Title of Invention	MULTI-CHANNEL RECONSTRUCTOR AND ENHANCED METHOD FOR SIGNAL SHAPING IN MULTI-CHANNEL AUDIO RECONSTRUCTION
Abstract	A reconstructed output channel, reconstructed with a multi-channel reconstructor using at least one downmix channel derived by downmixing a plurality of original channels and using a parameter representation including additional information on a temporal fine structure of an original channel can be generated using a generator (32) for generating a direct signal component (42) and a diffuse signal component (44) based on the downmix channel (38) is used. Only the direct signal component (42) is modified (34) such that the temporal (40) fine structure of the reconstructed output channel is fitting a desired temporal fine structure, indicated by the additional information on the temporal fine structure transmitted.

Title of Invention

MULTI-CHANNEL RECONSTRUCTOR AND ENHANCED METHOD FOR SIGNAL SHAPING IN MULTI-CHANNEL AUDIO RECONSTRUCTION

Abstract

A reconstructed output channel, reconstructed with a multi-channel reconstructor using at least one downmix channel derived by downmixing a plurality of original channels and using a parameter representation including additional information on a temporal fine structure of an original channel can be generated using a generator (32) for generating a direct signal component (42) and a diffuse signal component (44) based on the downmix channel (38) is used. Only the direct signal component (42) is modified (34) such that the temporal (40) fine structure of the reconstructed output channel is fitting a desired temporal fine structure, indicated by the additional information on the temporal fine structure transmitted.

