The present invention relates to audio signal processing and, in particular, to audio signal post-processing in order to enhance the audio quality by removing coding artifacts.
Audio coding is the domain of signal compression that deals with exploiting redundancy and irrelevance in audio signals using psychoacoustic knowledge. At low bitrate conditions, often unwanted artifacts are introduced into the audio signal. A prominent artifact are temporal pre- and post-echoes that are triggered by transient signal components.
Especially in block-based audio processing, these pre- and post-echoes occur, since e.g. the quantization noise of spectral coefficients in a frequency domain transform coder is spread over the entire duration of one block. Semi-parametric coding tools like gap-filling, parametric spatial audio, or bandwidth extension can also lead to parameter band confined echo artefacts, since parameter-driven adjustments usually happen within a time block of samples.
The invention relates to a non-guided post-processor that reduces or mitigates subjective quality impairments of transients that have been introduced by perceptual transform coding.
State of the art approaches to prevent pre- and post-echo artifacts within a codec include transform codec block-switching and temporal noise shaping. A state of the art approach to suppress pre- and post-echo artifacts using post-processing techniques behind a codec chain is published in [1].
The first class of approaches need to be inserted within the codec chain and cannot be applied a-posteriori on items that have been coded previously (e.g., archived sound material). Even though the second approach is essentially implemented as a post-processor to the decoder, it still needs control information derived from the original input signal at the encoder side.
According to an embodiment, an apparatus for post-processing an audio signal may have: a time-spectrum-converter for converting the audio signal into a spectral representation having a sequence of spectral frames; a prediction analyzer for calculating prediction filter data for a prediction over frequency within a spectral frame; a shaping filter controlled by the prediction filter data for shaping the spectral frame to enhance a transient portion within the spectral frame; and a spectrum-time-converter for converting a sequence of spectral frames having a shaped spectral frame into a time domain.
According to another embodiment, a method for post-processing an audio signal may have the steps of: converting the audio signal into a spectral representation having a sequence of spectral frames; calculating prediction filter data for a prediction over frequency within a spectral frame; shaping, in response to the prediction filter data, the spectral frame to enhance a transient portion within the spectral frame; and converting a sequence of spectral frames having a shaped spectral frame into a time domain.
Still another embodiment may have a non-transitory digital storage medium having stored thereon a computer program for performing a method for post-processing an audio signal, having the steps of: converting the audio signal into a spectral representation having a sequence of spectral frames; calculating prediction filter data for a prediction over frequency within a spectral frame; shaping, in response to the prediction filter data, the spectral frame to enhance a transient portion within the spectral frame; and converting a sequence of spectral frames having a shaped spectral frame into a time domain, when said computer program is run by a computer.
An aspect of the present invention is based on the finding that transients can still be localized in audio signals that have been subjected to earlier encoding and decoding, since such earlier coding/decoding operations, although degrading the perceptual quality, do not completely eliminate transients. Therefore, a transient location estimator is provided for estimating a location in time of a transient portion using the audio signal or the time-frequency representation of the audio signal. In accordance with the present invention, a time-frequency representation of the audio signal is manipulated to reduce or eliminate the pre-echo in the time-frequency representation at the location in time before the transient location or to perform a shaping of the time-frequency representation at the transient location and, depending on the implementation, subsequent to the transient location so that an attack of the transient portion is amplified.
In accordance with the present invention, a signal manipulation is performed within a time-frequency representation of the audio signal based on the detected transient location. Thus, a quite accurate transient location detection and, on the one hand, a corresponding useful pre-echo reduction, and, on the other hand, an attack amplification can be obtained by processing operations in the frequency domain so that a final frequency-time conversion results in an automatic smoothing/distribution of manipulations over the entire frame and due to overlap add operations over more than one frame. In the end, this avoids audible clicks due to the manipulation of the audio signal and, of course, results in an improved audio signal without any pre-echo or with a reduced amount of pre-echo on the one hand and/or with sharpened attacks for the transient portions on the other hand.
Embodiments relate to a non-guided post-processor that reduces or mitigates subjective quality impairments of transients that have been introduced by perceptual transform coding.
