.064
0.070 ≤ q[40] ≤ 0.072
0.079 ≤ q[41] ≤ 0.081
0.087 ≤ q[42] ≤ 0.089
0.096 ≤ q[43] ≤ 0.098
0.105 ≤ q[44] ≤ 0.107
0.113 ≤ q[45] ≤ 0.115
0.122 ≤ q[46] ≤ 0.124
0.132 ≤ q[47] ≤ 0.134
0.141 ≤ q[48] ≤ 0.143
0.150 ≤ q[49] ≤ 0.152
0.160 ≤ q[50] ≤ 0.162
0.170 ≤ q[51] ≤ 0.172
0.180 ≤ q[52] ≤ 0.182
0.190 ≤ q[53] ≤ 0.192
0.200 ≤ q[54] ≤ 0.202
0.210 ≤ q[55] ≤ 0.212
0.221 ≤ q[56] ≤ 0.223
0.232 ≤ q[57] ≤ 0.234
0.243 ≤ q[58] ≤ 0.245
0.254 ≤ q[59] ≤ 0.256
0.266 ≤ q[60] ≤ 0.268
0.278 ≤ q[61] ≤ 0.280
0.290 ≤ q[62] ≤ 0.292
0.303 ≤ q[63] ≤ 0.305
0.902 ≤ q[64] ≤ 0.904
0.909 ≤ q[65] ≤ 0.911
0.917 ≤ q[66] ≤ 0.919
0.924 ≤ q[67] ≤ 0.926
0.930 ≤ q[68] ≤ 0.932
0.936 ≤ q[69] ≤ 0.938
0.942 ≤ q[70] ≤ 0.944

0.947 ≤ q[71] ≤ 0.949
0.952 ≤ q[72] ≤ 0.954
0.957 ≤ q[73] ≤ 0.959
0.961 ≤ q[74] ≤ 0.963
0.965 ≤ q[75] ≤ 0.967
0.969 ≤ q[76] ≤ 0.971
0.972 ≤ q[77] ≤ 0.974
0.975 ≤ q[78] ≤ 0.977
0.978 ≤ q[79] ≤ 0.980
0.981 ≤ q[80] ≤ 0.983
0.984 ≤ q[81] ≤ 0.986
0.986 ≤ q[82] ≤ 0.988
0.988 ≤ q[83] ≤ 0.990
0.990 ≤ q[84] ≤ 0.992
0.992 ≤ q[85] ≤ 0.994
0.993 ≤ q[86] ≤ 0.995
0.995 ≤ q[87] ≤ 0.997
0.996 ≤ q[88] ≤ 0.998
0.997 ≤ q[89] ≤ 0.999
0.998 ≤ q[90] ≤ 1.000
0.999 ≤ q[91] ≤ 1.001
0.999 ≤ q[92] ≤ 1.001
1.000 ≤ q[93] ≤ 1.002
1.000 ≤ q[94] ≤ 1.002
1.000 ≤ q[95] ≤ 1.002
1.000 ≤ q[96] ≤ 1.002
1.000 ≤ q[97] ≤ 1.002
0.999 ≤ q[98] ≤ 1.001
0.999 ≤ q[99] ≤ 1.001
0.998 ≤ q[100] ≤ 1.000
0.997 ≤ q[101] ≤ 0.999
0.996 ≤ q[102] ≤ 0.998
0.995 ≤ q[103] ≤ 0.997
0.993 ≤ q[104] ≤ 0.995
0.992 ≤ q[105] ≤ 0.994
0.990 ≤ q[106] ≤ 0.992
0.988 ≤ q[107] ≤ 0.990
0.986 ≤ q[108] ≤ 0.988

0.984 ≤ q[109] ≤ 0.986
0.981 ≤ q[110] ≤ 0.983
0.978 ≤ q[111] ≤ 0.980
0.975 ≤ q[112] ≤ 0.977
0.972 ≤ q[113] ≤ 0.974
0.969 ≤ q[114] ≤ 0.971
0.965 ≤ q[115] ≤ 0.967
0.961 ≤ q[116] ≤ 0.963
0.957 ≤ q[117] ≤ 0.959
0.952 ≤ q[118] ≤ 0.954
0.947 ≤ q[119] ≤ 0.949
0.942 ≤ q[120] ≤ 0.944
0.936 ≤ q[121] ≤ 0.938
0.930 ≤ q[122] ≤ 0.932
0.924 ≤ q[123] ≤ 0.926
0.917 ≤ q[124] ≤ 0.919
0.909 ≤ q[125] ≤ 0.911
0.902 ≤ q[126] ≤ 0.904
0.893 ≤ q[127] ≤ 0.895
0.290 ≤ q[128] ≤ 0.292
0.278 ≤ q[129] ≤ 0.280
0.266 ≤ q[130] ≤ 0.268
0.254 ≤ q[131] ≤ 0.256
0.243 ≤ q[132] ≤ 0.245
0.232 ≤ q[133] ≤ 0.234
0.221 ≤ q[134] ≤ 0.223
0.210 ≤ q[135] ≤ 0.212
0.200 ≤ q[136] ≤ 0.202
0.190 ≤ q[137] ≤ 0.192
0.180 ≤ qtl38] ≤ 0.182
0.170 ≤ q[139] ≤ 0.172
0.160 ≤ q[140] ≤ 0.162
0.150 ≤ q[141] ≤ 0.152
0.141 ≤ q[142] ≤ 0.143
0.132 ≤ q[143] ≤ 0.134
0.122 ≤ q[144] ≤ 0.124
0.113 ≤ q[145] ≤ 0.115
0.105 ≤ q[146] ≤ 0.107

0.096 ≤ q[147] ≤ 0.098
0.087 ≤ q[148] ≤ 0.089
0.079 ≤ q[149] ≤ 0.081
0.070 ≤ q[150] ≤ 0.072
0.062 ≤ q[151] ≤ 0.064
0.054 ≤ q[152] ≤ 0.056
0.045 ≤ q[153] ≤ 0.047
0.037 ≤ q[154] ≤ 0.039
0.029 ≤ q[155] ≤ 0.031
0.021 ≤ q[156] ≤ 0.023
0.014 ≤ q[157] ≤ 0.016
0.006 ≤ q[158] ≤ 0.008
-0.002 ≤ q[159] ≤ 0.000
-0.009 ≤ q[160] ≤ -0.007
-0.017 ≤ q[161] ≤ -0.015
-0.024 ≤ q[162] ≤ -0.022
-0.032 ≤ q[163] ≤ -0.030
-0.039 ≤ q[164] ≤ -0.037
-0.046 ≤ q[165] ≤ -0.044
-0.054 ≤ q[166] ≤ -0.052
-0.061 ≤ q[167] ≤ -0.059
-0.068 ≤ q[168] ≤ -0.066
-0.075 ≤ q[169] ≤ -0.073
-0.082 ≤ q[170] ≤ -0.080
-0.089 ≤ q[171] ≤ -0.087
-0.096 ≤ q[172] ≤ -0.094
-0.102 ≤ q[173] ≤ -0.100
-0.109 ≤ q[174] ≤ -0.107
-0.116 ≤ q[175] ≤ -0.114
-0.122 ≤ q[176] ≤ -0.120
-0.129 ≤ q[177] ≤ -0.127
-0.135 ≤ q[178] ≤ -0.133
-0.142 ≤ q[179] ≤ -0.140
-0.148 ≤ q[180] ≤ -0.146
-0.154 ≤ q[181] ≤ -0.152
-0.160 ≤ q[182] ≤ -0.158
-0.166 ≤ q[183] ≤ -0.164
-0.172 ≤ q[184] ≤ -0.170

-0.178 ≤ q[185] ≤ -0.176
-0.183 ≤ q[186] ≤ -0.181
-0.189 ≤ q[187] ≤ -0.187
-0.194 ≤ q[188] ≤ -0.192
-0.199 ≤ q[189] ≤ -0.197
-0.204 ≤ q[190] ≤ -0.202
-0.209 ≤ q[191] ≤ -0.207.
11. Filter apparatus according to any of the claims 8 to
10, wherein the intermediate filters (190) are adapted
so that the prototype filter taps q(v) fulfil for
integers v from 0 to 191 the relations:
-0.20294 ≤ q[0] ≤ -0.20292
-0.19804 ≤ q[l] ≤ -0.19802
-0.19295 ≤ q[2] ≤ -0.19293
-0.18768 ≤ q[3] ≤ -0.18766
-0.18226 ≤ q[4] ≤ -0.18224
-0.17668 ≤ q[5] ≤ -0.17666
-0.17097 ≤ q[6] ≤ -0.17095
-0.16514 ≤ q[7] ≤ -0.16512
-0.15919 ≤ q[8] ≤ -0.15917
-0.15313 ≤ q[9] ≤ -0.15311
-0.14697 ≤ q[10] ≤ -0.14695
-0.14071 ≤ q[ll] ≤ -0.14069
-0.13437 ≤ q[12] ≤ -0.13435
-0.12794 ≤ q[13] ≤ -0.12792
-0.12144 ≤ q[14] ≤ -0.12142
-0.11486 ≤ q[15] ≤ -0.11484
-0.10821 ≤ q[16] ≤ -0.10819
-0.10149 ≤ q[17] ≤ -0.10147
-0.09471 ≤ q[18] ≤ -0.09469
-0.08786 ≤ q[19] ≤ -0.08784
-0.08095 ≤ q[20] ≤ -0.08093
-0.07397 ≤ q[21] ≤ -0.07395
-0.06694 ≤ q[22] ≤ -0.06692
-0.05984 ≤ q[23] ≤ -0.05982
-0.05269 ≤ q[24] ≤ -0.05267