Full Text	Enhanced method for signal shaping in multi-channel audio reconstruction Description Field of the Invention The present invention relates to a concept of enhanced signal shaping in multi-channel audio reconstruction and in particular to a new approach of envelope shaping. Background of the Invention and Prior Art Recent development in audio coding enables recreation of 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 solutions, such as Dolby Prologic, since additional control data is transmitted to control the recreation, also referred to as up-mix, of the surround channels based on the transmitted mono or stereo channels. Such parametric multi-channel audio decoders reconstruct N channels based on M transmitted channels, where N > M, and the additional control data. Using the additional control data causes a significantly lower data rate than transmitting all N channels, making the coding very efficient, while at the same time ensuring compatibility with both M channel devices and N channel devices. The M channels can either be a single mono channel, a stereo channel, or a 5.1 channel representation. Hence, it is possible to have an 7.2 channel original signal, downmixed to a 5.1 channel backwards compatible signal, and spatial audio parameters enabling a spatial audio decoder to reproduce a closely resembling version of the original 7.2 channels, at a small additional bit rate overhead. These parametric surround coding methods usually comprise a parameterization of the surround signal based on time and frequency variant ILD (Inter Channel Level Difference) and ICC (Inter Channel Coherence) parameters. These parameters describe e.g. power ratios and correlations between channel pairs of the original multi-channel signal. In the decoding process, the re-created multichannel signal is obtained by distributing the energy of the received downmix channels between all the channel pairs as described by the transmitted ILD parameters. However, since a multi-channel signal can have equal power distribution between all channels, while the signals in the different channels are very different, thus giving the listening impression of a very wide sound, the correct wideness is obtained by mixing signals with decorrelated versions of the same, as described by the ICC parameter. The decorrelated version of the signal, often also referred to as wet or diffuse signal, is obtained by passing the signal through a reverberator, such as an all-pass filter. A simple form of decorrelation is applying a specific delay to the signal. Generally, there are a lot of different reverberators known in the art, the precise implementation of the reverberator used is of minor importance. The output from the decorrelator has a time response that is usually very flat. Hence, a dirac input signal gives a decaying noise burst out. When mixing the decorrelated and the original signal, it is for some transient signal types, like applause signals, important to perform some post- processing on the signal to avoid perceptuality of additionally introduced artefacts that may result in a larger perceived room size and pre-echo type of artefacts. Generally, the invention relates to a system that represents multi-channel audio as a combination of audio downmix data (e.g. one or two channels) and related parametric multi-channel data. In such a scheme (for example in binaural cue coding) an audio downmix data stream is transmitted, wherein it may be noted that the simplest form of downmix is simply adding the different signals of a multi-channel signal. Such a signal (sum signal) is accompanied by a parametric multi-channel data stream (side info). The side info comprises for example one or more of the parameter types discussed above to describe the spatial interrelation of the original channels of the multi-channel signal. In a sense, the parametric multi- channel scheme acts as a pre-/post-processor to the sending/receiving end of the downmix data, e.g. having the sum signal and the side information. It shall be noted that the sum signal of the downmix data may additionally be coded using any audio or speech coder. As transmission of multi-channel signals over low-bandwidth carriers is becoming more and more popular these systems, also known under "spatial audio coding", "MPEG surround", have been well developed recently. The following publications are known in the context of these technologies: [1] C. Faller and F. Baumgarte, "Efficient representation of spatial audio using perceptual parametrization," in Proc. IEEE WASPAA, Mohonk, NY, Oct. 2001. [2] F. Baumgarte and C. Faller, "Estimation of auditory spatial cues for binaural cue coding," in Proc. ICASSP 2002, Orlando, FL, May 2002. [3] C. Faller and F. Baumgarte, "Binaural cue coding: a novel and efficient representation of spatial audio," in Proc. ICASSP 2002, Orlando, FL, May 2002. [4] F. Baumgarte and C. Faller, "Why binaural cue coding is better than intensity stereo coding," in Proc. AES 112th Conv., Munich, Germany, May 2002. [5] C. Faller and F. Baumgarte, "Binaural cue coding applied to stereo and multi-channel audio compression," in Proc. AES 112th Conv., Munich, Germany, May 2002. [6] F. Baumgarte and C. Faller, "Design and evaluation of binaural cue coding," in AES 113th Conv., Los Angeles, CA, Oct. 2002. [7] C. Faller and F. Baumgarte, "Binaural cue coding applied to audio compression with flexible rendering," in Proc. AES 113th Conv., Los Angeles, CA, Oct. 2002. [8] J. Breebaart, J. Herre, C. Faller, J. Roden, F. Myburg, S. Disch, H. Purnhagen, G. Hoto, M. Neusinger, K. Kjorling, W. Oomen: "MPEG Spatial Audio Coding / MPEG Surround: Overview and Current Status", 119th AES Convention, New York 2005, Preprint 6599 [9] J. Herre, H. Purnhagen, J. Breebaart, C. Faller, S. Disch, K. Kjorling, E. Schuijers, J. Hilpert, F. Myburg, "The Reference Model Architecture for MPEG Spatial Audio Coding", 118th AES Convention, Barcelona 2005, Preprint 6477 [10] J. Herre, C. Faller, S. Disch, C. Ertel, J. Hilpert, A. Hoelzer, K. Linzmeier, C. Spenger, P. Kroon: "Spatial Audio Coding: Next-Generation Efficient and Compatible Coding of Multi-Channel Audio", 117th AES Convention, San Francisco 2004, Preprint 6186 [11] J. Herre, C. Faller, C. Ertel, J. Hilpert, A Hoelzer, C. Spenger: "MP3 Surround: Efficient and Compatible Coding of Multi-Channel Audio", 116th AES Convention, Berlin 2004, Preprint 604 9. A related technique, focusing on transmission of two channels via one transmitted mono signal is called "parametric stereo" and for example described more extensively in the following publications: [12] J. Breebaart, S. van de Par, A. Kohlrausch, E. Schuijers, "High-Quality Parametric Spatial Audio Coding at Low Bitrates", AES 116th Convention, Berlin, Preprint 6072, May 2004 [13] E. Schuijers, J. Breebaart, H. Purnhagen, J. Engdegard, "Low Complexity Parametric Stereo Coding", AES 116th Convention, Berlin, Preprint 6073, May 2004. In a spatial audio decoder, the multi-channel upmix is computed from a direct signal part and a diffuse signal part, which is derived by means of decorrelation from the direct part, as already mentioned above. Thus, in general, the diffuse part has a different temporal envelope than the direct part. The term "temporal envelope" describes in this context the variation of the energy or amplitude of the signal with time. The differing temporal envelope leads to artifacts (pre- and post-echoes, temporal "smearing") in the upmix signals for input signals that have a wide stereo image and, at the same time, a transient envelope structure. Transient signals generally are signals that are varying strongly in a short time period. The probably most important examples for this class of signals are applause-like signals, which are frequently present in live recordings. In order to avoid artefacts caused by introducing diffuse/decorrelated sound with an inappropriate temporal envelope into the upmix signal, a number of techniques have been proposed: The US application 11/006,492 ("Diffuse Sound Shaping for BCC Schemes and The Like") shows that the perceptual quality of critical transient signals can be improved by shaping the temporal envelope of the diffuse signal to match the temporal envelope of the direct signal. This approach has already been introduced into MPEG surround technology by different tools, such as "temporal envelope shaping" (TES) and the "temporal processing" (TP). Since the target temporal envelope of the diffuse signal is derived from the envelope of the transmitted downmix signal, this method does not require additional side information to be transmitted. However, as a consequence, the temporal fine structure of the diffuse sound is the same for all output channels. As the direct signal part, which is directly derived from the transmitted downmix signal, does also have a similar temporal envelope, this method may improve the perceptual quality of applause-like signals in terms of "crisp-ness", i.e. However, as then the direct signal and diffuse signal have similar temporal envelopes for all channels, such techniques may enhance the subjective quality of applause-like signals but cannot improve the spatial distribution of single applause events in the signal, as this would only be possible, when one reconstructed channel would be much more intense at the occurrence of the transient signal than the other channels, which is impossible having signals sharing basically the same temporal envelope. An alternative method to overcome the problem is described by US application 11/006,482 ("individual Channel Shaping for BCC Schemes and The Like"). This approach employs fine- grain temporal broad band side information that is transmitted by the encoder to perform a fine temporal shaping of both the direct and the diffuse signal. Evidently, this approach allows a temporal fine structure that is individual for each output channel and thus is able to accommodate also signals for which transient events occur in only a subset of the output channels. A further variation of this approach is described in US 60/726,389 ("Methods for Improved Temporal and Spatial Shaping of Multi-Channel Audio Signals"). Both discussed approaches to enhance perceptual quality of transient coded signals comprise a temporal shaping of the envelope of the diffuse signal intended to match a corresponding direct signals temporal envelope. While both previously described prior-art methods can enhance the subjective quality of applause-like signals in terms of crisp-ness, only the latter approach can also improve the spatial redistribution of the reconstructed signal. Still, the subjective quality of the synthesized applause signals remains unsatisfactory, because the temporal shaping of both the combination of dry and diffused sound leads to characteristic distortions (the attacks of the individual claps are either perceived as not "tight" when only a loose temporal shaping is performed, or distortions are introduced if shaping with a very high temporal resolution is applied to the signal). This becomes evident, when a diffuse signal is simply a delayed copy of the direct signal. Then, the diffused signal mixed to the direct signal is likely to have a different spectral composition than the direct signal. Thus, even if the envelope is scaled to match the envelope of the direct signal, different spectral contributions, not originating directly from the original signal will be present in the reconstructed signal. The introduced distortions may become even worse, when the diffuse signal part is emphasized (made louder) during the reconstruction, when the diffuse signal is scaled to match the envelope of the direct signal. Summary of the Invention It is the object of the present invention to provide a concept of enhanced signal shaping in multi-channel reconstruction. This object is achieved by an apparatus in accordance with claims 1 or 29, a method in accordance with claim 2 8 and a computer program in accordance with claim 30. The present invention is based on the finding that a reconstructed output channel, reconstructed with a multi- channel reconstructor using at least one downmix channel derived by downmixing a plurality of original channels and using a parameter representation including additional information on a temporal (fine) structure of an original channel can be reconstructed efficiently with high quality, when a generator for generating a direct signal component and a diffuse signal component based on the downmix channel is used. The quality can be essentially enhanced, if only the direct signal component is modified such that the temporal fine structure of the reconstructed output channel is fitting a desired temporal fine structure, indicated by the additional information on the temporal fine structure transmitted. In other words, scaling the direct signal parts directly derived from the downmix signal, hardly introduces additional artifacts at the moment a transient signal occurs. When, as in prior art, the wet signal part is scaled to match a desired envelope, it may very well be the case that the original transient signal in the reconstructed channel is masked by an emphasized diffuse signal mixed to the direct signal, which will be more extensively described below. The present invention overcomes this problem by only scaling the direct signal component, thus giving no opportunity to introduce additional artifacts at the cost of transmitting additional parameters to describe the temporal envelope within the side information. According to one embodiment of the present invention, envelope scaling parameters are derived using a representation of the direct and the diffuse signal with a whitened spectrum, i.e., where different spectral parts of the signal have almost identical energies. The advantages of using whitened spectra are twofold. One the one hand, using a whitened spectrum as a basis for the calculation of a scaling factor used to scale the direct signal allows for the transmission of only one parameter per time slot including information on the temporal structure. As it is usual in multi-channel audio coding that signals are processed within numerous frequency bands, this feature helps to decrease the number of additionally needed side information and hence the bit rate increase for the transmission of the additional parameter. Typically, other parameters such as ICLD and ICC are transmitted once per time frame and parameter band. As the number of parameter bands may be higher than 20, it is a major advantage having to transmit only one single parameter per channel. Generally, in multi-channel coding, signals are processed in a frame structure, i.e., in entities having several sampling values, for example 1024 per frame. Furthermore, as already mentioned, the signals are split into several spectral portions before being processed, such that finally typically one ICC and ICLD parameter is transmitted per frame and spectral portion of the signal. The second advantage of using only one parameter is physically motivated, since the transient signals in question naturally have broad spectra. Therefore, to account for the energy of the transient signals within the single channels correctly, it is most appropriate to use whitened spectra for the calculation of energy scaling factors. In a further embodiment of the present invention the inventive concept of modifying the direct signal component is only applied for a spectral portion of the signal above a certain spectral limit in the presence of additional residual signals. This is because residual signals together with the downmix signal allow for a high quality- reproduction of the original channels. Summarizing, the inventive concept is designed to provide enhanced temporal and spatial quality with respect to the prior art approaches, avoiding the problems associated with those techniques. Therefore, side information is transmitted to describe the fine time envelope structure of the individual channels and thus allow fine temporal/spatial shaping of the upmix channel signals at the decoder side. The inventive method described in this document is based on the following findings/considerations: • Applause-like signals can be seen as composed of single, distinct nearby claps and a noise-like ambience originating from very dense far-off claps. • In a spatial audio decoder, the best approximation of the nearby claps in terms of temporal envelope is the direct signal. Therefore, only the direct signal is processed by the inventive method. • Since the diffuse signal represents mainly the ambience part of the signal, any processing on a fine temporal resolution is likely to introduce distortion and modulation artefacts (even though a certain subjective enhancement of applause ^crispness' might be achieved by such a technique). As a consequence to these considerations, thus the diffuse signal is untouched (i.e. not subjected to a fine time shaping) by the inventive processing. • Nevertheless the diffuse signal contributes to the energy balance of the upmixed signal. The inventive method accounts for this by calculating a modified broadband scaling factor from the transmitted information that is to be applied solely to the direct signal part. This modified factor is chosen such that the overall energy in a given time interval is the same within certain bounds as if the original factor had been applied to both the direct and the diffuse part of the signal in this interval. • Using the inventive method, best subjective audio quality is obtained if the spectral resolution of the spatial cues is chosen to be low - for instance 'full bandwidth' - to ensure preservation of spectral integrity of the transients contained in the signal. In this case, the proposed method does not necessarily increase the average spatial side information bitrate, since spectral resolution is safely traded for temporal resolution. The subjective quality improvement is achieved by amplifying or damping ("shaping") the dry part of the signal over time only and thus • Enhancing transient quality by strengthening the direct signal part at the transient location, while avoiding additional distortion originating from a diffuse signal with inappropriate temporal envelope • Improving spatial localisation by emphasizing the direct part w.r.t. the diffuse part at the spatial origin of a transient event and damping it relative to the diffuse part at far-off panning positions. Brief Description of the Drawings Fig. 1 shows a block diagram of