In accordance with a further aspect of the present invention, transient improvement processing is performed without the specific need of a transient location estimator. In this aspect, a time-spectrum converter for converting the audio signal into a spectral representation comprising a sequence of spectral frames is used. A prediction analyzer then calculates prediction filter data for a prediction over frequency within a spectral frame and a subsequently connected shaping filter controlled by the prediction filter data shapes the spectral frame to enhance a transient portion within the spectral frame. The post-processing of the audio signal is completed with the spectrum-time conversion for converting a sequence of spectral frames comprising a shaped spectral frame back into a time domain.
Thus, once again, any modifications are done within a spectral representation rather than in a time domain representation so that any audible clicks, etc., due to a time domain processing are avoided. Furthermore, due to the fact that a prediction analyzer for calculating prediction filtered data for a prediction over frequency within a spectral frame is used, the corresponding time domain envelope of the audio signal is automatically influenced by subsequent shaping. Particularly, the shaping is done in such a way that, due to the processing within the spectral domain and due to the fact that the prediction over frequency is used, the time domain envelope of the audio signal is enhanced, i.e., made so that the time domain envelope has higher peaks and deeper valleys. In other words, the opposite of smoothing is performed by the shaping which automatically enhances transients without the need to actually locate the transients.
Advantageously, two kinds of prediction filter data are derived. The first prediction filter data are prediction filter data for a flattening filter characteristic and the second prediction filter data are prediction filter data for a shaping filter characteristic. In other words, the flattening filter characteristic is an inverse filter characteristic and the shaping filter characteristic is a prediction synthesis filter characteristic. However, once again, both these filter data are derived by performing a prediction over frequency within a spectral frame. Advantageously, time constants for the derivation of the different filter coefficients are different so that, for calculating the first prediction filter coefficients, a first time constant is used and for the calculation of the second prediction filter coefficients, a second time constant is used, where the second time constant is greater than the first time constant. This processing, once again, automatically makes sure that transient signal portions are much more influenced than non-transient signal portions. In other words, although the processing does not rely on an explicit transient detection method, the transient portions are much more influenced than the non-transient portion by means of the flattening and subsequent shaping that are based on different time constants.
Thus, in accordance with the present invention and due to the application of a prediction over frequency, an automatic kind of transient improvement procedure is obtained, in which the time domain envelope is enhanced (rather than smoothed).
Embodiments of the present invention are designed as post-processors on previously coded sound material operating without using further guidance information. Therefore, these embodiments can be applied on archived sound material that has been impaired through perceptual coding that has been applied to this archived sound material before it has been archived.
Embodiments of the first aspect consist of the following main processing steps:
Embodiments of the second aspect consist of the following main processing steps:
An embodiment is that of a post-processor that implements unguided transient enhancement as a last step in a multi-step processing chain. If other enhancement techniques are to be applied, e.g., unguided bandwidth extension, spectral gap filling etc., then the transient enhancement may be last in chain, such that the enhancement includes and is effective on signal modifications that have been introduced from previous enhancement stages.
All aspects of the invention can be implemented as post-processors, one, two or three modules can be computed in series or can share common modules (e.g., (I)STFT, transient detection, tonality detection) for computational efficiency.
It is to be noted that the two aspects described herein can be used independently from each other or together for post-processing an audio signal. The first aspect relying on transient location detection and pre-echo reduction and attack amplification can be used in order to enhance a signal without the second aspect. Correspondingly, the second aspect based on LPC analysis over frequency and the corresponding shaping filtering within the frequency domain does not necessarily rely on a transient detection but automatically enhances transients without an explicit transient location detector. This embodiment can be enhanced by a transient location detector but such a transient location detector is not necessarily required. Furthermore, the second aspect can be applied independently from the first aspect. Additionally, it is to be emphasized that, in other embodiments, the second aspect can be applied to an audio signal that has been post-processed by the first aspect. Alternatively, however, the order can be made in such a way that, in the first step, the second aspect is applied and, subsequently, the first aspect is applied in order to post-process an audio signal to improve its audio quality by removing earlier introduced coding artifacts.