-0.04547 ≤ q[25] ≤ -0.04545
-0.03819 ≤ q[26] ≤ -0.03817
-0.03085 ≤ q[27] ≤ -0.03083
-0.02345 ≤ q[28] ≤ -0.02343
-0.01598 ≤ q[29] ≤ -0.01596
-0.00845 ≤ q[30] ≤ -0.00843
-0.00084 ≤ q[31] ≤ -0.00082
0.00683 ≤ q[32] ≤ 0.00685
0.01458 ≤ q[33] ≤ 0.01460
0.02240 ≤ q[34] ≤ 0.02242
0.03030 ≤ q[35] ≤ 0.03032
0.03828 ≤ q[36] ≤ 0.03830
0.04635 ≤ q[37] ≤ 0.04637
0.05451 ≤ q[38] ≤ 0.05453
0.06275 ≤ q[39] ≤ 0.06277
0.07110 ≤ q[40] ≤ 0.07112
0.07954 ≤ q[41] ≤ 0.07956
0.08809 ≤ q[42] ≤ 0.08811
0.09675 ≤ q[43] ≤ 0.09677
0.10552 ≤ q[44] ≤ 0.10554
0.11442 ≤ q[45] ≤ 0.11444
0.12344 ≤ q[46] ≤ 0.12346
0.13259 ≤ q[47] ≤ 0.13261
0.14189 ≤ q[48] ≤ 0.14191
0.15132 ≤ q[49] ≤ 0.15134
0.16091 ≤ q[50] ≤ 0.16093
0.17066 ≤ q[51] ≤ 0.17068
0.18058 ≤ q[52] ≤ 0.18060
0.19067 ≤ q[53] ≤ 0.19069
0.20095 ≤ q[54] ≤ 0.20097
0.21143 ≤ q[55] ≤ 0.21145
0.22211 ≤ q[56] ≤ 0.22213
0.23300 ≤ q[57] ≤ 0.23302
0.24412 ≤ q[58] ≤ 0.24414
0.25549 ≤ q[59] ≤ 0.25551
0.26711 ≤ q[60] ≤ 0.26713
0.27899 ≤ q[61] ≤ 0.27901
0.29117 ≤ q[62] ≤ 0.29119

0.30364 ≤ q[63] ≤ 0.30366
0.90252 ≤ q[64] ≤ 0.90254
0.91035 ≤ q[65] ≤ 0.91037
0.91769 ≤ q[66] ≤ 0.91771
0.92457 ≤ q[67] ≤ 0.92459
0.93101 ≤ q[68] ≤ 0.93103
0.93705 ≤ q[69] ≤ 0.93707
0.94270 ≤ q[70] ≤ 0.94272
0.94800 ≤ q[71] ≤ 0.94802
0.95295 ≤ q[72] ≤ 0.95297
0.95758 ≤ q[73] ≤ 0.95760
0.96190 ≤ q[74] ≤ 0.96192
0.96593 ≤ q[75] ≤ 0.96595
0.96968 ≤ q[76] ≤ 0.96970
0.97317 ≤ q[77] ≤ 0.97319
0.97641 ≤ q[78] ≤ 0.97643
0.97940 ≤ q[79] ≤ 0.97942
0.98217 ≤ q[80] ≤ 0.98219
0.98472 ≤ q[81] ≤ 0.98474
0.98706 ≤ q[82] ≤ 0.98708
0.98919 ≤ q[83] ≤ 0.98921
0.99113 ≤ q[84] ≤ 0.99115
0.99288 ≤ q[85] ≤ 0.99290
0.99444 ≤ q[86] ≤ 0.99446
0.99583 ≤ q[87] ≤ 0.99585
0.99704 ≤ q[88] ≤ 0.99706
0.99809 ≤ q[89] ≤ 0.99811
0.99896 ≤ q[90] ≤ 0.99898
0.99967 ≤ q[91] ≤ 0.99969
1.00023 ≤ q[92] ≤ 1.00025
1.00062 ≤ q[93] ≤ 1.00064
1.00086 ≤ q[94] ≤ 1.00088
1.00093 ≤ q[95] ≤ 1.00095
1.00086 ≤ q[96] ≤ 1.00088
1.00062 ≤ q[97] ≤ 1.00064
1.00023 ≤ q[98] ≤ 1.00025
0.99967 ≤ q[99] ≤ 0.99969
0.99896 ≤ q[100] ≤ 0.99898

0.99809 ≤ q[101] ≤ 0.99811
0.99704 ≤ q[102] ≤ 0.99706
0.99583 ≤ q[103] ≤ 0.99585
0.99444 ≤ q[104] ≤ 0.99446
0.99288 ≤ q[105] ≤ 0.99290
0.99113 ≤ q[106] ≤ 0.99115
0.98919 ≤ q[107] ≤ 0.98921
0.98706 ≤ q[108] ≤ 0.98708
0.98472 ≤ q[109] ≤ 0.98474
0.98217 ≤ q[110] ≤ 0.98219
0.97940 ≤ q[lll] ≤ 0.97942
0.97641 ≤ q[112] ≤ 0.97643
0.97317 ≤ q[113] ≤ 0.97319
0.96968 ≤ q[114] ≤ 0.96970
0.96593 ≤ q[115] ≤ 0.96595
0.96190 ≤ q[116] ≤ 0.96192
0.95758 ≤ q[117] ≤ 0.95760
0.95295 ≤ q[118] ≤ 0.95297
0.94800 ≤ q[119] ≤ 0.94802
0.94270 ≤ q[120] ≤ 0.94272
0.93705 ≤ q[121] ≤ 0.93707
0.93101 ≤ q[122] ≤ 0.93103
0.92457 ≤ q[123] ≤ 0.92459
0.91769 ≤ q[124] ≤ 0.91771
0.91035 ≤ q[125] ≤ 0.91037
0.90252 ≤ q[126] ≤ 0.90254
0.89416 ≤ q[127] ≤ 0.89418
0.29117 ≤ q[128] ≤ 0.29119
0.27899 ≤ q[129] ≤ 0.27901
0.26711 ≤ q[130] ≤ 0.26713
0.25549 ≤ q[131] ≤ 0.25551
0.24412 ≤ q[132] ≤ 0.24414
0.23300 ≤ q[133] ≤ 0.23302
0.22211 ≤ q[134] ≤ 0.22213
0.21143 ≤ q[135] ≤ 0.21145
0.20095 ≤ q[136] ≤ 0.20097
0.19067 ≤ q[137] ≤ 0.19069
0.18058 ≤ q[138] ≤ 0.18060

0.17066 ≤ q[139] ≤ 0.17068
0.16091 ≤ q[140] ≤ 0.16093
0.15132 ≤ q[141] ≤ 0.15134
0.14189 ≤ q[142] ≤ 0.14191
0.13259 ≤ q[143] ≤ 0.13261
0.12344 ≤ q[144] ≤ 0.12346
0.11442 ≤ q[145] ≤ 0.11444
0.10552 ≤ q[146] ≤ 0.10554
0.09675 ≤ q[147] ≤ 0.09677
0.08809 ≤ q[148] ≤ 0.08811
0.07954 ≤ q[149] ≤ 0.07956
0.07110 ≤ q[150] ≤ 0.07112
0.06275 ≤ q[151] ≤ 0.06277
0.05451 ≤ q[152] ≤ 0.05453
0.04635 ≤ q[153] ≤ 0.04637
0.03828 ≤ q[154] ≤ 0.03830
0.03030 ≤ q[155] ≤ 0.03032
0.02240 ≤ q[156] ≤ 0.02242
0.01458 ≤ q[157] ≤ 0.01460
0.00683 ≤ q[158] ≤ 0.00685
-0.00084 ≤ q[159] ≤ -0.00082
-0.00845 ≤ q[160] ≤ -0.00843
-0.01598 ≤ q[161] ≤ -0.01596
-0.02345 ≤ q[162] ≤ -0.02343
-0.03085 ≤ q[163] ≤ -0.03083
-0.03819 ≤ q[164] ≤ -0.03817
-0.04547 ≤ q[165] ≤ -0.04545
-0.05269 ≤ q[166] ≤ -0.05267
-0.05984 ≤ q[167] ≤ -0.05982
-0.06694 ≤ q[168] ≤ -0.06692
-0.07397 ≤ q[169] ≤ -0.07395
-0.08095 ≤ q[170] ≤ -0.08093
-0.08786 ≤ q[171] ≤ -0.08784
-0.09471 ≤ q[172] ≤ -0.09469
-0.10149 ≤ q[173] ≤ -0.10147
-0.10821 ≤ q[174] ≤ -0.10819
-0.11486 ≤ q[175] ≤ -0.11484
-0.12144 ≤ q[176] ≤ -0.12142