a multi-channel encoder and a corresponding decoder; Fig. lb shows a schematic sketch of signal reconstruction using decorrelated signals; Fig. 2 shows an example for an inventive multi-channel reconstructor; Fig. 3 shows a further example for an inventive multi- channel reconstructor; Fig. 4 shows an example for parameter band representations used to identify different parameter bands within a multi-channel decoding scheme; Fig. 5 shows an example for an inventive multi-channel decoder; and Fig. 6 shows a block diagram detailing an example for an inventive method of reconstructing an output channel; Detailed Description of the further embodiments Fig. 1 shows an example for coding of multi-channel audio data according to prior art, to more clearly illustrate the problem solved by the inventive concept. Generally, on an encoder side, an original multi-channel signal 10 is input into the multi-channel encoder 12, deriving side information 14 indicating the spatial distribution of the various channels of the original multi-channel signals with respect to one another. Apart from the generation of side information 14, a multi- channel encoder 12 generates one or more sum signals 16, being downmixed from the original multi-channel signal. Famous configurations widely used are so-called 5-1-5 and 5-2-5 configurations. In 5-1-5 configuration the encoder generates one single monophonic sum signal 16 from five input channels and hence, a corresponding decoder 18 has to generate five reconstructed channels of a reconstructed multi-channel signal 20. In the 5-2-5 configuration, the encoder generates two downmix channels from five input channels, the first channel of the downmixed channels typically holding information on a left side or a right side and the second channel of the downmixed channels holding information on the other side. Sample parameters describing the spatial distribution of the original channels are, as for example indicated in Fig. 1, the previously introduced parameters ICLD and ICC. It may be noted that within the analysis deriving the side information 14, the samples of the original channels of the multi-channel signal 10 are typically processed in subband domains representing a specific frequency interval of the original channels. A single frequency interval is indicated by K. In some applications, the input channels may be filtered by a hybrid filter bank before the processing, i.e., the parameter bands K may be further subdivided, each subdivision denoted with k. Furthermore, the processing of the sample values describing an original channel, is done in a frame-wise manner within each single parameter band, i.e. several consecutive samples form a frame of finite duration. The BCC parameters mentioned above typically describe a full frame. A parameter in some way related to the present invention and already known in the art is the ICLD parameter, describing the energy contained within a signal frame of a channel with respect to the corresponding frames of other channels of the original multi-channel or signal. Commonly, the generation of additional channels to derive a reconstruction of a multi-channel signal from one transmitted sum signal only is achieved with the help of decorrelated signals, being derived from the sum signal using decorrelators or reverberators. For a typical application, the discrete sample frequency may be 44.100 kH, such that a single sample represents an interval of finite length of about 0.02 ms of an original channel. It may be noted that, using filter banks, the signal is split into numerous signal parts, each representing a finite frequency interval of the original signal. To compensate for a possible increase in parameters describing the channel, the time resolution is normally decreased, such that a finite length time portion described by a single sample within a filter bank domain may increase to more than 0.5 ms. Typical frame length may vary between 10 and 15 ms. Deriving the decorrelated signal may make use of different filter structures and/or delays or combinations thereof without limiting the scope of the invention. It may be furthermore noted that not necessarily the whole spectrum has to be used to derive the decorrelated signals. For example, only spectral portions above a spectral lower bound (specific value of K) of the sum signal (downmix signal) may be used to derive the decorrelated signals using delays and/or filters. A decorrelated signal thus generally describes a signal derived from the downmix signal (downmix channel) such that a correlation coefficient, when derived using the decorrelated signal and the downmix channel significantly deviates from unity, for example by 0.2. Fig. lb gives an extremely simplified example of the down- mix and reconstruction process during multi-channel audio coding to explain the great benefit of the inventive concept of scaling only the direct signal component during reconstruction of a channel of a multi-channel signal. For the following description, some simplifications are assumed. The first simplification is that the down-mix of a left and a right channel is a simple addition of the amplitudes within the channels. The second strong simplification is, that the correlation is assumed to be a simple delay of the whole signal. Under these assumptions, a frame of a left channel 21a and a right channel 21b shall be encoded. As indicated on the x-axis of the shown windows, in multi-channel audio coding, the processing is typically performed on sample values, sampled with a fixed sample frequency. This shall, for ease of explanation, be furthermore neglected in the following short summary. As already mentioned, on the encoder side, a left and right channel is combined (down-mixed) into a down-mix channel 22 that is to be transmitted to the decoder. On the decoder side, a decorrelated signal 23 is derived from the transmitted down-mix channel 22, which is the sum of the left channel 21a and the right channel 21b in this example. As already explained, the reconstruction of the left channel is then performed from signal frames derived from the down-mix channel 22 and the decorrelated signal 23. It may be noted that each single frame is undergoing a global scaling before the combination, as indicated by the ICLD parameter, which relates the energies within the individual frames of single channels to the energy of the corresponding frames of the other channels of a multi- channel signal. As it is assumed in the present example, that equal energies are contained within the frame of the left channel 21a and the frame of the right channel 21b, the transmitted down-mix channel 22 and the decorrelated signal 23 are scaled by roughly the factor of 0.5 before the combination. That is, when up-mixing is equally simple as down-mixing, i.e. summing up the two signals, the reconstruction of the original left channel 21a is the sum of the scaled down-mix channel 24a and the scaled decorrelated signal 24b. Because of the summation for transmission and the scaling due to the ICLD parameter, the signal to background ratio of the transient signal would be decreased by a factor of roughly 2. Furthermore, when simply adding the two signals, , an additional echo type of artefact would be introduced at the position of the delayed transient structure in the scaled decorrelated signal 24b. As indicated in Fig. lb, prior art tries to overcome the echo problem by scaling the amplitude of the scaled decorrelated signal 24b to make it match the envelope of the scaled transmitted channel 24a, as indicated by the dashed lines in frame 24b. Due to the scaling, the amplitude at the position of the original transient signal in the left channel 21a may be increased. However, the spectral composition of the decorrelated signal at the position of the scaling in frame 24b is different from the spectral composition of the original transient signal. Therefore, audible artefacts are introduced into the signal, even though the general intensity of the signal may be reproduced well. The great advantage of the present invention is that the present invention does only scale a direct signal component of reconstructed. As this channel does have a signal component corresponding to the original transient signal having the right spectral composition and the right timing, scaling only the down-mix channel will yield a reconstructed signal reconstructing the original transient event with high accuracy. This is the case since only signal parts are emphasized by the scaling that have the same spectral composition as the original transient signal. Fig. 2 shows a block diagram of a example of an inventive multi-channel reconstructor, to detail the principal of the inventive concept. Fig. 2 shows a multi-channel reconstructor 30, having a generator 32, a direct signal modifier and a combiner 36. The generator 32 receives a downmix channel 38 downmixed from a plurality of original channels and a parameter representation 40 including information on a temporal structure of an original channel. The generator generates a direct signal component 42 and a diffuse signal component 44 based on the downmix channel. The direct signal modifier 34 receives as well the direct signal component 42 as the diffuse signal component 44 and in addition the parameter representation 40 having the information on a temporal structure of the original channel. According to the present invention, the direct signal modifier 34 modifies only the direct signal component 42 using the parameter representation to derive a modified direct signal component 46. The modified direct signal component 4 6 and the diffuse signal component 44, which is not altered by the direct signal modifier 34, are input into the combiner 36 that combines the modified direct signal component 4 6 and the diffuse signal component 44 to obtain a reconstructed output channel 50. By only modifying the direct signal component 42 derived from the transmitted downmix channel 38 without reverberation (decorrelation), it is possible to reconstruct a time envelope for the reconstructed output channel matching closely a time envelope of the underlying original channel without introducing additional artefacts and audible distortions, as in prior art techniques. As will be discussed in more detail in the description of Fig. 3, the inventive envelope shaping restores the broad band envelope of the synthesized output signal. It comprises a modified upmix procedure, followed by envelope flattening and reshaping of the direct signal portion of each output channel. For reshaping, parametric broad band envelope side information contained in the bit stream of the parameter representation is used. This side information consists, according to one embodiment of the present invention, of ratios (envRatio) relating the transmitted downmix signal's envelope to the original input channel signal's envelope. In the decoder, gain factors are derived from these ratios to be applied to the direct signal on each time slot in a frame of a given output channel. The diffuse sound portion of each channel is not altered according to the inventive concept. The preferred embodiment of the present invention shown in the block diagram of Fig. 3 is a multi-channel reconstructor 60 modified to fit in the decoder signal flow of a MPEG spatial decoder. The multi-channel reconstructor 60 comprises a generator 62 for generating a direct signal component 64 and a diffuse signal component 66 using a downmix channel 68 derived by downmixing a plurality of original channels and a parameter representation 70 having information on spatial properties of original channels of the multi- channel signal, as used within MPEG coding. The multi- channel reconstructor 60 further comprises a direct signal modifier 68, receiving the direct signal component 64, the diffuse signal component 66, the downmix signal 69 and additional envelope side information 72 as input. The direct signal modifier provides at its modifier output 73 the modified direct signal component, modified as described in more detail below. The combiner 74 receives the modified direct signal component and the diffuse signal component to obtain the reconstructed output channel 76. As shown in the Figure, the present invention may be easily implemented in already existing multi-channel environments. General application of the inventive concept within such a coding scheme could be switched on and off according to some parameters additionally transmitted within the parameter bit stream. For example, an additional flag bsTempShapeEnable could be introduced, which indicates, when set to 1, usage of the inventive concept is required. Furthermore, an additional flag could be introduced, specifying specifically the need of the application of the inventive concept on a channel by channel basis. Therefore, an additional flag may be used, called for example bsEnvShapeChannel. This flag, available for each individual channel, may then indicate the use of the inventive concept, when set to 1. It may furthermore be noted that for ease of presentation, only a two channel configuration is described in Fig. 3. Of course, the present invention is not intended to be limited to a two channel configuration only. Moreover, any channel configuration may be used in connection with the inventive concept. For example, five or seven input channels may be used in connection with the inventive advanced envelope shaping. When the inventive concept is applied within an MPEG coding scheme, as indicated in Fig. 3, and the application of the inventive concept is signaled by setting bsTempShapeEnable equal to 1, direct and diffuse signal components are synthesized separately by generator 62 using a modified post-mixing in the hybrid subband domain according to the following formula: y:;L=M"'w;,i, o Here and in the following paragraphs, vector wm,k describes the vector of n hybrid subband parameters for the k'th subband of the subband domain. As indicated by the above equation, direct and diffuse signal parameters y are separately derived in the upmixing. The direct outputs hold the direct signal component and the residual signal, which is a signal that may be additionally present in MPEG coding. Diffuse outputs provide the diffuse signal only. According to the inventive concept, only the direct signal component is further processed by the guided envelope shaping (the inventive envelope shaping). The envelope shaping process employs an envelope extraction operation on different signals. The envelopes extraction process taking place within direct signal modifier 68 is described in further detail in the following paragraphs as this is a mandatory step before application of the inventive modification to the direct signal component. As already mentioned, within the hybrid subband domain, subbands are denoted k. Several subbands k may also be organized in parameter bands K. The association of subbands to parameter bands underlying the embodiment of the present invention discussed below, is given in the tabular of Fig. 4. First, for each slot in a frame, the energies EKslolof certain parameter bands A: are calculated with y",k being a hybrid subband input signal. EM = 2>"'V'Y k = {k \| K(k) = K) VKstart k with Kstarl=\Q and ^=18 The summation includes all k being attributed to one parameter band Kaccording to Table A.l. Subsequently, a long-term energy average EKslotior each parameter band is calculated as E0,(n) = (l-a)Eol(n) + aE:hl(n-l) ( 64 > a = exp \ 0.4-44100J With a being a weighting factor corresponding to a first order IIR lowpass (approx. 400 ms time constant) and n is denoting the time slot index. The smoothed total average (broadband) energy Emal is calculated to be E,a,a, («) = (1 - «) E,o,a, («) + aK,al O ~ 1) with i K«°p E,olAn) = = Z £K") ( 64 ^ a-exp { 0.4-44100J As can be seen from the above formulas, the temporal envelope is smoothed before the gain factors are derived from the smoothed representation of the channels. Smoothing generally means deriving a smoothed representation from an original channel having decreased gradients. As can be seen from the above formulas, the subsequently described whitening operation is based on temporally smoothed total energy estimates and smoothed energy estimates in the subbands, thus ensuring greater stability of the final envelope estimates. The ratio of these energies is determined to obtain weights for a spectral whitening operation: wK(n)=-E""a,(-n) ELto + e The broadband envelope estimate is obtained by summation of the weighted contributions of the parameter bands, normalizing on a long-term energy average and calculation of the square root Env(n)= \En^s^ \ Env{n) with Kstop EnvAbs{n)= £ wK(n)■ EKslot(n) K=Kstart E~m{n) = (1 - p)EnvAbs{n) + p~Env{n -1) R ( 64 1 p = exp V 0.04-44100J P is a weighting factor corresponding to a first order IIR lowpass (approx. 