Furthermore it is to be noted that the first aspect basically has two sub-aspects. The first sub-aspect is the pre-echo reduction that is based on the transient location detection and the second sub-aspect is the attack amplification based on the transient location detection. Advantageously, both sub-aspects are combined in series, wherein, even more advantageously, the pre-echo reduction is performed first and then the attack amplification is performed. In other embodiments, however, the two different sub-aspects can be implemented independent from each other and can even be combined with the second sub-aspect as the case may be. Thus, a pre-echo reduction can be combined with the prediction-based transient enhancement procedure without any attack amplification. In other implementations, a pre-echo reduction is not preformed but an attack amplification is performed together with a subsequent LPC-based transient shaping not necessarily requiring a transient location detection.
In a combined embodiment, the first aspect including both sub-aspects and the second aspect are performed in a specific order, where this order consists of first performing the pre-echo reduction, secondly performing the attack amplification and thirdly performing the LPC-based attack/transient enhancement procedure based on a prediction of a spectral frame over frequency.
Embodiments of the present invention are subsequently discussed with respect to the accompanying drawings in which:
The apparatus for post-processing 20 illustrated in
Thus, the apparatus for post-processing in
Furthermore, as illustrated in
An impaired audio signal is provided at an input 10 and this audio signal is input into a converter 100 that is, advantageously, implemented as short-time Fourier transform analyzer operating with a certain block length and operating with overlapping blocks.
Furthermore, the tonality estimator 200 as discussed in
The result of block 370 is the output of the enhanced audio signal 30.
Advantageously, the pre-echo ducking curve block 160 is controlled by a pre-echo estimator 150 collecting characteristics related to the pre-echo such as the pre-echo width as determined by block 240 of
Advantageously, as outlined in
Advantageously, the pre-echo threshold estimator 260 is controlled by the pre-echo width and also receives information on the time-frequency representation. The same is true for the spectral weighting matrix calculator 300 and, of course, for the spectral weighter 320 that, in the end, applies the weighting factor matrix to the time-frequency representation in order to generate a frequency-domain output signal, in which the pre-echo is reduced or eliminated. Advantageously, the spectral weighting matrix calculator 300 operates in a certain frequency range being equal to or greater than 700 Hz and advantageously being equal than or greater than 800 Hz. Furthermore, the spectral weighting matrix calculator 300 is limited to calculate weighting factors so that only for the pre-echo area that, additionally, depends on an overlap-add characteristic as applied by the converter 100 of
Advantageously, the pre-echo threshold estimator 260 is configured to determine the pre-echo threshold using a weighting curve having an increasing characteristic from a start of the pre-echo width to the transient location. Particularly, such a weighting curve is determined by block 350 in
In a further embodiment, the signal manipulator 140 is configured to use a spectral weights calculator 300, 160 for calculating individual spectral weights for spectral values of the time-frequency representation. Furthermore, a spectral weighter 320 is provided for weighting spectral values of the time-frequency representation using the spectral weights to obtain a manipulated time-frequency representation. Thus, the manipulation is performed within the frequency domain by using weights and by weighting individual time/frequency bins as generated by the converter 100 of
Advantageously, the spectral weights are calculated as illustrated in the specific embodiment illustrated in
Advantageously, the target value input into the raw weights calculator 450 is specifically calculated by a pre-masking modeler 420. The pre-masking modeler 420 may operate in accordance with equation 4.26 defined later, but other implementations can be used as well that rely on psychoacoustic effects and, particularly rely on a pre-masking characteristic that is typically occurring for a transient. The pre-masking modeler 420 is, on the one hand, controlled by a mask estimator 410 specifically calculating a mask relying on the pre-masking type acoustic effect. In an embodiment, the mask estimator 410 operates in accordance with equation 4.21 described later on but, alternatively, other mask estimations can be applied that rely on the psychoacoustic pre-masking effect.