-0.12794 ≤ q[177] ≤ -0.12792
-0.13437 ≤ q[178] ≤ -0.13435
-0.14071 ≤ q[179] ≤ -0.14069
-0.14697 ≤ q[180] ≤ -0.14695
-0.15313 ≤ q[181] ≤ -0.15311
-0.15919 ≤ q[182] ≤ -0.15917
-0.16514 ≤ q[183] ≤ -0.16512
-0.17097 ≤ q[184] ≤ -0.17095
-0.17668 ≤ q[185] ≤ -0.17666
-0.18226 ≤ q[186] ≤ -0.18224
-0.18768 ≤ q[187] ≤ -0.18766
-0.19295 ≤ q[188] ≤ -0.19293
-0.19804 ≤ q[189] ≤ -0.19802
-0.20294 ≤ q[190] ≤ -0.20292
-0.20764 ≤ q[191] ≤-0.20762
12. Filter apparatus according to any of the claims 8 to
11, wherein the intermediate filters (190) are
adapted, so that the real valued prototype filter
coefficients q(v) for integer v in the range from 0
to 191 are given by
q[0] = -0.2029343380
q[l] = -0.1980331588
q[2] = -0.1929411519
q[3] = -0.1876744222
q[4] = -0.1822474011
q[5] = -0.1766730202
q[6] = -0.1709628636
q[7] = -0.1651273005
q[8] = -0.1591756024
q[9] = -0.1531160455
q[10] = -0.1469560005
q[ll] = -0.1407020132
q[12] = -0.1343598738
q[13] = -0.1279346790
q[14] = -0.1214308876
q[15] = -0.1148523686
q[16] = -0.1082024454

q[17] = -0.1014839341
q[18] = -0.0946991783
q[19] = -0.0878500799
q[20] = -0.0809381268
q[21] = -0.0739644174
q[22] = -0.0669296831
q[23] = -0.0598343081
q[24] = -0.0526783466
q[25] = -0.0454615388
q[26] = -0.0381833249
q[27] = -0.0308428572
q[28] = -0.0234390115
q[29] = -0.0159703957
q[30] = -0.0084353584
q[31] = -0.0008319956
q[32] = 0.0068418435
q[33] = 0.0145885527
q[34] = 0.0224107648
q[35] = 0.0303113495
q[36] = 0.0382934126
q[37] = 0.0463602959
q[38] = 0.0545155789
q[39] = 0.0627630810
q[40] = 0.0711068657
q[41] = 0.0795512453
q[42] = 0.0881007879
q[43] = 0.0967603259
q[44] = 0.1055349658
q[45] = 0.1144301000
q[46] = 0.1234514222
q[47] = 0.1326049434
q[48] = 0.1418970123
q[49] = 0.1513343370
q[50] = 0.1609240126
q[51] = 0.1706735517
q[52] = 0.1805909194
q[53] = 0.1906845753
q[54] = 0.2009635191

q[55] = 0.2114373458
q[56] = 0.2221163080
q[57] = 0.2330113868
q[58] = 0.2441343742
q[59] = 0.2554979664
q[60] = 0.2671158700
q[61] = 0.2790029236
q[62] = 0.2911752349
q[63] = 0.3036503350
q[64] = 0.9025275713
q[65] = 0.9103585196
q[66] = 0.9176977825
q[67] = 0.9245760683
q[68] = 0.9310214581
q[69] = 0.9370596739
q[70] = 0.9427143143
q[71] = 0.9480070606
q[72] = 0.9529578566
q[73] = 0.9575850672
q[74] = 0.9619056158
q[75] = 0.9659351065
q[76] = 0.9696879297
q[77] = 0.9731773547
q[78] = 0.9764156119
q[79] = 0.9794139640
q[80] = 0.9821827692
q[81] = 0.9847315377
q[82] = 0.9870689790
q[83] = 0.9892030462
q[84] = 0.9911409728
q[85] = 0.9928893067
q[86] = 0.9944539395
q[87] = 0.9958401318
q[88] = 0.9970525352
q[89] = 0.9980952118
q[90] = 0.9989716504
q[91] = 0.9996847806
q[92] = 1.0002369837

q[93] = 1.0006301028
q[94] = 1.0008654482
q[95] = 1.0009438063
q[96] = 1.0008654482
q[97] = 1.0006301028
q[98] = 1.0002369837
q[99] = 0.9996847806
q[100] = 0.9989716504
q[101] = 0.9980952118
q[102] = 0.9970525352
q[103] = 0.9958401318
q[104] = 0.9944539395
q[105] = 0.9928893067
q[106] = 0.9911409728
q[107] = 0.9892030462
q[108] = 0.9870689790
q[109] = 0.9847315377
q[110] = 0.9821827692
q[lll] = 0.9794139640
q[112] = 0.9764156119
q[113] = 0.9731773547
q[114] = 0.9696879297
q[115] = 0.9659351065
q[116] = 0.9619056158
q[117] = 0.9575850672
q[118] = 0.9529578566
q[119] = 0.9480070606
q[120] = 0.9427143143
q[121] = 0.9370596739
q[122] = 0.9310214581
q[123] = 0.9245760683
q[124] = 0.9176977825
q[125] = 0.9103585196
q[126] = 0.9025275713
q[127] = 0.8941712974
q[128] = 0.2911752349
q[129] = 0.2790029236
q[130] = 0.2671158700

q[131] = 0.2554979664
q[132] = 0.2441343742
q[133] = 0.2330113868
q[134] = 0.2221163080
q[135] = 0.2114373458
q[136] = 0.2009635191
q[137] = 0.1906845753
q[138] = 0.1805909194
q[139] = 0.1706735517
q[140] = 0.1609240126
q[141] = 0.1513343370
q[142] = 0.1418970123
q[143] = 0.1326049434
q[144] = 0.1234514222
q[145] = 0.1144301000
q[146] = 0.1055349658
q[147] = 0.0967603259
q[148] = 0.0881007879
q[149] = 0.0795512453
q[150] = 0.0711068657
q[151] = 0.0627630810
q[152] = 0.0545155789
q[153] = 0.0463602959
q[154] = 0.0382934126
q[155] = 0.0303113495
q[156] = 0.0224107648
q[157] = 0.0145885527
q[158] = 0.0068418435
q[159] = -0.0008319956
q[160] = -0.0084353584
q[161] = -0.0159703957
q[162] = -0.0234390115
q[163] = -0.0308428572
q[164] = -0.0381833249
q[165] = -0.0454615388
q[166] = -0.0526783466
q[167] = -0.0598343081
q[168] = -0.0669296831

q[169] = -0.0739644174
q[170] = -0.0809381268
qtl71] = -0.0878500799
q[172] = -0.0946991783
q[173] = -0.1014839341
q[174] = -0.1082024454
q[175] = -0.1148523686
q[176] = -0.1214308876
q[177] = -0.1279346790
q[178] = -0.1343598738
q[179] = -0.1407020132
q[180] = -0.1469560005
q[181] = -0.1531160455
q[182] = -0.1591756024
q[183] = -0.1651273005
q[184] = -0.1709628636
q[185] = -0.1766730202
q[186] = -0.1822474011
q[187] = -0.1876744222
q[188] = -0.1929411519
q[189] = -0.1980331588
q[190] = -0.2029343380
q[191] = -0.2076267137
13. Filter apparatus according to any of preceding,
wherein the filter characteristic is based on an HRTF
filter characteristic.
14. Filter apparatus according to any of the preceding
claims, wherein the complex analysis filter bank (101)
comprises a downsampler (140) for each subband signal
output by the complex analysis filter bank (101).
15. Filter apparatus according to claim 14, wherein the
complex analysis filter bank (101) is adapted to
output L complex subband signals, wherein L is a
positive integer greater than 1, and wherein each of

the downsampler (140) is adapted to downsample the
subband signals by a factor of L.
16. Filter apparatus according to any of the preceding
claims, wherein the complex analysis filter bank (101)
comprises a complex modulated filter for each complex
subband signal based on a prototype filter.
17. Filter apparatus according to any of the preceding
claims, wherein the complex synthesis filter bank
(103) comprises an upsampler (160) for each of the
subband signals.
18. Filter apparatus according to claim 17, wherein the
complex synthesis filter bank (103) is operative to
synthesize L signals of the intermediate filters to
obtain the time domain output signal, wherein L is a
positive integer greater than 1, wherein the complex
synthesis filter bank (103) comprises L upsampler
(160) and wherein each of the upsampler (160) is
adapted for upsampling the output of the intermediate
filters (190) by a factor of L.
19. Filter apparatus according to any of the preceding
claims, wherein the complex synthesis filter bank
(103) comprises for each subband signal an
intermediate synthesis filter, wherein the complex
synthesis filter bank (103) comprises a real part
extractor (180) for each signal output by intermediate
synthesis filters (150), and wherein the complex
synthesis filter bank (103) further comprises an adder
(170) for adding the output of each of a the real part
extractor (180) to obtain the time domain output
signal.
20. Filter apparatus according to any of the claims 1 to
18, wherein the complex synthesis filter bank (103)
comprises an intermediate synthesis filter (150) for