40 ms time constant). Spectrally whitened energy or amplitude measures are used as the basis for the calculation of the scaling factors. As can be seen from the above formulas, spectrally whitening means altering the spectrum such, that the same energy or mean amplitude is contained within each spectral band of the representation of the audio channels. This is most advantageous since the transient signals in question have very broad spectra such that it is necessary to use full information on the whole available spectrum for the calculation of the gain factors to not suppress the transient signals with respect to other non-transient signals. In other words, spectrally whitened signals are signals that have approximately equal energy in different spectral bands of their spectral representation. The inventive direct signal modifier modifies the direct signal component. As already mentioned, processing may be restricted to some subband indices starting with a starting index, in the presence of transmitted residual signals. Furthermore, processing may generally be restricted to subband indices above a threshold index. The envelope shaping process consists of a flattening of the direct sound envelope for each output channel followed by a reshaping towards a target envelope. This results in a gain curve being applied to the direct signal of each output channel if bsEnvShapeChannel=l is signalled for this channel in the side information. The processing is done for certain hybrid sub-subbands k only: k>l In presence of transmitted residual signals, k is chosen to start above the highest residual band involved in the upmix of the channel in question. For 5-1-5 configuration the target envelope is obtained by estimating the envelope of the transmitted downmix EnvDmx, as described in the previous section, and subsequently scaling it with encoder transmitted and re-quantized envelope ratios envRatioch . Then, a gain curve gch(n) for all slots in a frame is calculated for each output channel by estimating its envelope Envch and relate it to the target envelope. Finally, this gain curve is converted into an effective gain curve for solely scaling the direct part of the upmixed channel: ratioch (n) = min (4,max (0.25, gch + ampRatioch (n) ■ (gch -1))) with ,„, _ envRatioch {n) ■ EnvDmx (n) Envch{n) Y\v"'k I Z^jy ch,diffuse [ ampRatioch(n) = k. nk ■ / . ych,dmct + £ k che{L,Ls,C,R,Rs} For 5-2-5 configuration the target envelope for L and Ls is derived from the left channel transmitted downmix signal's envelope EnvDmxL, for R and Rs the right channel transmitted downmix envelope is used EnvDmxR. The center channel is derived from the sum of left and right transmitted downmix signal's envelopes. The gain curve is calculated for each output channel by estimating its envelope EnvL,Ls-c,R,Rs and relate it to the target envelope. In a second step this gain curve is converted into an effective gain curve for solely scaling the direct part of the upmixed channel: ratioch(ri) = min (4, max (0.25, gch + ampRatioch («) • (gch -1))) with ratioch («) = min (4,max (0.25, gch + ampRatioch(«) ■ {gch -1))) with o- ^ - CTVJ?fl^(")'£"V(") Envch{n) Y\v"'k I ampRatioch(n) = * nt = / .yc'h.airect I + £ k ch&{L,Ls,C,R,Rs) For 5-2-5 configuration the target envelope for L and Ls is derived from the left channel transmitted downmix signal's envelope EnvDmxL, for R and Rs the right channel transmitted downmix envelope is used EnvDmxR. The center channel is derived from the sum of left and right transmitted downmix signal's envelopes. The gain curve is calculated for each output channel by estimating its envelope EnvL-Ls-c-R,Rs and relate it to the target envelope. In a second step this gain curve is converted into an effective gain curve for solely scaling the direct part of the upmixed channel: ratioch («) = min (4, max (0.25, gch + ampRatioch (n) ■ (gch -1))) with y\vn-k I / i Y ch, diffuse \| ampRatioch(w) = * nk : , che{L,Ls,C,R,Rs] / ,\ych.diKct\+£ k n) = «n^OO^wOOf ch&{LM Envch{n) gch(n)=envRatio(n).EnvDmiR(n)^ Envch{n) (ri) = envRatioch (")' °-5 (EnvD^L O) + £"Vw (")) c/je(c} For all channels, the envelope adjustment gain curve is applied if bsEnvShapeChannel=l. ykdirec (") = ratio A (n) ■ ykchdirect («), che{L, Ls, C, R, Rs} Else the direct signal is simply copied ?**, (") = &+, («). che{Lt Ls, C, R, Rs) Finally, the modified direct signal component of each individual channel has to be combined with the diffuse signal component of the corresponding individual channel within the hybrid subband domain according to the following equation: yncH=yidiKc^y"cU^ che{L,Ls,C,R,Rs} As can be seen from the above paragraphs, the inventive concept teaches improving the perceptual quality and spatial distribution of applause-like signals in a spatial audio decoder. The enhancement is accomplished by deriving gain factors with fine scale temporal granularity to scale the direct part of the spatial upmix signal only. These gain factors are derived essentially from transmitted side information and level or energy measurements of the direct and diffuse signal in the encoder. As the above example particularly describes the calculation based on amplitude measurements, it should be noted that the inventive method is not restricted to this but could also calculate with, for example energy- measurements or other quantities suitable to describe a temporal envelope of a signal. The above example describes the calculation for 5-1-5 and 5-2-5 channel configurations. Naturally, the above outlined principle could be applied analogously for e.g. 7-2-7 and 7-5-7 channel configurations. Fig. 5 shows an example of an inventive multi-channel audio decoder 100, receiving a downmix channel 102 derived by downmixing a plurality of channels of one original multi-channel signal and a parameter representation 104 including information on a temporal structure of the original channels (left front, right front, left rear and right rear) of the original multi-channel signal. The multi-channel decoder 100 is having a generator 106 for generating a direct signal component and a diffuse signal component for each of the original channels underlying the downmix channel 102. The multi-channel decoder 100 further comprises four inventive direct signal modifiers 108a to 108d for each of the channels to be reconstructed, such that the multi-channel decoder outputs four output channels (left front, right front, left rear and right rear) on its outputs 112. Although the inventive multi-channel decoder has been detailed using an example configuration of four original channels to be reconstructed, the inventive concept may be implemented in multi-channel audio schemes having arbitrary numbers of channels. Fig. 6 shows a block diagram, detailing the inventive method of generating a reconstructed output channel. In a generation step 110, a direct signal component and a diffuse signal component is derived from the downmix channel, in a modification step 112 the direct signal component is modified using parameters of the parameter representation having information on a temporal structure of an original channel. In a combination step 114, the modified direct signal component and the diffuse signal component are combined to obtain a reconstructed output channel. 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 disk, DVD or a CD having electronically readable control signals stored thereon, which cooperate with a programmable computer system such that the inventive methods are performed. Generally, the present invention is, therefore, a computer program product with a program code stored on a machine readable carrier, the program code being operative for performing the inventive methods when the computer program product runs on a computer. In other words, 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 on a computer. While the foregoing has been particularly shown and described with reference to particular embodiments thereof, it will be understood by those skilled in the art that various other changes in the form and details may be made without departing from the spirit and scope thereof. It is to be understood that various changes may be made in adapting to different embodiments without departing from the broader concepts disclosed herein and comprehended by the claims that follow. WE CLAIM 1. Multi-channel reconstructor (30; 60) for generating a reconstructed output channel (50; 76) in an at least one downmix channel (38; 68) derived by downmixing a plurality of original channels and application of a parameter representation (40; 72), the parameter representation (40; 72) having information on a temporal structure of an original channel, comprising: a generator (32; 62) for generating a direct signal component (42; 64) and a diffuse signal component (44; 66) for the reconstructed output channel (50; 76), based on the downmix channel (38; 68); a direct signal modifier (34; 69) for modifying the direct signal component (42; 64) using the parameter representation (40; 72) without modifying the diffuse signal component using the information on the temporal structure of the original channel; and a combiner (36; 74) for combining the modified direct signal component (46) and the diffuse signal component (44; 66) to obtain the reconstructed output channel (50; 76). 2. Multi-channel reconstructor as claimed in claim 1, wherein the generator (32; 62) generates the direct signal component (42; 64) adapting only the components of the downmix channel (38; 68). 3. Multi-channel reconstructor (30; 60) as claimed in claims 1 or 2, wherein the generator (32; 62) generates the diffuse signal component (44; 66) in a filtered and/or delayed portion of the downmix channel (38; 68). 4. Multi-channel reconstructor (30; 60) as claimed in any of claims 1 to 3, wherein the direct signal modifier (34; 69) is adapting information on the temporal structure of the original channel indicating the energy contained in the original channel within a finite length time portion of the original channel. 5. Multi-channel reconstructor (30; 60) as claimed in any of claims 1 to 3, wherein the direct signal modifier (34; 69) applies information on the temporal structure of the original channel indicating a mean amplitude of the original channel within a finite length time portion of the original channel. 6. Multi-channel reconstructor (30; 60) as claimed in any of claims 1 to 5, wherein the combiner (36; 74) adds the modified direct signal component (46) and the diffuse signal component (44; 66) to obtain the reconstructed signal. 7. Multi-channel reconstructor as claimed in any of claims 1 to 6, wherein the multi-channel reconstructor adapts a first downmix channel having information on a left side of the plurality of original channels and a second downmix channel (38; 68) having information on a right side of the plurality of original channels, wherein a first reconstructed output channel (50; 76) for a left side is combined only in the direct and diffuse signal components generated from the first downmix channel and wherein a second reconstructed output channel for a right side is combined using direct and diffuse signal components generated only from the second downmix signal. 8. Multi-channel generator (30; 60) as claimed in any of claims 1 to 7, wherein the direct signal modifier (34; 68) is enabled to modify the direct signal for finite length time portions being shorter than frame time portions of additional parametric information within the parameter representation (40; 72), and wherein the additional parametric information is processed by the generator (32; 62) for generating the direct and the diffuse signal components. 9. Multi-channel generator (30; 60) as claimed in claim 8, wherein the generator (32; 62) is capable to apply additional parametric information having information on the energy of the original channel with respect to other channels of the plurality of original channels. 10. Multi-channel reconstructor (30; 60) as claimed in any of the preceding claims, wherein the direct signal modifier (34; 68) adapts information on a temporal structure of the original channel that is relating a temporal structure of the original channel to a temporal structure of the downmix channel (38; 68). 11. Multi-channel reconstructor (30; 60) as claimed in any of the preceding claims, wherein the information on the temporal structure of the original channel and the information on the temporal structure of the downmix channel is having an energy or an amplitude measure. 12. Multi-channel reconstructor (30; 60) as claimed in any of the preceding claims, wherein the direct signal modifier (34; 68) derives downmix temporal information on the temporal structure of the downmix channel (38; 68). 13. Multi-channel reconstructor (30; 60) as claimed in claim 12, wherein the direct signal modifier (34; 68) derives downmix temporal information indicating the energy contained in the downmix channel (38; 68) within a finite length time interval or an amplitude measure for the finite length time interval. 14. Multi-channel reconstructor (30; 60) as claimed in claims 12 or 13, wherein the direct signal modifier (34; 68) derives a target temporal structure for the reconstructed downmix channel (38; 68) with the application of downmix temporal information and the information on the temporal structure of the original channel. 15. Multi-channel reconstructor (30; 60) as claimed in any of claims 12 to 14, wherein the direct signal modifier (34; 68) derives the downmix temporal information for a spectral portion of the downmix channel (38; 68) above a spectral lower bound. 16. Multi-channel reconstructor (30; 60) as claimed in any of claims 12 to 15, wherein the direct signal modifier (34; 68) spectrally whitens the downmix channel (38; 68) and derives the downmix temporal information using the spectrally whitened downmix channel (38; 68). 17. Multi-channel reconstructor (30; 60) as claimed in any of claims 12 to 16, wherein the direct signal modifier (34; 68) derives a smoothed representation of the downmix channel (38; 68) and also derives the downmix temporal information from the. smoothed representation of the downmix channel. 18. Multi-channel reconstructor (30; 60) as claimed in claim 17, wherein the direct signal modifier (34; 68) derives the smoothed representation by filtering the downmix channel (38; 68) with a first order lowpass filter. 19. Multi-channel reconstructor (30; 60) as claimed in any of the previous claims, wherein the direct signal modifier (34; 68) derives information on a temporal structure of a combination of the direct signal component and the diffuse signal component. 20. Multi-channel reconstructor (30; 60) as claimed in claim 19, wherein the direct signal modifier (34; 68) spectrally whitens the combination of the direct signal and the diffuse signal components and derives the information on the temporal structure of the combination of the direct signal and the diffuse signal components using the spectrally whitened direct and diffuse signal components. 21. Multi-channel reconstructor (30; 60) as claimed in claims 19 or 20, wherein the direct signal modifier (34; 68) derives a smoothed representation of the combination of the direct and the diffuse signal components and also derives the information on the temporal structure of the combination of the direct and the diffuse signal components from the smoothed representation of the combination of the direct and the diffuse signal components. 22. Multi-channel reconstructor (30; 60) as claimed in claim 21, wherein the direct signal modifier (34; 68) derives the smoothed representation of the combination of the direct and the diffuse signal components by filtering the direct and the diffuse signal components with a first order lowpass filter. 23. Multi-channel reconstructor (30; 60) as claimed in any of the previous claims, wherein the direct signal modifier (34; 68) applies information on the temporal structure of the original channel representing a ratio of the energy or amplitude for a finite length time interval of the original channel and the energy or amplitude for the original channel and the energy or amplitude for the finite length time interval of the downmix channel (38; 68). 24. Multi-channel reconstructor (30; 60) as claimed in any of the previous claims, wherein the direct signal modifier (34; 68) derives a target temporal structure for the reconstructed output channel (50; 76) adapting the downmix channel (38; 68) and the information on the temporal structure. 25. Multi-channel reconstructor (30; 60) as claimed in claim 23, wherein the direct signal modifier (34; 68) is enabled to modify the direct signal component such that a temporal structure of the reconstructed output channel (50; 76) equals the target temporal structure within a tolerance range. 26. Multi-channel reconstructor (30; 60) as claimed in claim 24, wherein the direct signal modifier (34; 68) derives an intermediate scaling factor, the intermediate scaling factor being such that the temporal structure of the reconstructed output channel (50; 76) equals the target temporal structure within the tolerance range, when the reconstructed output channel (50; 76) equals the target temporal structure within the tolerance range, when the reconstructed output channel (50; 76) is combined using the direct signal components scaled with the intermediate scaling factor and the diffuse signal component scaled with the intermediate scaling factor. 27. Multi-channel reconstructor (30; 60) as claimed in claim 25, wherein the direct signal modifier (34; 68) derives a final scaling factor using the intermediate scaling factor and the direct and diffuse signal components such that the temporal structure of the reconstructed output channel (50; 76) equals the target temporal structure within the tolerance range, when the reconstructed output channel (50; 76) is combined using the diffuse signal component and the direct signal component scaled using the final scaling factor. 28. Method for generating a reconstructed output channel (50; 76) in at least one downmix channel (38; 68) derived by downmixing a plurality of original channels and adapting a parameter representation (40; 72), the parameter representation (40; 72) having information on a temporal structure of an original channel, the method comprising: generating a direct signal component and a diffuse signal component for the reconstructed output channel (50; 76), based on the downmix channel (38; 68); modifying the direct signal component with the application of the parameter representation (40; 72) without modifying the diffuse signal component using the information on the temporal structure of the original channel; and combining the modified direct signal component (46) and the diffuse signal component to obtain the reconstructed output channel (50; 76). 29. Multi-channel audio decoder for generating a reconstruction of a multi- channel signal using at least one downmix channel (38; 68) derived by downmixing a plurality of original channels and adapting a parameter representation (40; 72), the parameter representation (40; 72) having information on a temporal structure of an original channel, the multi- channel audio decoder, comprising a multi-channel reconstructor as claimed in claims 1 to 27. ABSTRACT TITLE: MULTI-CHANNEL RECONSTRUCTOR AND ENHANCED METHOD FOR SIGNAL SHAPING IN MULTI-CHANNEL AUDIO RECONSTRUCTION A reconstructed output channel, reconstructed with a multi-channel reconstructor using at least one downmix channel derived by downmixing a plurality of original channels and using a parameter representation including additional information on a temporal fine structure of an original channel can be generated using a generator (32) for generating a direct signal component (42) and a diffuse signal component (44) based on the downmix channel (38) is used. Only the direct signal component (42) is modified (34) such that the temporal (40) fine structure of the reconstructed output channel is fitting a desired temporal fine structure, indicated by the additional information on the temporal fine structure transmitted.