Furthermore, a fader 430 is used for fade-in a reduction or elimination of the pre-echo using a fading curve over a plurality of frames at the beginning of the pre-echo width. This fading curve may be controlled by the actual value in a certain frame and by the determined pre-echo threshold thk. The fader 430 makes sure that the pre-echo reduction/elimination not only starts at once, but is smoothly faded in. An implementation is illustrated later on in connection with equation 4.20, but other fading operations are useful as well. Advantageously, the fader 430 is controlled by a fading curve estimator 440 controlled by the pre-echo width Mpre as determined, for example, by the pre-echo width estimator 240. Embodiments of the fading curve estimator operate in accordance with equation 4.19 discussed later on, but other implementations are useful as well. All these operations by blocks 410, 420, 430, 440 are useful to calculate a certain target value so that, in the end, together with the actual value, a certain weight can be determined by block 450 that is then applied to the time-frequency representation and, particularly, to the specific time/frequency bin subsequent to smoothing.
Naturally, a target value can also be determined without any pre-masking psychoacoustic effect and without any fading. Then, the target value would be directly the threshold thk, but it has been found that the specific calculations performed by blocks 410, 420, 430, 440 result in an improved pre-echo reduction in the output signal of the spectral weighter 320.
Thus, it is of advantage to determine the target spectral value so that the spectral value having an amplitude below a pre-echo threshold is not influenced by the signal manipulation or to determine the target spectral values using the pre-masking model 410, 420 so that a damping of a spectral value in the pre-echo area is reduced based on the pre-masking model 410.
Advantageously, the algorithm performed in the converter 100 is so that the time-frequency representation comprises complex-valued spectral values. On the other hand, however, the signal manipulator is configured to apply real-valued spectral weighting values to the complex-valued spectral values so that, subsequent to the manipulation in block 320, only the amplitudes have been changed, but the phases are the same as before the manipulation.
Advantageously, the signal manipulator 140 is configured to only amplify spectral values above a minimum frequency, where this minimum frequency is greater than 250 Hz and lower than 2 KHz. The amplification can be performed until the upper border frequency, since attacks at the beginning of the transient location typically extend over the whole high frequency range of the signal.
Advantageously, the signal manipulator 140 and, particularly, the attack amplifier 500 of
As stated, the signal manipulator 140 is configured to also amplify a time portion of the time-frequency representation subsequent to the transient location in time using a fade-out characteristic 685 as illustrated by block 680. Particularly, the spectral weights calculator 610 comprises a weighting factor determiner 680 receiving information on the transient part on the one hand, on the sustained part on the other hand, on the fade-out curve Gm 685 and advantageously also receiving information on the amplitude of the corresponding spectral value Xk,m. Advantageously, the weighting factor determiner 680 operates in accordance with equation 4.29 discussed later on, but other implementations relying on information on the transient part, on the sustained part and the fade-out characteristic 685 are useful as well.
Subsequent to the weighting factor determination 680, a smoothing across frequency is performed in block 690 and, then, at the output of block 690, the weighting factors for the individual frequency values are available and are ready to be used by the spectral weighter 620 in order to spectrally weight the time/frequency representation. Advantageously, of the amplified part as determined, for example by a maximum of the fade-out characteristics 685 is predetermined and between 300% and 150%. In an embodiment, as maximum amplification factor of 2.2 is used that decreases, over a number of frames, until a value of 1, where, as illustrated in
Advantageously, the result of the signal manipulation 140 is converted from the frequency domain into the time domain using a spectral-time converter 370 illustrated in
Advantageously, the converter 100 on the one hand and the other converter 370 on the other hand apply the same hop size between 1 and 3 ms or an analysis window having a window length between 2 and 6 ms. And, advantageously, the overlap range on the one hand, the hop size on the other hand or the windows applied by the time-frequency converter 100 and the frequency-time converter 370 are equal to each other.
Advantageously, the prediction analyzer 720 on the one hand or the shaping filter 740 on the other hand operate without an explicit transient location detection. Instead, due to the prediction over frequency applied by block 720 and due to the shaping to enhance the transient portion generated by block 740, a time envelope of the audio signal is manipulated so that a transient portion is enhanced automatically, without any specific transient detection. However, as the case may be, block 720, 740 can also be supported by an explicit transient location detection in order to make sure that any probably artifacts are not impressed into the audio signal at non-transient portions.