each of the subband signals output by the intermediate
filters (190), wherein the complex synthesis filter
bank (103) further comprises an adder (170) for
summing up the ouputs of each intermediate synthesis
filters (150) and wherein the complex synthesis filter
bank (103) further comprises a real part extractor
(180) for extracting a real valued signal as the time
domain output signal from the output of the adder
(170) .
21. Filter apparatus according to any of the preceding
claims, wherein the filter apparatus further comprises
a gain adjuster for at least one subband signal or for
at least one signal output by intermediate filter
(190) for adjusting the gain.
22. Filtering apparatus according to any of the preceding
claims, wherein the filtering apparatus further
comprises a further intermediate filter for filtering
at least one of the complex valued subband signals or
for filtering at least one of the signals output by
one of the intermediate filters (190).
23. Filter tap generator (104) for providing an
intermediate filter definition signal comprising
filter taps for intermediate subband filters based on
an impulse response signal indicative of an
amplitude/frequency filter characteristic in a time
domain,
comprising:
a complex modulated filter bank (301) for filtering
the impulse response signal to obtain 64 complex
valued subband signals as the intermediate filter
definition signal,

wherein the complex modulated filter bank (301) is
adapted to provide complex valued subband signals
having values gn (k) based on the equation

wherein Nh is the length of the impulse response h(v)
of a filter having the filter characteristic, wherein
π = 3.1415926... is the circular number, wherein i =
is the complex unit, and wherein q(v) are filter
taps of a real valued prototype filter;
wherein each complex valued subband signal of the
complex modulated filter bank (301) corresponds to an
impulse response for an intermediate filter for a
subband signal;
wherein at least one of the complex valued subband
signals comprises at least two different non-vanishing
values; and
wherein each complex valued subband signal comprises
(Kh + 2) filter taps;
wherein Kh is given by
Kh=[Nh/64];
wherein the prototype filter taps q(v) fulfill for
integers v from 0 to 191 the relations:
-0.204 ≤ q[0] ≤ -0.202
-0.199 ≤ q[l] ≤ -0.197
-0.194 ≤ q[2] ≤ -0.192

-0.189 ≤ q[3] ≤ -0.187
-0.183 ≤ q[4] ≤ -0.181
-0.178 ≤ q[5] ≤ -0.176
-0.172 ≤ q[6] ≤ -0.170
-0.166 ≤ q[7] ≤ -0.164
-0.160 ≤ q[8] ≤ -0.158
-0.154 ≤ q[9] ≤ -0.152
-0.148 ≤ q[10] ≤ -0.146
-0.142 ≤ q[ll] ≤ -0.140
-0.135 ≤ q[12] ≤ -0.133
-0.129 ≤ q[13] ≤ -0.127
-0.122 ≤ q[14] ≤ -0.120
-0.116 ≤ q[15] ≤ -0.114
-0.109 ≤ q[16] ≤ -0.107
-0.102 ≤ q[17] ≤ -0.100
-0.096 ≤ q[18] ≤ -0.094
-0.089 ≤ q[19] ≤ -0.087
-0.082 ≤ q[20] ≤ -0.080
-0.075 ≤ q[21] ≤ -0.073
-0.068 ≤ q[22] ≤ -0.066
-0.061 ≤ q[23] ≤ -0.059
-0.054 ≤ q[24] ≤ -0.052
-0.046 ≤ q[25] ≤ -0.044
-0.039 ≤ q[26] ≤ -0.037
-0.032 ≤ q[27] ≤ -0.030
-0.024 ≤ q[28] ≤ -0.022
-0.017 ≤ q[29] ≤ -0.015
-0.009 ≤ q[30] ≤ -0.007
-0.002 ≤ q[31] ≤ 0.000
0.006 ≤ q[32] ≤ 0.008
0.014 ≤ q[33] ≤ 0.016
0.021 ≤ q[34] ≤ 0.023
0.029 ≤ q[35] ≤ 0.031
0.037 ≤ q[36] ≤ 0.039
0.045 ≤ q[37] ≤ 0.047
0.054 ≤ q[38] ≤ 0.056
0.062 ≤ q[39] ≤ 0.064
0.070 ≤ q[40] ≤ 0.072

0.079 ≤ q[41] ≤ 0.081
0.087 ≤ q[42] ≤ 0.089
0.096 ≤ q[43] ≤ 0.098
0.105 ≤ q[44] ≤ 0.107
0.113 ≤ q[45] ≤ 0.115
0.122 ≤ q[46] ≤ 0.124
0.132 ≤ q[47] ≤ 0.134
0.141 ≤ q[48] ≤ 0.143
0.150 ≤ q[49] ≤ 0.152
0.160 ≤ q[50] ≤ 0.162
0.170 ≤ q[51] ≤ 0.172
0.180 ≤ q[52] ≤ 0.182
0.190 ≤ q[53] ≤ 0.192
0.200 ≤ q[54] ≤ 0.202
0.210 ≤ q[55] ≤ 0.212
0.221 ≤ q[56] ≤ 0.223
0.232 ≤ q[57] ≤ 0.234
0.243 ≤ q[58] ≤ 0.245
0.254 ≤ q[59] ≤ 0.256
0.266 ≤ q[60] ≤ 0.268
0.278 ≤ q[61] ≤ 0.280
0.290 ≤ q[62] ≤ 0.292
0.303 ≤ q[63] ≤ 0.305
0.902 ≤ q[64] ≤ 0.904
0.909 ≤ q[65] ≤ 0.911
0.917 ≤ q[66] ≤ 0.919
0.924 ≤ q[67] ≤ 0.926
0.930 ≤ q[68] ≤ 0.932
0.936 ≤ q[69] ≤ 0.938
0.942 ≤ q[70] ≤ 0.944
0.947 ≤ q[71] ≤ 0.949
0.952 ≤ q[72] ≤ 0.954
0.957 ≤ q[73] ≤ 0.959
0.961 ≤ q[74] ≤ 0.963
0.965 ≤ q[75] ≤ 0.967
0.969 ≤ q[76] ≤ 0.971
0.972 ≤ q[77] ≤ 0.974
0.975 ≤ q[78] ≤ 0.977

0.978 ≤ q[79] ≤ 0.980
0.981 ≤ q[80] ≤ 0.983
0.984 ≤ q[81] ≤ 0.986
0.986 ≤ q[82] ≤ 0.988
0.988 ≤ q[83] ≤ 0.990
0.990 ≤ q[84] ≤ 0.992
0.992 ≤ q[85] ≤ 0.994
0.993 ≤ q[86] ≤ 0.995
0.995 ≤ q[87] ≤ 0.997
0.996 ≤ q[88] ≤ 0.998
0.997 ≤ q[89] ≤ 0.999
0.998 ≤ q[90] ≤ 1.000
0.999 ≤ q[91] ≤ 1.001
0.999 ≤ q[92] ≤ 1.001
1.000 ≤ q[93] ≤ 1.002
1.000 ≤ q[94] ≤ 1.002
1.000 ≤ q[95] ≤ 1.002
1.000 ≤ q[96] ≤ 1.002
1.000 ≤ q[97] ≤ 1.002
0.999 ≤ q[98] ≤ 1.001
0.999 ≤ q[99] ≤ 1.001
0.998 ≤ q[100] ≤ 1.000
0.997 ≤ q[101] ≤ 0.999
0.996 ≤ q[102] ≤ 0.998
0.995 ≤ q[103] ≤ 0.997
0.993 ≤ q[104] ≤ 0.995
0.992 ≤ q[105] ≤ 0.994
0.990 ≤ q[106] ≤ 0.992
0.988 ≤ q[107] ≤ 0.990
0.986 ≤ q[108] ≤ 0.988
0.984 ≤ q[109] ≤ 0.986
0.981 ≤ q[110] ≤ 0.983
0.978 ≤ q[lll] ≤ 0.980
0.975 ≤ q[112] ≤ 0.977
0.972 ≤ q[113] ≤ 0.974
0.969 ≤ q[114] ≤ 0.971
0.965 ≤ q[115] ≤ 0.967
0.961 ≤ q[116] ≤ 0.963