Full Text

Enhanced method for signal shaping in multi-channel audio
reconstruction
Description
Field of the Invention
The present invention relates to a concept of enhanced
signal shaping in multi-channel audio reconstruction and in
particular to a new approach of envelope shaping.
Background of the Invention and Prior Art
Recent development in audio coding enables recreation of 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
solutions, such as Dolby Prologic, since additional control
data is transmitted to control the recreation, also
referred to as up-mix, of the surround channels based on
the transmitted mono or stereo channels. Such parametric
multi-channel audio decoders reconstruct N channels based
on M transmitted channels, where N > M, and the additional
control data. Using the additional control data causes a
significantly lower data rate than transmitting all N
channels, making the coding very efficient, while at the
same time ensuring compatibility with both M channel
devices and N channel devices. The M channels can either be
a single mono channel, a stereo channel, or a 5.1 channel
representation. Hence, it is possible to have an 7.2
channel original signal, downmixed to a 5.1 channel
backwards compatible signal, and spatial audio parameters
enabling a spatial audio decoder to reproduce a closely
resembling version of the original 7.2 channels, at a small
additional bit rate overhead.

These parametric surround coding methods usually comprise a
parameterization of the surround signal based on time and
frequency variant ILD (Inter Channel Level Difference) and
ICC (Inter Channel Coherence) parameters. These parameters
describe e.g. power ratios and correlations between channel
pairs of the original multi-channel signal. In the decoding
process, the re-created multichannel signal is obtained by
distributing the energy of the received downmix channels
between all the channel pairs as described by the
transmitted ILD parameters. However, since a multi-channel
signal can have equal power distribution between all
channels, while the signals in the different channels are
very different, thus giving the listening impression of a
very wide sound, the correct wideness is obtained by mixing
signals with decorrelated versions of the same, as
described by the ICC parameter.
The decorrelated version of the signal, often also referred
to as wet or diffuse signal, is obtained by passing the
signal through a reverberator, such as an all-pass filter.
A simple form of decorrelation is applying a specific delay
to the signal. Generally, there are a lot of different
reverberators known in the art, the precise implementation
of the reverberator used is of minor importance.
The output from the decorrelator has a time response that
is usually very flat. Hence, a dirac input signal gives a
decaying noise burst out. When mixing the decorrelated and
the original signal, it is for some transient signal types,
like applause signals, important to perform some post-
processing on the signal to avoid perceptuality of
additionally introduced artefacts that may result in a
larger perceived room size and pre-echo type of artefacts.
Generally, the invention relates to a system that
represents multi-channel audio as a combination of audio
downmix data (e.g. one or two channels) and related
parametric multi-channel data. In such a scheme (for

example in binaural cue coding) an audio downmix data
stream is transmitted, wherein it may be noted that the
simplest form of downmix is simply adding the different
signals of a multi-channel signal. Such a signal (sum
signal) is accompanied by a parametric multi-channel data
stream (side info). The side info comprises for example one
or more of the parameter types discussed above to describe
the spatial interrelation of the original channels of the
multi-channel signal. In a sense, the parametric multi-
channel scheme acts as a pre-/post-processor to the
sending/receiving end of the downmix data, e.g. having the
sum signal and the side information. It shall be noted that
the sum signal of the downmix data may additionally be
coded using any audio or speech coder.
As transmission of multi-channel signals over low-bandwidth
carriers is becoming more and more popular these systems,
also known under "spatial audio coding", "MPEG surround",
have been well developed recently.
The following publications are known in the context of
these technologies:
[1] C. Faller and F. Baumgarte, "Efficient representation
of spatial audio using perceptual parametrization," in
Proc. IEEE WASPAA, Mohonk, NY, Oct. 2001.
[2] F. Baumgarte and C. Faller, "Estimation of auditory
spatial cues for binaural cue coding," in Proc. ICASSP
2002, Orlando, FL, May 2002.
[3] C. Faller and F. Baumgarte, "Binaural cue coding: a
novel and efficient representation of spatial audio," in
Proc. ICASSP 2002, Orlando, FL, May 2002.
[4] F. Baumgarte and C. Faller, "Why binaural cue coding is
better than intensity stereo coding," in Proc. AES 112th
Conv., Munich, Germany, May 2002.

[5] C. Faller and F. Baumgarte, "Binaural cue coding
applied to stereo and multi-channel audio compression," in
Proc. AES 112th Conv., Munich, Germany, May 2002.
[6] F. Baumgarte and C. Faller, "Design and evaluation of
binaural cue coding," in AES 113th Conv., Los Angeles, CA,
Oct. 2002.
[7] C. Faller and F. Baumgarte, "Binaural cue coding
applied to audio compression with flexible rendering," in
Proc. AES 113th Conv., Los Angeles, CA, Oct. 2002.
[8] J. Breebaart, J. Herre, C. Faller, J. Roden, F. Myburg,
S. Disch, H. Purnhagen, G. Hoto, M. Neusinger, K. Kjorling,
W. Oomen: "MPEG Spatial Audio Coding / MPEG Surround:
Overview and Current Status", 119th AES Convention, New
York 2005, Preprint 6599
[9] J. Herre, H. Purnhagen, J. Breebaart, C. Faller, S.
Disch, K. Kjorling, E. Schuijers, J. Hilpert, F. Myburg,
"The Reference Model Architecture for MPEG Spatial Audio
Coding", 118th AES Convention, Barcelona 2005, Preprint
6477
[10] J. Herre, C. Faller, S. Disch, C. Ertel, J. Hilpert,
A. Hoelzer, K. Linzmeier, C. Spenger, P. Kroon: "Spatial
Audio Coding: Next-Generation Efficient and Compatible
Coding of Multi-Channel Audio", 117th AES Convention, San
Francisco 2004, Preprint 6186
[11] J. Herre, C. Faller, C. Ertel, J. Hilpert, A Hoelzer,
C. Spenger: "MP3 Surround: Efficient and Compatible Coding
of Multi-Channel Audio", 116th AES Convention, Berlin 2004,
Preprint 604 9.
A related technique, focusing on transmission of two
channels via one transmitted mono signal is called

"parametric stereo" and for example described more
extensively in the following publications:
[12] J. Breebaart, S. van de Par, A. Kohlrausch, E.
Schuijers, "High-Quality Parametric Spatial Audio Coding at
Low Bitrates", AES 116th Convention, Berlin, Preprint 6072,
May 2004
[13] E. Schuijers, J. Breebaart, H. Purnhagen, J.
Engdegard, "Low Complexity Parametric Stereo Coding", AES
116th Convention, Berlin, Preprint 6073, May 2004.
In a spatial audio decoder, the multi-channel upmix is
computed from a direct signal part and a diffuse signal
part, which is derived by means of decorrelation from the
direct part, as already mentioned above. Thus, in general,
the diffuse part has a different temporal envelope than the
direct part. The term "temporal envelope" describes in this
context the variation of the energy or amplitude of the
signal with time. The differing temporal envelope leads to
artifacts (pre- and post-echoes, temporal "smearing") in
the upmix signals for input signals that have a wide stereo
image and, at the same time, a transient envelope
structure. Transient signals generally are signals that are
varying strongly in a short time period.
The probably most important examples for this class of
signals are applause-like signals, which are frequently
present in live recordings.
In order to avoid artefacts caused by introducing
diffuse/decorrelated sound with an inappropriate temporal
envelope into the upmix signal, a number of techniques have
been proposed:
The US application 11/006,492 ("Diffuse Sound Shaping for
BCC Schemes and The Like") shows that the perceptual
quality of critical transient signals can be improved by

shaping the temporal envelope of the diffuse signal to
match the temporal envelope of the direct signal.
This approach has already been introduced into MPEG
surround technology by different tools, such as "temporal
envelope shaping" (TES) and the "temporal processing" (TP).
Since the target temporal envelope of the diffuse signal is
derived from the envelope of the transmitted downmix
signal, this method does not require additional side
information to be transmitted. However, as a consequence,
the temporal fine structure of the diffuse sound is the
same for all output channels. As the direct signal part,
which is directly derived from the transmitted downmix
signal, does also have a similar temporal envelope, this
method may improve the perceptual quality of applause-like
signals in terms of "crisp-ness", i.e. However, as then the
direct signal and diffuse signal have similar temporal
envelopes for all channels, such techniques may enhance the
subjective quality of applause-like signals but cannot
improve the spatial distribution of single applause events
in the signal, as this would only be possible, when one
reconstructed channel would be much more intense at the
occurrence of the transient signal than the other channels,
which is impossible having signals sharing basically the
same temporal envelope.
An alternative method to overcome the problem is described
by US application 11/006,482 ("individual Channel Shaping
for BCC Schemes and The Like"). This approach employs fine-
grain temporal broad band side information that is
transmitted by the encoder to perform a fine temporal
shaping of both the direct and the diffuse signal.
Evidently, this approach allows a temporal fine structure
that is individual for each output channel and thus is able
to accommodate also signals for which transient events
occur in only a subset of the output channels. A further
variation of this approach is described in US 60/726,389
("Methods for Improved Temporal and Spatial Shaping of

Multi-Channel Audio Signals"). Both discussed approaches to
enhance perceptual quality of transient coded signals
comprise a temporal shaping of the envelope of the diffuse
signal intended to match a corresponding direct signals
temporal envelope.
While both previously described prior-art methods can
enhance the subjective quality of applause-like signals in
terms of crisp-ness, only the latter approach can also
improve the spatial redistribution of the reconstructed
signal. Still, the subjective quality of the synthesized
applause signals remains unsatisfactory, because the
temporal shaping of both the combination of dry and
diffused sound leads to characteristic distortions (the
attacks of the individual claps are either perceived as not
"tight" when only a loose temporal shaping is performed, or
distortions are introduced if shaping with a very high
temporal resolution is applied to the signal). This becomes
evident, when a diffuse signal is simply a delayed copy of
the direct signal. Then, the diffused signal mixed to the
direct signal is likely to have a different spectral
composition than the direct signal. Thus, even if the
envelope is scaled to match the envelope of the direct
signal, different spectral contributions, not originating
directly from the original signal will be present in the
reconstructed signal. The introduced distortions may become
even worse, when the diffuse signal part is emphasized
(made louder) during the reconstruction, when the diffuse
signal is scaled to match the envelope of the direct
signal.
Summary of the Invention
It is the object of the present invention to provide a
concept of enhanced signal shaping in multi-channel
reconstruction.

This object is achieved by an apparatus in accordance with
claims 1 or 29, a method in accordance with claim 2 8 and a
computer program in accordance with claim 30.
The present invention is based on the finding that a
reconstructed output channel, reconstructed with a multi-
channel reconstructor using at least one downmix channel
derived by downmixing a plurality of original channels and
using a parameter representation including additional
information on a temporal (fine) structure of an original
channel can be reconstructed efficiently with high
quality, when a generator for generating a direct signal
component and a diffuse signal component based on the
downmix channel is used. The quality can be essentially
enhanced, if only the direct signal component is modified
such that the temporal fine structure of the reconstructed
output channel is fitting a desired temporal fine
structure, indicated by the additional information on the
temporal fine structure transmitted.
In other words, scaling the direct signal parts directly
derived from the downmix signal, hardly introduces
additional artifacts at the moment a transient signal
occurs. When, as in prior art, the wet signal part is
scaled to match a desired envelope, it may very well be
the case that the original transient signal in the
reconstructed channel is masked by an emphasized diffuse
signal mixed to the direct signal, which will be more
extensively described below.
The present invention overcomes this problem by only
scaling the direct signal component, thus giving no
opportunity to introduce additional artifacts at the cost
of transmitting additional parameters to describe the
temporal envelope within the side information.
According to one embodiment of the present invention,
envelope scaling parameters are derived using a