0.957 ≤ q[117] ≤ 0.959
0.952 ≤ q[118] ≤ 0.954
0.947 ≤ q[119] ≤ 0.949
0.942 ≤ q[120] ≤ 0.944
0.936 ≤ q[121] ≤ 0.938
0.930 ≤ q[122] ≤ 0.932
0.924 ≤ q[123] ≤ 0.926
0.917 ≤ q[124] ≤ 0.919
0.909 ≤ q[125] ≤ 0.911
0.902 ≤ q[126] ≤ 0.904
0.893 ≤ q[127] ≤ 0.895
0.290 ≤ q[128] ≤ 0.292
0.278 ≤ q[129] ≤ 0.280
0.266 ≤ q[130] ≤ 0.268
0.254 ≤ q[131] ≤ 0.256
0.243 ≤ q[132] ≤ 0.245
0.232 ≤ q[133] ≤ 0.234
0.221 ≤ q[134] ≤ 0.223
0.210 ≤ q[135] ≤ 0.212
0.200 ≤ q[136] ≤ 0.202
0.190 ≤ q[137] ≤ 0.192
0.180 ≤ q[138] ≤ 0.182
0.170 ≤ q[139] ≤ 0.172
0.160 ≤ q[140] ≤ 0.162
0.150 ≤ q[141] ≤ 0.152
0.141 ≤ q[142] ≤ 0.143
0.132 ≤ q[143] ≤ 0.134
0.122 ≤ q[144] ≤ 0.124
0.113 ≤ q[145] ≤ 0.115
0.105 ≤ q[146] ≤ 0.107
0.096 ≤ q[147] ≤ 0.098
0.087 ≤ q[148] ≤ 0.089
0.079 ≤ q[149] ≤ 0.081
0.070 ≤ q[150] ≤ 0.072
0.062 ≤ q[151] ≤ 0.064
0.054 ≤ q[152] ≤ 0.056
0.045 ≤ q[153] ≤ 0.047
0.037 ≤ q[154] ≤ 0.039

0.029 ≤ q[155] ≤ 0.031
0.021 ≤ q[156] ≤ 0.023
0.014 ≤ q[157] ≤ 0.016
0.006 ≤ q[158] ≤ 0.008
-0.002 ≤ q[159] ≤ 0.000
-0.009 ≤ q[160] ≤ -0.007
-0.017 ≤ q[161] ≤ -0.015
-0.024 ≤ q[162] ≤ -0.022
-0.032 ≤ q[163] ≤ -0.030
-0.039 ≤ q[164] ≤ -0.037
-0.046 ≤ q[165] ≤ -0.044
-0.054 ≤ q[166] ≤ -0.052
-0.061 ≤ q[167] ≤ -0.059
-0.068 ≤ q[168] ≤ -0.066
-0.075 ≤ q[169] ≤ -0.073
-0.082 ≤ q[170] ≤ -0.080
-0.089 ≤ q[171] ≤ -0.087
-0.096 ≤ q[172] ≤ -0.094
-0.102 ≤ q[173] ≤ -0.100
-0.109 ≤ q[174] ≤ -0.107
-0.116 ≤ q[175] ≤ -0.114
-0.122 ≤ q[176] ≤ -0.120
-0.129 ≤ q[177] ≤ -0.127
-0.135 ≤ q[178] ≤ -0.133
-0.142 ≤ q[179] ≤ -0.140
-0.148 ≤ q[180] ≤ -0.146
-0.154 ≤ q[181] ≤ -0.152
-0.160 ≤ q[182] ≤ -0.158
-0.166 ≤ q[183] ≤ -0.164
-0.172 ≤ q[184] ≤ -0.170
-0.178 ≤ q[185] ≤ -0.176
-0.183 ≤ q[186] ≤ -0.181
-0.189 ≤ q[187] ≤ -0.187
-0.194 ≤ q[188] ≤ -0.192
-0.199 ≤ q[189] ≤ -0.197
-0.204 ≤ q[190] ≤ -0.202
-0.209 ≤ q[191] ≤ -0.207 .

24. Filter generator (104) according to claim 23, wherein
the complex modulated filter bank (301) is adapted for
outputting at least one complex valued subband signal
as a linear combination of at least two values of the
impulse response signal.
25. Filter generator (104) according to any of the claims
23 to 24, wherein the complex modulated filter bank
(301) is adapted for filtering an impulse response
signal of a non-uniform amplitude/frequency filter
characteristic.
26. Filter generator (104) according to any of the claims
23 to 25, wherein the complex modulated filter bank
(301)is operative to filter the impulse response
signal, and wherein the impulse response signal is
based on a HRTF-related impulse response.
27. Filter generator (104) according to any of the claims
23 to 26, wherein the complex modulated filter bank
(301) is adapted to output L complex valued subband
signals, wherein L is a positive integer greater than
1.
28. Filter generator (104) according to claim 27, wherein
the complex modulated filter bank (301) is adapted for
providing the L complex valued subband signals
downsampled by a factor L.
29. Filter generator (104) according to any of the claims
27 to 28, wherein the complex modulated filter bank
(301) is adapted to output L = 64 complex valued
subband signals.
30. Filter generator (104) according to any of the claims
23 to 29, wherein the complex modulated filter bank
(301) is adapted to provide complex valued subband
signals having values gn (k) based on the equation


, wherein n is an integer in the range from 0 to (L-1)
indicating an index of the complex valued subband
signal, wherein k and v are integers, wherein h(v) is
the response of a filter having the filter
characteristic, wherein n = 3.1415926... is the circular
number, wherein is the complex unit, and
wherein q(v) are filter taps of a real valued
prototype filter.
Filter generator (104) according to any of the claims
23 to 30, wherein the complex modulated filter bank
(301) is adapted so that the prototype filter q(v)
fulfils for integers v from 0 to 191 the relations:
-0.20294 ≤ q[0] ≤ -0.20292
-0.19804 ≤ q[l] ≤ -0.19802
-0.19295 ≤ q[2] ≤ -0.19293
-0.18768 ≤ q[3] ≤ -0.18766
-0.18226 ≤ q[4] ≤ -0.18224
-0.17668 ≤ q[5] ≤ -0.17666
-0.17097 ≤ q[6] ≤ -0.17095
-0.16514 ≤ q[7] ≤ -0.16512
-0.15919 ≤ q[8] ≤ -0.15917
-0.15313 ≤ q[9] ≤ -0.15311
-0.14697 ≤ q[10] ≤ -0.14695
-0.14071 ≤ q[ll] ≤ -0.14069
-0.13437 ≤ q[12] ≤ -0.13435
-0.12794 ≤ q[13] ≤ -0.12792
-0.12144 ≤ q[14] ≤ -0.12142
-0.11486 ≤ q[15] ≤ -0.11484
-0.10821 ≤ q[16] ≤ -0.10819
-0.10149 ≤ q[17] ≤ -0.10147
-0.09471 ≤ q[18] ≤ -0.09469
-0.08786 ≤ q[19] ≤ -0.08784
-0.08095 ≤ q[20] ≤ -0.08093

-0.07397 ≤ q[21] ≤ -0.07395
-0.06694 ≤ q[22] ≤ -0.06692
-0.05984 ≤ q[23] ≤ -0.05982
-0.05269 ≤ q[24] ≤ -0.05267
-0.04547 ≤ q[25] ≤ -0.04545
-0.03819 ≤ q[26] ≤ -0.03817
-0.03085 ≤ q[27] ≤ -0.03083
-0.02345 ≤ q[28] ≤ -0.02343
-0.01598 ≤ q[29] ≤ -0.01596
-0.00845 ≤ q[30] ≤ -0.00843
-0.00084 ≤ q[31] ≤ -0.00082
0.00683 ≤ q[32] ≤ 0.00685
0.01458 ≤ q[33] ≤ 0.01460
0.02240 ≤ q[34] ≤ 0.02242
0.03030 ≤ q[35] ≤ 0.03032
0.03828 ≤ q[36] ≤ 0.03830
0.04635 ≤ q[37] ≤ 0.04637
0.05451 ≤ q[38] ≤ 0.05453
0.06275 ≤ q[39] ≤ 0.06277
0.07110 ≤ q[40] ≤ 0.07112
0.07954 ≤ q[41] ≤ 0.07956
0.08809 ≤ q[42] ≤ 0.08811
0.09675 ≤ q[43] ≤ 0.09677
0.10552 ≤ q[44] ≤ 0.10554
0.11442 ≤ q[45] ≤ 0.11444
0.12344 ≤ q[46] ≤ 0.12346
0.13259 ≤ q[47] ≤ 0.13261
0.14189 ≤ q[48] ≤ 0.14191
0.15132 ≤ q[49] ≤ 0.15134
0.16091 ≤ q[50] ≤ 0.16093
0.17066 ≤ q[51] ≤ 0.17068
0.18058 ≤ q[52] ≤ 0.18060
0.19067 ≤ q[53] ≤ 0.19069
0.20095 ≤ q[54] ≤ 0.20097
0.21143 ≤ q[55] ≤ 0.21145
0.22211 ≤ q[56] ≤ 0.22213
0.23300 ≤ q[57] ≤ 0.23302
0.24412 ≤ q[58] ≤ 0.24414

1.00062 ≤ q[97] ≤ 1.00064
1.00023 ≤ q[98] ≤ 1.00025
0.99967 ≤ q[99] ≤ 0.99969
0.99896 ≤ q[100] ≤ 0.99898
0.99809 ≤ q[101] ≤ 0.99811
0.99704 ≤ q[102] ≤ 0.99706
0.99583 ≤ q[103] ≤ 0.99585
0.99444 ≤ q[104] ≤ 0.99446
0.99288 ≤ q[105] ≤ 0.99290
0.99113 ≤ q[106] ≤ 0.99115
0.98919 ≤ q[107] ≤ 0.98921
0.98706 ≤ q[108] ≤ 0.98708
0.98472 ≤ q[109] ≤ 0.98474
0.98217 ≤ q[110] ≤ 0.98219
0.97940 ≤ q[lll] ≤ 0.97942
0.97641 ≤ q[112] ≤ 0.97643
0.97317 ≤ q[113] ≤ 0.97319
0.96968 ≤ q[114] ≤ 0.96970
0.96593 ≤ q[115] ≤ 0.96595
0.96190 ≤ q[116] ≤ 0.96192
0.95758 ≤ q[117] ≤ 0.95760
0.95295 ≤ q[118] ≤ 0.95297
0.94800 ≤ q[119] ≤ 0.94802
0.94270 ≤ q[120] ≤ 0.94272
0.93705 ≤ q[121] ≤ 0.93707
0.93101 ≤ q[122] ≤ 0.93103
0.92457 ≤ q[123] ≤ 0.92459
0.91769 ≤ q[124] ≤ 0.91771
0.91035 ≤ q[125] ≤ 0.91037
0.90252 ≤ q[126] ≤ 0.90254
0.89416 ≤ q[127] ≤ 0.89418
0.29117 ≤ q[128] ≤ 0.29119
0.27899 ≤ q[129] ≤ 0.27901
0.26711 ≤ q[130] ≤ 0.26713
0.25549 ≤ q[131] ≤ 0.25551
0.24412 ≤ q[132] ≤ 0.24414
0.23300 ≤ q[133] ≤ 0.23302
0.22211 ≤ q[134] ≤ 0.22213

0.21143 ≤ q[135] ≤ 0.21145
0.20095 ≤ q[136] ≤ 0.20097
0.19067 ≤ q[137] ≤ 0.19069
0.18058 ≤ q[138] ≤ 0.18060
0.17066 ≤ q[139] ≤ 0.17068
0.16091 ≤ q[140] ≤ 0.16093
0.15132 ≤ q[141] ≤ 0.15134
0.14189 ≤ q[142] ≤ 0.14191
0.13259 ≤ q[143] ≤ 0.13261
0.12344 ≤ q[144] ≤ 0.12346
0.11442 ≤ q[145] ≤ 0.11444
0.10552 ≤ q[146] ≤ 0.10554
0.09675 ≤ q[147] ≤ 0.09677
0.08809 ≤ q[148] ≤ 0.08811
0.07954 ≤ q[149] ≤ 0.07956
0.07110 ≤ q[150] ≤ 0.07112
0.06275 ≤ q[151] ≤ 0.06277
0.05451 ≤ q[152] ≤ 0.05453
0.04635 ≤ q[153] ≤ 0.04637
0.03828 ≤ q[154] ≤ 0.03830
0.03030 ≤ q[155] ≤ 0.03032
0.02240 ≤ q[156] ≤ 0.02242
0.01458 ≤ q[157] ≤ 0.01460
0.00683 ≤ q[158] ≤ 0.00685
-0.00084 ≤ q[159] ≤ -0.00082
-0.00845 ≤ q[160] ≤ -0.00843
-0.01598 ≤ q[161] ≤ -0.01596
-0.02345 ≤ q[162] ≤ -0.02343
-0.03085 ≤ q[163] ≤ -0.03083
-0.03819 ≤ q[164] ≤ -0.03817
-0.04547 ≤ q[165] ≤ -0.04545
-0.05269 ≤ q[166] ≤ -0.05267
-0.05984 ≤ q[167] ≤ -0.05982
-0.06694 ≤ q[168] ≤ -0.06692
-0.07397 ≤ q[169] ≤ -0.07395
-0.08095 ≤ q[170] ≤ -0.08093
-0.08786 ≤ q[171] ≤ -0.08784
-0.09471 ≤ q[172] ≤ -0.09469

-0.10149 ≤ q[173] ≤ -0.10147
-0.10821 ≤ q[174] ≤ -0.10819
-0.11486 ≤ q[175] ≤ -0.11484
-0.12144 ≤ q[176] ≤ -0.12142
-0.12794 ≤ q[177] ≤ -0.12792
-0.13437 ≤ q[178] ≤ -0.13435
-0.14071 ≤ q[179] ≤ -0.14069
-0.14697 ≤ q[180] ≤ -0.14695
-0.15313 ≤ q[181] ≤ -0.15311
-0.15919 ≤ q[182] ≤ -0.15917
-0.16514 ≤ q[183] ≤ -0.16512
-0.17097 ≤ q[184] ≤ -0.17095
-0.17668 ≤ q[185] ≤ -0.17666
-0.18226 ≤ q[186] ≤ -0.18224
-0.18768 ≤ q[187] ≤ -0.18766
-0.19295 ≤ q[188] ≤ -0.19293
-0.19804 ≤ q[189] ≤ -0.19802
-0.20294 ≤ q[190] ≤ -0.20292
-0.20764 ≤ q[191] ≤ -0.20762
32. Filter generator (104) according to any of the claims
23 to 31, wherein the complex modulated filter bank
(301) is adapted so that the real valued prototype
filter coefficients q(v) for integer v in the range
from 0 to 191 are given by
q[0] = -0.2029343380
q[1] = -0.1980331588
q[2] = -0.1929411519
q[3] = -0.1876744222
q[4] = -0.1822474011
q[5] = -0.1766730202
q[6] = -0.1709628636
q[7] = -0.1651273005
q[8] = -0.1591756024
q[9] = -0.1531160455
q[10] = -0.1469560005
q[ll] = -0.1407020132

q[12] = -0.1343598738
q[13] = -0.1279346790
q[14] = -0.1214308876
q[15] = -0.1148523686
q[16] = -0.1082024454
q[17] = -0.1014839341
q[18] = -0.0946991783
q[19] = -0.0878500799
q[20] = -0.0809381268
q[21] = -0.0739644174
q[22] = -0.0669296831
q[23] = -0.0598343081
q[24] = -0.0526783466
q[25] = -0.0454615388
q[26] = -0.0381833249
q[27] = -0.0308428572
q[28] = -0.0234390115
q[29] = -0.0159703957
q[30] = -0.0084353584
q[31] = -0.0008319956
q[32] = 0.0068418435
q[33] = 0.0145885527
q[34] = 0.0224107648
q[35] = 0.0303113495
q[36] = 0.0382934126
q[37] = 0.0463602959
q[38] = 0.0545155789
q[39] = 0.0627630810
q[40] = 0.0711068657
q[41] = 0.0795512453
q[42] = 0.0881007879
q[43] = 0.0967603259
q[44] = 0.1055349658
q[45] = 0.1144301000
q[46] = 0.1234514222
q[47] = 0.1326049434
q[48] = 0.1418970123
q[49] = 0.1513343370

q[50] = 0.1609240126
q[51] = 0.1706735517
q[52] = 0.1805909194
q[53] = 0.1906845753
q[54] = 0.2009635191
q[55] = 0.2114373458
q[56] = 0.2221163080
q[57] = 0.2330113868
q[58] = 0.2441343742
q[59] = 0.2554979664
q[60] = 0.2671158700
q[61] = 0.2790029236
q[62] = 0.2911752349
q[63] = 0.3036503350
q[64] = 0.9025275713
q[65] = 0.9103585196
q[66] = 0.9176977825
q[67] = 0.9245760683
q[68] = 0.9310214581
q[69] = 0.9370596739
q[70] = 0.9427143143
q[71] = 0.9480070606
q[72] = 0.9529578566
q[73] = 0.9575850672
q[74] = 0.9619056158
q[75] = 0.9659351065
q[76] = 0.9696879297
q[77] = 0.9731773547
q[78] = 0.9764156119
q[79] = 0.9794139640
q[80] = 0.9821827692
q[81] = 0.9847315377
q[82] = 0.9870689790
q[83] = 0.9892030462
q[84] = 0.9911409728
q[85] = 0.9928893067
q[86] = 0.9944539395
q[87] = 0.9958401318

q[88] = 0.9970525352
q[89] = 0.9980952118
q[90] = 0.9989716504
q[91] = 0.9996847806
q[92] = 1.0002369837
q[93] = 1.0006301028
q[94] = 1.0008654482
q[95] = 1.0009438063
q[96] = 1.0008654482
q[97] = 1.0006301028
q[98] = 1.0002369837
q[99] = 0.9996847806
q[100] = 0.9989716504
q[101] = 0.9980952118
q[102] = 0.9970525352
q[103] = 0.9958401318
q[104] = 0.9944539395
q[105] = 0.9928893067
q[106] = 0.9911409728
q[107] = 0.9892030462
q[108] = 0.9870689790
q[109] = 0.9847315377
q[110] = 0.9821827692
q[lll] = 0.9794139640
q[112] = 0.9764156119
q[113] = 0.9731773547
q[114] = 0.9696879297
q[115] = 0.9659351065
q[116] = 0.9619056158
q[117] = 0.9575850672
q[118] = 0.9529578566
q[119] = 0.9480070606
q[120] = 0.9427143143
q[121] = 0.9370596739
q[122] = 0.9310214581
q[123] = 0.9245760683
q[124] = 0.9176977825
q[125] = 0.9103585196