representation of the direct and the diffuse signal with a
whitened spectrum, i.e., where different spectral parts of
the signal have almost identical energies. The advantages
of using whitened spectra are twofold. One the one hand,
using a whitened spectrum as a basis for the calculation
of a scaling factor used to scale the direct signal allows
for the transmission of only one parameter per time slot
including information on the temporal structure. As it is
usual in multi-channel audio coding that signals are
processed within numerous frequency bands, this feature
helps to decrease the number of additionally needed side
information and hence the bit rate increase for the
transmission of the additional parameter. Typically, other
parameters such as ICLD and ICC are transmitted once per
time frame and parameter band. As the number of parameter
bands may be higher than 20, it is a major advantage
having to transmit only one single parameter per channel.
Generally, in multi-channel coding, signals are processed
in a frame structure, i.e., in entities having several
sampling values, for example 1024 per frame. Furthermore,
as already mentioned, the signals are split into several
spectral portions before being processed, such that
finally typically one ICC and ICLD parameter is
transmitted per frame and spectral portion of the signal.
The second advantage of using only one parameter is
physically motivated, since the transient signals in
question naturally have broad spectra. Therefore, to
account for the energy of the transient signals within the
single channels correctly, it is most appropriate to use
whitened spectra for the calculation of energy scaling
factors.
In a further embodiment of the present invention the
inventive concept of modifying the direct signal component
is only applied for a spectral portion of the signal above
a certain spectral limit in the presence of additional
residual signals. This is because residual signals

together with the downmix signal allow for a high quality-
reproduction of the original channels.
Summarizing, the inventive concept is designed to provide
enhanced temporal and spatial quality with respect to the
prior art approaches, avoiding the problems associated
with those techniques. Therefore, side information is
transmitted to describe the fine time envelope structure
of the individual channels and thus allow fine
temporal/spatial shaping of the upmix channel signals at
the decoder side. The inventive method described in this
document is based on the following
findings/considerations:
• Applause-like signals can be seen as composed of
single, distinct nearby claps and a noise-like
ambience originating from very dense far-off claps.
• In a spatial audio decoder, the best approximation of
the nearby claps in terms of temporal envelope is the
direct signal. Therefore, only the direct signal is
processed by the inventive method.
• Since the diffuse signal represents mainly the
ambience part of the signal, any processing on a fine
temporal resolution is likely to introduce distortion
and modulation artefacts (even though a certain
subjective enhancement of applause ^crispness' might
be achieved by such a technique). As a consequence to
these considerations, thus the diffuse signal is
untouched (i.e. not subjected to a fine time shaping)
by the inventive processing.
• Nevertheless the diffuse signal contributes to the
energy balance of the upmixed signal. The inventive
method accounts for this by calculating a modified
broadband scaling factor from the transmitted
information that is to be applied solely to the direct
signal part. This modified factor is chosen such that
the overall energy in a given time interval is the

same within certain bounds as if the original factor
had been applied to both the direct and the diffuse
part of the signal in this interval.
• Using the inventive method, best subjective audio
quality is obtained if the spectral resolution of the
spatial cues is chosen to be low - for instance 'full
bandwidth' - to ensure preservation of spectral
integrity of the transients contained in the signal.
In this case, the proposed method does not necessarily
increase the average spatial side information bitrate,
since spectral resolution is safely traded for
temporal resolution.
The subjective quality improvement is achieved by
amplifying or damping ("shaping") the dry part of the
signal over time only and thus
• Enhancing transient quality by strengthening the
direct signal part at the transient location, while
avoiding additional distortion originating from a
diffuse signal with inappropriate temporal envelope
• Improving spatial localisation by emphasizing the
direct part w.r.t. the diffuse part at the spatial
origin of a transient event and damping it relative to
the diffuse part at far-off panning positions.
Brief Description of the Drawings
Fig. 1 shows a block diagram of a multi-channel encoder
and a corresponding decoder;
Fig. lb shows a schematic sketch of signal reconstruction
using decorrelated signals;
Fig. 2 shows an example for an inventive multi-channel
reconstructor;

Fig. 3 shows a further example for an inventive multi-
channel reconstructor;
Fig. 4 shows an example for parameter band
representations used to identify different
parameter bands within a multi-channel decoding
scheme;
Fig. 5 shows an example for an inventive multi-channel
decoder; and
Fig. 6 shows a block diagram detailing an example for an
inventive method of reconstructing an output
channel;
Detailed Description of the further embodiments
Fig. 1 shows an example for coding of multi-channel audio
data according to prior art, to more clearly illustrate
the problem solved by the inventive concept.
Generally, on an encoder side, an original multi-channel
signal 10 is input into the multi-channel encoder 12,
deriving side information 14 indicating the spatial
distribution of the various channels of the original
multi-channel signals with respect to one another. Apart
from the generation of side information 14, a multi-
channel encoder 12 generates one or more sum signals 16,
being downmixed from the original multi-channel signal.
Famous configurations widely used are so-called 5-1-5 and
5-2-5 configurations. In 5-1-5 configuration the encoder
generates one single monophonic sum signal 16 from five
input channels and hence, a corresponding decoder 18 has
to generate five reconstructed channels of a reconstructed
multi-channel signal 20. In the 5-2-5 configuration, the
encoder generates two downmix channels from five input
channels, the first channel of the downmixed channels

typically holding information on a left side or a right
side and the second channel of the downmixed channels
holding information on the other side.
Sample parameters describing the spatial distribution of
the original channels are, as for example indicated in
Fig. 1, the previously introduced parameters ICLD and ICC.
It may be noted that within the analysis deriving the side
information 14, the samples of the original channels of
the multi-channel signal 10 are typically processed in
subband domains representing a specific frequency interval
of the original channels. A single frequency interval is
indicated by K. In some applications, the input channels
may be filtered by a hybrid filter bank before the
processing, i.e., the parameter bands K may be further
subdivided, each subdivision denoted with k.
Furthermore, the processing of the sample values
describing an original channel, is done in a frame-wise
manner within each single parameter band, i.e. several
consecutive samples form a frame of finite duration. The
BCC parameters mentioned above typically describe a full
frame.
A parameter in some way related to the present invention
and already known in the art is the ICLD parameter,
describing the energy contained within a signal frame of a
channel with respect to the corresponding frames of other
channels of the original multi-channel or signal.
Commonly, the generation of additional channels to derive
a reconstruction of a multi-channel signal from one
transmitted sum signal only is achieved with the help of
decorrelated signals, being derived from the sum signal
using decorrelators or reverberators. For a typical
application, the discrete sample frequency may be 44.100
kH, such that a single sample represents an interval of

finite length of about 0.02 ms of an original channel. It
may be noted that, using filter banks, the signal is split
into numerous signal parts, each representing a finite
frequency interval of the original signal. To compensate
for a possible increase in parameters describing the
channel, the time resolution is normally decreased, such
that a finite length time portion described by a single
sample within a filter bank domain may increase to more
than 0.5 ms. Typical frame length may vary between 10 and
15 ms.
Deriving the decorrelated signal may make use of different
filter structures and/or delays or combinations thereof
without limiting the scope of the invention. It may be
furthermore noted that not necessarily the whole spectrum
has to be used to derive the decorrelated signals. For
example, only spectral portions above a spectral lower
bound (specific value of K) of the sum signal (downmix
signal) may be used to derive the decorrelated signals
using delays and/or filters. A decorrelated signal thus
generally describes a signal derived from the downmix
signal (downmix channel) such that a correlation
coefficient, when derived using the decorrelated signal
and the downmix channel significantly deviates from unity,
for example by 0.2.
Fig. lb gives an extremely simplified example of the down-
mix and reconstruction process during multi-channel audio
coding to explain the great benefit of the inventive
concept of scaling only the direct signal component during
reconstruction of a channel of a multi-channel signal. For
the following description, some simplifications are
assumed. The first simplification is that the down-mix of a
left and a right channel is a simple addition of the
amplitudes within the channels. The second strong
simplification is, that the correlation is assumed to be a
simple delay of the whole signal.

Under these assumptions, a frame of a left channel 21a and
a right channel 21b shall be encoded. As indicated on the
x-axis of the shown windows, in multi-channel audio coding,
the processing is typically performed on sample values,
sampled with a fixed sample frequency. This shall, for ease
of explanation, be furthermore neglected in the following
short summary.
As already mentioned, on the encoder side, a left and right
channel is combined (down-mixed) into a down-mix channel 22
that is to be transmitted to the decoder. On the decoder
side, a decorrelated signal 23 is derived from the
transmitted down-mix channel 22, which is the sum of the
left channel 21a and the right channel 21b in this example.
As already explained, the reconstruction of the left
channel is then performed from signal frames derived from
the down-mix channel 22 and the decorrelated signal 23.
It may be noted that each single frame is undergoing a
global scaling before the combination, as indicated by the
ICLD parameter, which relates the energies within the
individual frames of single channels to the energy of the
corresponding frames of the other channels of a multi-
channel signal.
As it is assumed in the present example, that equal
energies are contained within the frame of the left
channel 21a and the frame of the right channel 21b, the
transmitted down-mix channel 22 and the decorrelated
signal 23 are scaled by roughly the factor of 0.5 before
the combination. That is, when up-mixing is equally simple
as down-mixing, i.e. summing up the two signals, the
reconstruction of the original left channel 21a is the sum
of the scaled down-mix channel 24a and the scaled
decorrelated signal 24b.
Because of the summation for transmission and the scaling
due to the ICLD parameter, the signal to background ratio

of the transient signal would be decreased by a factor of
roughly 2. Furthermore, when simply adding the two signals,
, an additional echo type of artefact would be introduced
at the position of the delayed transient structure in the
scaled decorrelated signal 24b.
As indicated in Fig. lb, prior art tries to overcome the
echo problem by scaling the amplitude of the scaled
decorrelated signal 24b to make it match the envelope of
the scaled transmitted channel 24a, as indicated by the
dashed lines in frame 24b. Due to the scaling, the
amplitude at the position of the original transient signal
in the left channel 21a may be increased. However, the
spectral composition of the decorrelated signal at the
position of the scaling in frame 24b is different from the
spectral composition of the original transient signal.
Therefore, audible artefacts are introduced into the
signal, even though the general intensity of the signal may
be reproduced well.
The great advantage of the present invention is that the
present invention does only scale a direct signal component
of reconstructed. As this channel does have a signal
component corresponding to the original transient signal
having the right spectral composition and the right timing,
scaling only the down-mix channel will yield a
reconstructed signal reconstructing the original transient
event with high accuracy. This is the case since only
signal parts are emphasized by the scaling that have the
same spectral composition as the original transient signal.
Fig. 2 shows a block diagram of a example of an inventive
multi-channel reconstructor, to detail the principal of
the inventive concept.
Fig. 2 shows a multi-channel reconstructor 30, having a
generator 32, a direct signal modifier and a combiner 36.
The generator 32 receives a downmix channel 38 downmixed

from a plurality of original channels and a parameter
representation 40 including information on a temporal
structure of an original channel.
The generator generates a direct signal component 42 and a
diffuse signal component 44 based on the downmix channel.
The direct signal modifier 34 receives as well the direct
signal component 42 as the diffuse signal component 44 and
in addition the parameter representation 40 having the
information on a temporal structure of the original
channel. According to the present invention, the direct
signal modifier 34 modifies only the direct signal
component 42 using the parameter representation to derive
a modified direct signal component 46.
The modified direct signal component 4 6 and the diffuse
signal component 44, which is not altered by the direct
signal modifier 34, are input into the combiner 36 that
combines the modified direct signal component 4 6 and the
diffuse signal component 44 to obtain a reconstructed
output channel 50.
By only modifying the direct signal component 42 derived
from the transmitted downmix channel 38 without
reverberation (decorrelation), it is possible to
reconstruct a time envelope for the reconstructed output
channel matching closely a time envelope of the underlying
original channel without introducing additional artefacts
and audible distortions, as in prior art techniques.
As will be discussed in more detail in the description of
Fig. 3, the inventive envelope shaping restores the broad
band envelope of the synthesized output signal. It
comprises a modified upmix procedure, followed by envelope
flattening and reshaping of the direct signal portion of
each output channel. For reshaping, parametric broad band
envelope side information contained in the bit stream of