q[126] = 0.9025275713
q[127] = 0.8941712974
q[128] = 0.2911752349
q[129] = 0.2790029236
q[130] = 0.2671158700
q[131] = 0.2554979664
q[132] = 0.2441343742
q[133] = 0.2330113868
q[134] = 0.2221163080
q[135] = 0.2114373458
q[136] = 0.2009635191
q[137] = 0.1906845753
q[138] = 0.1805909194
q[139] = 0.1706735517
q[140] = 0.1609240126
q[141] = 0.1513343370
q[142] = 0.1418970123
q[143] = 0.1326049434
q[144] = 0.1234514222
q[145] = 0.1144301000
q[146] = 0.1055349658
q[147] = 0.0967603259
q[148] = 0.0881007879
q[149] = 0.0795512453
q[150] = 0.0711068657
q[151] = 0.0627630810
q[152] = 0.0545155789
q[153] = 0.0463602959
q[154] = 0.0382934126
q[155] = 0.0303113495
q[156] = 0.0224107648
q[157] = 0.0145885527
q[158] = 0.0068418435
q[159] = -0.0008319956
q[160] = -0.0084353584
q[161] = -0.0159703957
q[162] = -0.0234390115
q[163] = -0.0308428572

q[164] = -0.0381833249
q[165] = -0.0454615388
q[166] = -0.0526783466
q[167] = -0.0598343081
q[168] = -0.0669296831
q[169] = -0.0739644174
q[170] = -0.0809381268
q[171] = -0.0878500799
q[172] = -0.0946991783
q[173] = -0.1014839341
q[174] = -0.1082024454
q[175] = -0.1148523686
q[176] = -0.1214308876
q[177] = -0.1279346790
q[178] = -0.1343598738
q[179] = -0.1407020132
q[180] = -0.1469560005
q[181] = -0.1531160455
q[182] = -0.1591756024
q[183] = -0.1651273005
q[184] = -0.1709628636
q[185] = -0.1766730202
q[186] = -0.1822474011
q[187] = -0.1876744222
q[188] = -0.1929411519
q[189] = -0.1980331588
q[190] = -0.2029343380
q[191] = -0.2076267137
33. Filter generator (104) according to any of the claims
23 to 32, wherein the complex modulated filter bank
(301) further comprises a gain adjuster for adjusting
at least one complex valued subband signal with
respect to its value before outputting the gain
adjusted complex valued subband signal as the
intermediate filter definition signal.

34. Filter generator (104) according to any of the claims
23 to 33, wherein the complex modulated filter bank
(301) further comprises an impulse response generator
(610) for generating the impulse response signal based
on a filter definition signal provided to the filter
generator (104), wherein the impulse response signal
output by the impulse response generator (610) is
provided to the complex modulated filter bank (301).
35. Filter generator (104) according to claim 34, wherein
the impulse response generator (610) is adapted for
generating the impulse response signal based on at
least one of an amplitude/frequency filter
characteristic, a phase/frequency filter
characteristic and a signal comprising a set of filter
taps indicative of the amplitude/frequency filter
characteristic in the time domain as a filter
definition signal.
36. Method for filtering a time domain input signal to
obtain a time domain output signal, which is a
representation of the time domain input signal
filtered using a filter characteristic having a non-
uniform amplitude/frequency characteristic,
comprising the steps:
filtering a finite impulse response signal comprising
KH • L filter taps and being indicative of the filter
characteristic of the non-uniform amplitude/frequency
characteristic based on a prototype filter comprising
KQ • L taps to obtain L complex valued subband signals
as an intermediate filter definition signal,
wherein each complex valued subband signal of the
intermediate filter definition signal corresponds to a
filter impulse response for one subband comprising (KH
+ KQ - 1) filter taps;

wherein at least one of the complex valued subband
signals of the intermediate filter definition signal
comprises at least two different non-vanishing values;
and
wherein at least one of the complex valued subband
signals of the intermediate filter definition signal
corresponds to a non-uniform amplitude/frequency
characteristic;
analyzing the time domain input signal to obtain L
complex subband signals;
filtering each of the analyzed complex subband
signals,
wherein at least one of the complex subband signals is
filtered using a non-uniform amplitude/frequency
characteristic,
wherein each of the complex subband signals is
filtered based on an filter impulse response of the
filter definition signal;
wherein the filter impulse responses of the filter
definition signal comprising (KH + KQ - 1) filter taps
each are shorter than the impulse response of a filter
having the filter characteristic comprising KH • L
taps; and
wherein the non-uniform amplitude/frequency
characteristic of the impulse responses used for
filtering the plurality of subband signals together
represent the non-uniform filter characteristic; and

synthesizing from the output of the filtering of the
analyzed complex subband signals the time domain
output signal,
wherein L, KQ and KH are positive integers.
37. Method for providing an intermediate filter definition
signal comprising filter taps for intermediate subband
filters based on an impulse response signal indicative
of an amplitude/frequency filter characteristic in a
time domain,
comprising the steps:
filtering the impulse response signal indicative of
the amplitude/frequency filter characteristic in a
time domain to obtain 64 complex valued subband
signals as the intermediate filter definition signal,
wherein each of the complex valued subband signals
comprises values gn(k) based on the equation

wherein Nh is the length of the impulse response h(v)
of a filter having the filter characteristic, wherein
n = 3.1415926... is the circular number, wherein i =
is the complex unit, and wherein q(v) are filter
taps of a real valued prototype filter;
wherein each complex valued subband signal corresponds
to an impulse response for an intermediate filter for
subband signal;

wherein at least one of the complex valued subband
signals comprises at least two different non-vanishing
values; and
wherein each complex valued subband signal comprises
(Kh + 2) filter taps;
wherein Kh is given by
Kh=[Nh/64];
wherein the prototype filter taps q(v) fulfill for
integers v from 0 to 191 the relations:
-0.204 ≤ q[0] ≤ -0.202
-0.199 ≤ q[l] ≤ -0.197
-0.194 ≤ q[2] ≤ -0.192
-0.189 ≤ q[3] ≤ -0.187
-0.183 ≤ q[4] ≤ -0.181
-0.178 ≤ q[5] ≤ -0.176
-0.172 ≤ q[6] ≤ -0.170
-0.166 ≤ q[7] ≤ -0.164
-0.160 ≤ q[8] ≤ -0.158
-0.154 ≤ q[9] ≤ -0.152
-0.148 ≤ q[10] ≤ -0.146
-0.142 ≤ q[ll] ≤ -0.140
-0.135 ≤ q[12] ≤ -0.133
-0.129 ≤ q[13] ≤ -0.127
-0.122 ≤ q[14] ≤ -0.120
-0.116 ≤ q[15] ≤ -0.114
-0.109 ≤ q[16] ≤ -0.107
-0.102 ≤ q[17] ≤ -0.100
-0.096 ≤ q[18] ≤ -0.094
-0.089 ≤ q[19] ≤ -0.087
-0.082 ≤ q[20] ≤ -0.080
-0.075 ≤ q[21] ≤ -0.073
-0.068 ≤ q[22] ≤ -0.066
-0.061 ≤ q[23] ≤ -0.059

-0.054 ≤ q[24] ≤ -0.052
-0.046 ≤ q[25] ≤ -0.044
-0.039 ≤ q[26] ≤ -0.037
-0.032 ≤ q[27] ≤ -0.030
-0.024 ≤ q[28] ≤ -0.022
-0.017 ≤ q[29] ≤ -0.015
-0.009 ≤ q[30] ≤ -0.007
-0.002 ≤ q[31] ≤ 0.000
0.006 ≤ q[32] ≤ 0.008
0.014 ≤ q[33] ≤ 0.016
0.021 ≤ q[34] ≤ 0.023
0.029 ≤ q[35] ≤ 0.031
0.037 ≤ q[36] ≤ 0.039
0.045 ≤ q[37] ≤ 0.047
0.054 ≤ q[38] ≤ 0.056
0.062 ≤ q[39] ≤ 0.064
0.070 ≤ q[40] ≤ 0.072
0.079 ≤ q[41] ≤ 0.081
0.087 ≤ q[42] ≤ 0.089
0.096 ≤ q[43] ≤ 0.098
0.105 ≤ q[44] ≤ 0.107
0.113 ≤ q[45] ≤ 0.115
0.122 ≤ q[46] ≤ 0.124
0.132 ≤ q[47] ≤ 0.134
0.141 ≤ q[48] ≤ 0.143
0.150 ≤ q[49] ≤ 0.152
0.160 ≤ q[50] ≤ 0.162
0.170 ≤ q[51] ≤ 0.172
0.180 ≤ q[52] ≤ 0.182
0.190 ≤ q[53] ≤ 0.192
0.200 ≤ q[54] ≤ 0.202
0.210 ≤ q[55] ≤ 0.212
0.221 ≤ q[56] ≤ 0.223
0.232 ≤ q[57] ≤ 0.234
0.243 ≤ q[58] ≤ 0.245
0.254 ≤ q[59] ≤ 0.256
0.266 ≤ q[60] ≤ 0.268
0.278 ≤ q[61] ≤ 0.280

0.290 ≤ q[62] ≤ 0.292
0.303 ≤ q[63] ≤ 0.305
0.902 ≤ q[64] ≤ 0.904
0.909 ≤ q[65] ≤ 0.911
0.917 ≤ q[66] ≤ 0.919
0.924 ≤ q[67] ≤ 0.926
0.930 ≤ q[68] ≤ 0.932
0.936 ≤ q[69] ≤ 0.938
0.942 ≤ q[70] ≤ 0.944
0.947 ≤ q[71] ≤ 0.949
0.952 ≤ q[72] ≤ 0.954
0.957 ≤ q[73] ≤ 0.959
0.961 ≤ q[74] ≤ 0.963
0.965 ≤ q[75] ≤ 0.967
0.969 ≤ q[76] ≤ 0.971
0.972 ≤ q[77] ≤ 0.974
0.975 ≤ q[78] ≤ 0.977
0.978 ≤ q[79] ≤ 0.980
0.981 ≤ q[80] ≤ 0.983
0.984 ≤ q[81] ≤ 0.986
0.986 ≤ q[82] ≤ 0.988
0.988 ≤ q[83] ≤ 0.990
0.990 ≤ q[84] ≤ 0.992
0.992 ≤ q[85] ≤ 0.994
0.993 ≤ q[86] ≤ 0.995
0.995 ≤ q[87] ≤ 0.997
0.996 ≤ q[88] ≤ 0.998
0.997 ≤ q[89] ≤ 0.999
0.998 ≤ q[90] ≤ 1.000
0.999 ≤ q[91] ≤ 1.001
0.999 ≤ q[92] ≤ 1.001
1.000 ≤ q[93] ≤ 1.002
1.000 ≤ q[94] ≤ 1.002
1.000 ≤ q[95] ≤ 1.002
1.000 ≤ q[96] ≤ 1.002
1.000 ≤ q[97] ≤ 1.002
0.999 ≤ q[98] ≤ 1.001
0.999 ≤ q[99] ≤ 1.001

0.998 ≤ q[100] ≤ 1.000
0.997 ≤ q[101] ≤ 0.999
0.996 ≤ q[102] ≤ 0.998
0.995 ≤ q[103] ≤ 0.997
0.993 ≤ q[104] ≤ 0.995
0.992 ≤ q[105] ≤ 0.994
0.990 ≤ q[106] ≤ 0.992
0.988 ≤ q[107] ≤ 0.990
0.986 ≤ q[108] ≤ 0.988
0.984 ≤ q[109] ≤ 0.986
0.981 ≤ q[110] ≤ 0.983
0.978 ≤ q[lll] ≤ 0.980
0.975 ≤ q[112] ≤ 0.977
0.972 ≤ q[113] ≤ 0.974
0.969 ≤ q[114] ≤ 0.971
0.965 ≤ q[115] ≤ 0.967
0.961 ≤ q[116] ≤ 0.963
0.957 ≤ q[117] ≤ 0.959
0.952 ≤ q[118] ≤ 0.954
0.947 ≤ q[119] ≤ 0.949
0.942 ≤ q[120] ≤ 0.944
0.936 ≤ q[121] ≤ 0.938
0.930 ≤ q[122] ≤ 0.932
0.924 ≤ q[123] ≤ 0.926
0.917 ≤ q[124J ≤ 0.919
0.909 ≤ q[125] ≤ 0.911
0.902 ≤ q[126] ≤ 0.904
0.893 ≤ q[127] ≤ 0.895
0.290 ≤ q[128] ≤ 0.292
0.278 ≤ q[129] ≤ 0.280
0.266 ≤ q[130] ≤ 0.268
0.254 ≤ q[131] ≤ 0.256
0.243 ≤ q[132] ≤ 0.245
0.232 ≤ q[133] ≤ 0.234
0.221 ≤ q[134] ≤ 0.223
0.210 ≤ qtl35] ≤ 0.212
0.200 ≤ q[136] ≤ 0.202
0.190 ≤ q[137] ≤ 0.192

0.180 ≤ q[138] ≤ 0.182
0.170 ≤ q[139] ≤ 0.172
0.160 ≤ q[140] ≤ 0.162
0.150 ≤ q[141] ≤ 0.152
0.141 ≤ q[142] ≤ 0.143
0.132 ≤ q[143] ≤ 0.134
0.122 ≤ q[144] ≤ 0.124
0.113 ≤ q[145] ≤ 0.115
0.105 ≤ q[146] ≤ 0.107
0.096 ≤ q[147] ≤ 0.098
0.087 ≤ q[148] ≤.0.089
0.079 ≤ q[149] ≤ 0.081
0.070 ≤ q[150] ≤ 0.072
0.062 ≤ q[151] ≤ 0.064
0.054 ≤ q[152] ≤ 0.056
0.045 ≤ q[153] ≤ 0.047
0.037 ≤ q[154] ≤ 0.039
0.029 ≤ q[155] ≤ 0.031
0.021 ≤ q[156] ≤ 0.023
0.014 ≤ q[157] ≤ 0.016
0.006 ≤ q[158] ≤ 0.008
-0.002 ≤ q[159] ≤ 0.000
-0.009 ≤ q[160] ≤ -0.007
-0.017 ≤ q[161] ≤ -0.015
-0.024 ≤ q[162] ≤ -0.022
-0.032 ≤ q[163] ≤ -0.030
-0.039 ≤ q[164] ≤ -0.037
-0.046 ≤ q[165] ≤ -0.044
-0.054 ≤ q[166] ≤ -0.052
-0.061 ≤ q[167] ≤ -0.059
-0.068 ≤ q[168] ≤ -0.066
-0.075 ≤ q[169] ≤ -0.073
-0.082 ≤ q[170] ≤ -0.080
-0.089 ≤ q[171] ≤ -0.087
-0.096 ≤ q[172] ≤ -0.094
-0.102 ≤ q[173] ≤ -0.100
-0.109 ≤ q[174] ≤ -0.107
-0.116 ≤ q[175] ≤ -0.114

-0.122 ≤ q[176] ≤ -0.120
-0.129 ≤ q[177] ≤ -0.127
-0.135 ≤ q[178] ≤ -0.133
-0.142 ≤ q[179] ≤ -0.140
-0.148 ≤ q[180] ≤ -0.146
-0.154 ≤ q[181] ≤ -0.152
-0.160 ≤ q[182] ≤ -0.158
-0.166 ≤ q[183] ≤ -0.164
-0.172 ≤ q[184] ≤ -0.170
-0.178 ≤ q[185] ≤ -0.176
-0.183 ≤ q[186] ≤ -0.181
-0.189 ≤ q[187] ≤ -0.187
-0.194 ≤ q[188] ≤ -0.192
-0.199 ≤ q[189] ≤ -0.197
-0.204 ≤ q[190] ≤ -0.202
-0.209 ≤ q[191] ≤ -0.207.
38. Computer program for performing, when running on a
computer, a method in accordance with one of the
methods of claims 36 or 37.

A filter apparatus for filtering a time domain input signal
to obtain a time domain output signal, which is a
representation of the time domain input signal filtered
using a filter characteristic having an non-uniform
amplitude/frequency characteristic, comprises a complex
analysis filter bank for generating a plurality of complex
subband signals from the time domain input signals, a
plurality of intermediate filters, wherein at least one of
the intermediate filters of the plurality of the
intermediate filters has a non-uniform amplitude/frequency
characteristic, wherein the plurality of intermediate
filters have a shorter impulse response compared to an
impulse response of a filter having the filter
characteristic, and wherein the non-uniform
amplitude/frequency characteristics of the plurality of
intermediate filters together represent the non-uniform
filter characteristic, and a complex synthesis filter bank
for synthesizing the output of the intermediate filters to
obtain the time domain output signal.

Documents:

http://ipindiaonline.gov.in/patentsearch/GrantedSearch/viewdoc.aspx?id=2ZuE8nZ6EE41GWUqJexaBg==&loc=wDBSZCsAt7zoiVrqcFJsRw==


Patent Number 269029
Indian Patent Application Number 3132/KOLNP/2008
PG Journal Number 40/2015
Publication Date 02-Oct-2015
Grant Date 29-Sep-2015
Date of Filing 30-Jul-2008
Name of Patentee DOLBY INTERNATIONAL AB,
Applicant Address APOLLO BUILDING, 3E HERIKERBERGWEG 1-35, 1101 CN, AMSTERDAM ZUID-OOST, NETHERLANDS
Inventors:
# Inventor's Name Inventor's Address
1 LARS VILLEMOES MANDOLINVAGEN 22, 175 56 JARFALLA
PCT International Classification Number H03H 17/02
PCT International Application Number PCT/EP2006/008565
PCT International Filing date 2006-09-01
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 60/744,559 2006-04-10 U.S.A.
2 60/762,592 2006-01-27 U.S.A.