the parameter representation is used. This side
information consists, according to one embodiment of the
present invention, of ratios (envRatio) relating the
transmitted downmix signal's envelope to the original
input channel signal's envelope. In the decoder, gain
factors are derived from these ratios to be applied to the
direct signal on each time slot in a frame of a given
output channel. The diffuse sound portion of each channel
is not altered according to the inventive concept.
The preferred embodiment of the present invention shown in
the block diagram of Fig. 3 is a multi-channel
reconstructor 60 modified to fit in the decoder signal
flow of a MPEG spatial decoder.
The multi-channel reconstructor 60 comprises a generator
62 for generating a direct signal component 64 and a
diffuse signal component 66 using a downmix channel 68
derived by downmixing a plurality of original channels and
a parameter representation 70 having information on
spatial properties of original channels of the multi-
channel signal, as used within MPEG coding. The multi-
channel reconstructor 60 further comprises a direct signal
modifier 68, receiving the direct signal component 64, the
diffuse signal component 66, the downmix signal 69 and
additional envelope side information 72 as input.
The direct signal modifier provides at its modifier output
73 the modified direct signal component, modified as
described in more detail below.
The combiner 74 receives the modified direct signal
component and the diffuse signal component to obtain the
reconstructed output channel 76.
As shown in the Figure, the present invention may be
easily implemented in already existing multi-channel
environments. General application of the inventive concept

within such a coding scheme could be switched on and off
according to some parameters additionally transmitted
within the parameter bit stream. For example, an
additional flag bsTempShapeEnable could be introduced,
which indicates, when set to 1, usage of the inventive
concept is required.
Furthermore, an additional flag could be introduced,
specifying specifically the need of the application of the
inventive concept on a channel by channel basis.
Therefore, an additional flag may be used, called for
example bsEnvShapeChannel. This flag, available for each
individual channel, may then indicate the use of the
inventive concept, when set to 1.
It may furthermore be noted that for ease of presentation,
only a two channel configuration is described in Fig. 3.
Of course, the present invention is not intended to be
limited to a two channel configuration only. Moreover, any
channel configuration may be used in connection with the
inventive concept. For example, five or seven input
channels may be used in connection with the inventive
advanced envelope shaping.
When the inventive concept is applied within an MPEG
coding scheme, as indicated in Fig. 3, and the application
of the inventive concept is signaled by setting
bsTempShapeEnable equal to 1, direct and diffuse signal
components are synthesized separately by generator 62
using a modified post-mixing in the hybrid subband domain
according to the following formula:
y:;L=M"'*w;,i, o Here and in the following paragraphs, vector wm,k describes
the vector of n hybrid subband parameters for the k'th

subband of the subband domain. As indicated by the above
equation, direct and diffuse signal parameters y are
separately derived in the upmixing. The direct outputs
hold the direct signal component and the residual signal,
which is a signal that may be additionally present in MPEG
coding. Diffuse outputs provide the diffuse signal only.
According to the inventive concept, only the direct signal
component is further processed by the guided envelope
shaping (the inventive envelope shaping).
The envelope shaping process employs an envelope
extraction operation on different signals. The envelopes
extraction process taking place within direct signal
modifier 68 is described in further detail in the
following paragraphs as this is a mandatory step before
application of the inventive modification to the direct
signal component.
As already mentioned, within the hybrid subband domain,
subbands are denoted k. Several subbands k may also be
organized in parameter bands K.
The association of subbands to parameter bands underlying
the embodiment of the present invention discussed below,
is given in the tabular of Fig. 4.
First, for each slot in a frame, the energies EKslolof certain
parameter bands A: are calculated with y",k being a hybrid
subband input signal.
EM = 2>"'V'*Y k = {k | K(k) = K) VKstart k
with Kstarl=\Q and ^=18

The summation includes all k being attributed to one
parameter band Kaccording to Table A.l.
Subsequently, a long-term energy average EKslotior each
parameter band is calculated as
E*0,(n) = (l-a)E*ol(n) + aE:hl(n-l)
( 64 >
a = exp
\ 0.4-44100J
With a being a weighting factor corresponding to a first
order IIR lowpass (approx. 400 ms time constant) and n is
denoting the time slot index. The smoothed total average
(broadband) energy Emal is calculated to be
E,a,a, («) = (1 - «) E,o,a, («) + aK,al O ~ 1)
with
i K«°p
E,olAn) = = Z £K")
( 64 ^
a-exp
{ 0.4-44100J
As can be seen from the above formulas, the temporal
envelope is smoothed before the gain factors are derived
from the smoothed representation of the channels. Smoothing
generally means deriving a smoothed representation from an
original channel having decreased gradients.
As can be seen from the above formulas, the subsequently
described whitening operation is based on temporally
smoothed total energy estimates and smoothed energy
estimates in the subbands, thus ensuring greater stability
of the final envelope estimates.

The ratio of these energies is determined to obtain weights
for a spectral whitening operation:
wK(n)=-E""a,(-n)
ELto + e
The broadband envelope estimate is obtained by summation of
the weighted contributions of the parameter bands,
normalizing on a long-term energy average and calculation
of the square root
Env(n)= \En^s^
\ Env{n)
with
Kstop
EnvAbs{n)= £ wK(n)■ EKslot(n)
K=Kstart
E~m{n) = (1 - p)EnvAbs{n) + p~Env{n -1)
R ( 64 1
p = exp
V 0.04-44100J
P is a weighting factor corresponding to a first order
IIR lowpass (approx. 40 ms time constant).
Spectrally whitened energy or amplitude measures are used
as the basis for the calculation of the scaling factors. As
can be seen from the above formulas, spectrally whitening
means altering the spectrum such, that the same energy or
mean amplitude is contained within each spectral band of
the representation of the audio channels. This is most
advantageous since the transient signals in question have
very broad spectra such that it is necessary to use full
information on the whole available spectrum for the
calculation of the gain factors to not suppress the
transient signals with respect to other non-transient
signals. In other words, spectrally whitened signals are

signals that have approximately equal energy in different
spectral bands of their spectral representation.
The inventive direct signal modifier modifies the direct
signal component. As already mentioned, processing may be
restricted to some subband indices starting with a
starting index, in the presence of transmitted residual
signals. Furthermore, processing may generally be
restricted to subband indices above a threshold index.
The envelope shaping process consists of a flattening of
the direct sound envelope for each output channel followed
by a reshaping towards a target envelope. This results in a
gain curve being applied to the direct signal of each
output channel if bsEnvShapeChannel=l is signalled for this
channel in the side information.
The processing is done for certain hybrid sub-subbands k
only:
k>l
In presence of transmitted residual signals, k is chosen
to start above the highest residual band involved in the
upmix of the channel in question.
For 5-1-5 configuration the target envelope is obtained by
estimating the envelope of the transmitted downmix EnvDmx,
as described in the previous section, and subsequently
scaling it with encoder transmitted and re-quantized
envelope ratios envRatioch .
Then, a gain curve gch(n) for all slots in a frame is
calculated for each output channel by estimating its
envelope Envch and relate it to the target envelope.
Finally, this gain curve is converted into an effective
gain curve for solely scaling the direct part of the
upmixed channel:

ratioch (n) = min (4,max (0.25, gch + ampRatioch (n) ■ (gch -1)))
with
,„, _ envRatioch {n) ■ EnvDmx (n)
Envch{n)
Y\v"'k I
Z^jy ch,diffuse [
ampRatioch(n) = k. nk ■
/ . ych,dmct + £
k
che{L,Ls,C,R,Rs}
For 5-2-5 configuration the target envelope for L and Ls is
derived from the left channel transmitted downmix signal's
envelope EnvDmxL, for R and Rs the right channel transmitted
downmix envelope is used EnvDmxR. The center channel is
derived from the sum of left and right transmitted downmix
signal's envelopes.
The gain curve is calculated for each output channel by
estimating its envelope EnvL,Ls-c,R,Rs and relate it to the
target envelope. In a second step this gain curve is
converted into an effective gain curve for solely scaling
the direct part of the upmixed channel:
ratioch(ri) = min (4, max (0.25, gch + ampRatioch («) • (gch -1)))
with

ratioch («) = min (4,max (0.25, gch + ampRatioch(«) ■ {gch -1)))
with
o- ^ - CTVJ?fl^(")'£"V(")
Envch{n)
Y\v"'k I
ampRatioch(n) = * nt =
/ .yc'h.airect I + £
k
ch&{L,Ls,C,R,Rs)
For 5-2-5 configuration the target envelope for L and Ls is
derived from the left channel transmitted downmix signal's
envelope EnvDmxL, for R and Rs the right channel transmitted
downmix envelope is used EnvDmxR. The center channel is
derived from the sum of left and right transmitted downmix
signal's envelopes.
The gain curve is calculated for each output channel by
estimating its envelope EnvL-Ls-c-R,Rs and relate it to the
target envelope. In a second step this gain curve is
converted into an effective gain curve for solely scaling
the direct part of the upmixed channel:
ratioch («) = min (4, max (0.25, gch + ampRatioch (n) ■ (gch -1)))
with

y\vn-k I
/ i Y ch, diffuse |
ampRatioch(w) = * nk : , che{L,Ls,C,R,Rs]
/ ,\ych.diKct\+£
k
n) = «n^OO^wOOf ch&{LM
Envch{n)
gch(n)=envRatio(n).EnvDmiR(n)^
Envch{n)
(ri) = envRatioch (")' °-5 (EnvD^L O) + £"Vw (")) c/je(c}
For all channels, the envelope adjustment gain curve is
applied if bsEnvShapeChannel=l.
ykdirec (") = ratio A (n) ■ ykchdirect («), che{L, Ls, C, R, Rs}
Else the direct signal is simply copied
?***, (") = &+*, («). che{Lt Ls, C, R, Rs)
Finally, the modified direct signal component of each
individual channel has to be combined with the diffuse
signal component of the corresponding individual channel
within the hybrid subband domain according to the
following equation:
yncH=yidiKc^y"cU^ che{L,Ls,C,R,Rs}
As can be seen from the above paragraphs, the inventive
concept teaches improving the perceptual quality and
spatial distribution of applause-like signals in a spatial
audio decoder. The enhancement is accomplished by deriving
gain factors with fine scale temporal granularity to scale
the direct part of the spatial upmix signal only. These
gain factors are derived essentially from transmitted side
information and level or energy measurements of the direct
and diffuse signal in the encoder.

As the above example particularly describes the
calculation based on amplitude measurements, it should be
noted that the inventive method is not restricted to this
but could also calculate with, for example energy-
measurements or other quantities suitable to describe a
temporal envelope of a signal.
The above example describes the calculation for 5-1-5 and
5-2-5 channel configurations. Naturally, the above
outlined principle could be applied analogously for e.g.
7-2-7 and 7-5-7 channel configurations.
Fig. 5 shows an example of an inventive multi-channel
audio decoder 100, receiving a downmix channel 102 derived
by downmixing a plurality of channels of one original
multi-channel signal and a parameter representation 104
including information on a temporal structure of the
original channels (left front, right front, left rear and
right rear) of the original multi-channel signal. The
multi-channel decoder 100 is having a generator 106 for
generating a direct signal component and a diffuse signal
component for each of the original channels underlying the
downmix channel 102. The multi-channel decoder 100 further
comprises four inventive direct signal modifiers 108a to
108d for each of the channels to be reconstructed, such
that the multi-channel decoder outputs four output
channels (left front, right front, left rear and right
rear) on its outputs 112.
Although the inventive multi-channel decoder has been
detailed using an example configuration of four original
channels to be reconstructed, the inventive concept may be
implemented in multi-channel audio schemes having
arbitrary numbers of channels.
Fig. 6 shows a block diagram, detailing the inventive
method of generating a reconstructed output channel.

In a generation step 110, a direct signal component and a
diffuse signal component is derived from the downmix
channel, in a modification step 112 the direct signal
component is modified using parameters of the parameter
representation having information on a temporal structure
of an original channel.
In a combination step 114, the modified direct signal
component and the diffuse signal component are combined to
obtain a reconstructed output channel.
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 disk, DVD or a CD having electronically
readable control signals stored thereon, which cooperate
with a programmable computer system such that the
inventive methods are performed. Generally, the present
invention is, therefore, a computer program product with a
program code stored on a machine readable carrier, the
program code being operative for performing the inventive
methods when the computer program product runs on a
computer. In other words, 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 on a computer.
While the foregoing has been particularly shown and
described with reference to particular embodiments
thereof, it will be understood by those skilled in the art
that various other changes in the form and details may be
made without departing from the spirit and scope thereof.
It is to be understood that various changes may be made in
adapting to different embodiments without departing from
the broader concepts disclosed herein and comprehended by
the claims that follow.

WE CLAIM
1. Multi-channel reconstructor (30; 60) for generating a reconstructed output
channel (50; 76) in an at least one downmix channel (38; 68) derived by
downmixing a plurality of original channels and application of a parameter
representation (40; 72), the parameter representation (40; 72) having
information on a temporal structure of an original channel, comprising:
a generator (32; 62) for generating a direct signal component (42; 64) and
a diffuse signal component (44; 66) for the reconstructed output channel
(50; 76), based on the downmix channel (38; 68);
a direct signal modifier (34; 69) for modifying the direct signal component
(42; 64) using the parameter representation (40; 72) without modifying the
diffuse signal component using the information on the temporal structure of
the original channel; and
a combiner (36; 74) for combining the modified direct signal component
(46) and the diffuse signal component (44; 66) to obtain the reconstructed
output channel (50; 76).
2. Multi-channel reconstructor as claimed in claim 1, wherein the generator
(32; 62) generates the direct signal component (42; 64) adapting only the
components of the downmix channel (38; 68).
3. Multi-channel reconstructor (30; 60) as claimed in claims 1 or 2, wherein
the generator (32; 62) generates the diffuse signal component (44; 66) in a
filtered and/or delayed portion of the downmix channel (38; 68).

4. Multi-channel reconstructor (30; 60) as claimed in any of claims 1 to 3,
wherein the direct signal modifier (34; 69) is adapting information on the
temporal structure of the original channel indicating the energy contained in
the original channel within a finite length time portion of the original
channel.
5. Multi-channel reconstructor (30; 60) as claimed in any of claims 1 to 3,
wherein the direct signal modifier (34; 69) applies information on the
temporal structure of the original channel indicating a mean amplitude of
the original channel within a finite length time portion of the original
channel.
6. Multi-channel reconstructor (30; 60) as claimed in any of claims 1 to 5,
wherein the combiner (36; 74) adds the modified direct signal component
(46) and the diffuse signal component (44; 66) to obtain the reconstructed
signal.
7. Multi-channel reconstructor as claimed in any of claims 1 to 6, wherein the
multi-channel reconstructor adapts a first downmix channel having
information on a left side of the plurality of original channels and a second
downmix channel (38; 68) having information on a right side of the plurality
of original channels, wherein a first reconstructed output channel (50; 76)
for a left side is combined only in the direct and diffuse signal components
generated from the first downmix channel and wherein a second
reconstructed output channel for a right side is combined using direct and
diffuse signal components generated only from the second downmix signal.

8. Multi-channel generator (30; 60) as claimed in any of claims 1 to 7, wherein
the direct signal modifier (34; 68) is enabled to modify the direct signal for
finite length time portions being shorter than frame time portions of
additional parametric information within the parameter representation (40;
72), and wherein the additional parametric information is processed by the
generator (32; 62) for generating the direct and the diffuse signal
components.
9. Multi-channel generator (30; 60) as claimed in claim 8, wherein the
generator (32; 62) is capable to apply additional parametric information
having information on the energy of the original channel with respect to
other channels of the plurality of original channels.
10. Multi-channel reconstructor (30; 60) as claimed in any of the preceding
claims, wherein the direct signal modifier (34; 68) adapts information on a
temporal structure of the original channel that is relating a temporal
structure of the original channel to a temporal structure of the downmix
channel (38; 68).
11. Multi-channel reconstructor (30; 60) as claimed in any of the preceding
claims, wherein the information on the temporal structure of the original
channel and the information on the temporal structure of the downmix
channel is having an energy or an amplitude measure.
12. Multi-channel reconstructor (30; 60) as claimed in any of the preceding
claims, wherein the direct signal modifier (34; 68) derives downmix
temporal information on the temporal structure of the downmix channel
(38; 68).

13. Multi-channel reconstructor (30; 60) as claimed in claim 12, wherein the
direct signal modifier (34; 68) derives downmix temporal information
indicating the energy contained in the downmix channel (38; 68) within a
finite length time interval or an amplitude measure for the finite length time
interval.
14. Multi-channel reconstructor (30; 60) as claimed in claims 12 or 13, wherein
the direct signal modifier (34; 68) derives a target temporal structure for
the reconstructed downmix channel (38; 68) with the application of
downmix temporal information and the information on the temporal
structure of the original channel.
15. Multi-channel reconstructor (30; 60) as claimed in any of claims 12 to 14,
wherein the direct signal modifier (34; 68) derives the downmix temporal
information for a spectral portion of the downmix channel (38; 68) above a
spectral lower bound.
16. Multi-channel reconstructor (30; 60) as claimed in any of claims 12 to 15,
wherein the direct signal modifier (34; 68) spectrally whitens the downmix
channel (38; 68) and derives the downmix temporal information using the
spectrally whitened downmix channel (38; 68).
17. Multi-channel reconstructor (30; 60) as claimed in any of claims 12 to 16,
wherein the direct signal modifier (34; 68) derives a smoothed
representation of the downmix channel (38; 68) and also derives the
downmix temporal information from the. smoothed representation of the
downmix channel.

18. Multi-channel reconstructor (30; 60) as claimed in claim 17, wherein the
direct signal modifier (34; 68) derives the smoothed representation by
filtering the downmix channel (38; 68) with a first order lowpass filter.
19. Multi-channel reconstructor (30; 60) as claimed in any of the previous
claims, wherein the direct signal modifier (34; 68) derives information on a
temporal structure of a combination of the direct signal component and the
diffuse signal component.
20. Multi-channel reconstructor (30; 60) as claimed in claim 19, wherein the
direct signal modifier (34; 68) spectrally whitens the combination of the
direct signal and the diffuse signal components and derives the information
on the temporal structure of the combination of the direct signal and the
diffuse signal components using the spectrally whitened direct and diffuse
signal components.
21. Multi-channel reconstructor (30; 60) as claimed in claims 19 or 20, wherein
the direct signal modifier (34; 68) derives a smoothed representation of the
combination of the direct and the diffuse signal components and also
derives the information on the temporal structure of the combination of the
direct and the diffuse signal components from the smoothed representation
of the combination of the direct and the diffuse signal components.
22. Multi-channel reconstructor (30; 60) as claimed in claim 21, wherein the
direct signal modifier (34; 68) derives the smoothed representation of the
combination of the direct and the diffuse signal

components by filtering the direct and the diffuse signal components with a
first order lowpass filter.
23. Multi-channel reconstructor (30; 60) as claimed in any of the previous
claims, wherein the direct signal modifier (34; 68) applies information on
the temporal structure of the original channel representing a ratio of the
energy or amplitude for a finite length time interval of the original channel
and the energy or amplitude for the original channel and the energy or
amplitude for the finite length time interval of the downmix channel (38;
68).
24. Multi-channel reconstructor (30; 60) as claimed in any of the previous
claims, wherein the direct signal modifier (34; 68) derives a target temporal
structure for the reconstructed output channel (50; 76) adapting the
downmix channel (38; 68) and the information on the temporal structure.
25. Multi-channel reconstructor (30; 60) as claimed in claim 23, wherein the
direct signal modifier (34; 68) is enabled to modify the direct signal
component such that a temporal structure of the reconstructed output
channel (50; 76) equals the target temporal structure within a tolerance
range.
26. Multi-channel reconstructor (30; 60) as claimed in claim 24, wherein the
direct signal modifier (34; 68) derives an intermediate scaling factor, the
intermediate scaling factor being such that the temporal structure of the
reconstructed output channel (50; 76) equals the target temporal structure
within the tolerance range, when the reconstructed

output channel (50; 76) equals the target temporal structure within the
tolerance range, when the reconstructed output channel (50; 76) is
combined using the direct signal components scaled with the intermediate
scaling factor and the diffuse signal component scaled with the intermediate
scaling factor.
27. Multi-channel reconstructor (30; 60) as claimed in claim 25, wherein the
direct signal modifier (34; 68) derives a final scaling factor using the
intermediate scaling factor and the direct and diffuse signal components
such that the temporal structure of the reconstructed output channel (50;
76) equals the target temporal structure within the tolerance range, when
the reconstructed output channel (50; 76) is combined using the diffuse
signal component and the direct signal component scaled using the final
scaling factor.
28. Method for generating a reconstructed output channel (50; 76) in at least
one downmix channel (38; 68) derived by downmixing a plurality of original
channels and adapting a parameter representation (40; 72), the parameter
representation (40; 72) having information on a temporal structure of an
original channel, the method comprising:
generating a direct signal component and a diffuse signal component for
the reconstructed output channel (50; 76), based on the downmix channel
(38; 68);
modifying the direct signal component with the application of the parameter
representation (40; 72) without modifying the diffuse signal component
using the information on the temporal structure of the original channel; and

combining the modified direct signal component (46) and the diffuse signal
component to obtain the reconstructed output channel (50; 76).
29. Multi-channel audio decoder for generating a reconstruction of a multi-
channel signal using at least one downmix channel (38; 68) derived by
downmixing a plurality of original channels and adapting a parameter
representation (40; 72), the parameter representation (40; 72) having
information on a temporal structure of an original channel, the multi-
channel audio decoder, comprising a multi-channel reconstructor as claimed
in claims 1 to 27.

ABSTRACT

TITLE: MULTI-CHANNEL RECONSTRUCTOR AND ENHANCED
METHOD FOR SIGNAL SHAPING IN MULTI-CHANNEL
AUDIO RECONSTRUCTION
A reconstructed output channel, reconstructed with a multi-channel reconstructor
using at least one downmix channel derived by downmixing a plurality of original
channels and using a parameter representation including additional information
on a temporal fine structure of an original channel can be generated using a
generator (32) for generating a direct signal component (42) and a diffuse signal
component (44) based on the downmix channel (38) is used. Only the direct
signal component (42) is modified (34) such that the temporal (40) fine structure
of the reconstructed output channel is fitting a desired temporal fine structure,
indicated by the additional information on the temporal fine structure
transmitted.

MULTI-CHANNEL RECONSTRUCTOR AND ENHANCED METHOD FOR SIGNAL SHAPING IN MULTI-CHANNEL AUDIO RECONSTRUCTION

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