Advantageously, the prediction analyzer 720 is configured to calculate first prediction filter data 720a for a flattening filter characteristic 740a and second prediction filter data 720b for a shaping filter characteristic 740b as illustrated in
Advantageously, the degree of shaping represented by the second filter data 720b is greater than the degree of flattening 720a represented by the first filter data so that, subsequent to the application of the shaping filter having both characteristics 740a, 740b, a kind of an “over shaping” of the signal is obtained that results in a temporal envelope being less flatter than the original temporal envelope. This is exactly what is used for a transient enhancement.
Although
In this embodiment, an autocorrelation signal 800 is calculated from a spectral frame as illustrated at 800 in
Due to the fact that the autocorrelation signal is windowed with windows having two different time constants, the—automatic—transient enhancement is obtained. Typically, the windowing is such that the different time constants only have an impact on one class of signals but do not have an impact on the other class of signals. Transient signals are actually influenced by means of the two different time constants, while non-transient signals have such an autocorrelation signal that windowing with the second larger time constant results in almost the same output as windowing with the first time constant. With respect to
Depending on the implementation, the shaping filter can be implemented in many different ways. One way is illustrated in
However, the two different filter characteristics and the gain compensation can also be implemented within a single shaping filter 740 and the combined filter characteristic of the shaping filter 740 is calculated by a filter characteristic combiner 820 relying, on the one hand, on both first and second filter data and additionally relying, on the other hand, on the gains of the first filter data and the second filter data to finally also implement the gain compensation function 811 as well. Thus, with respect to
Thus, applying a window to the autocorrelation value prior to Levinson-Durbin recursion results in an expansion of the time support at local temporal peaks. In particular, the expansion using a Gaussian window is described by
Thus, a signal flow of a frequency domain-LPC based attack shaping is obtained as illustrated in
The detection function calculator 1000 relies on several steps illustrated in
In block 1130, the area around each peak is scanned for a larger peak in order to determine from this area the relevant peaks. The area around the peaks extends a number of Ib frames before the peak and a number of Ia frames subsequent to the peak.
In block 1140, close peaks are discarded so that, in the end, the transient onset frame indices mi are determined.
Subsequently, technical and auditory concepts, that are utilized in the proposed transient enhancement methods are disclosed. First, some basic digital signal processing techniques regarding selected filtering operations and linear prediction will be introduced, followed by a definition of transients. Subsequently, the psychoacoustic concept of auditory masking is explained, that is exploited in the perceptual coding of audio content. This portion closes with a brief description of a generic perceptual audio codec and the induced compression artifacts, that are subject to the enhancement methods in accordance with the invention.
The transient enhancement methods described later on make frequent use of some particular filtering operations. An introduction to these filters will be given in the section below. Refer to [9, 10] for a more detailed description. Eq. (2.1) describes a finite impulse response (FIR) low-pass filter that computes the current output sample value yn as the mean value of the current and past samples of an input signal xn. The filtering process of this so-called moving average filter is given by
where p is the filter order. The top image of
A different way to smooth a signal is to apply a single pole recursive averaging filter, that is given by the following difference equation:
y
n
=b·x
n+(1−b)·yn-1, 1≤n≤N,
with y0=x1 and N denoting the number of samples in xn.
where xn and yn are the input and output signals of Eq. (2.2), respectively, the resulting output signals ynmax and ynmin directly follow the attack or decay phase of the input signal.
Strong amplitude increments or decrements of an input signal xn can be detected by filtering xn with a FIR high-pass filter as
with b=[1, −1] or b=[1, 0, . . . , −1]. The resulting signal after high-pass filtering the rectangular function is shown in
Linear prediction (LP) is a useful method for the encoding of audio. Some past studies particularly describe its ability to model the speech production process [11, 12, 13], while others also apply it for the analysis of audio signals in general [14, 15, 16, 17]. The following section is based on [11, 12, 13, 15, 18].
In linear predictive coding (LPC) a sampled time signal s(nT)sn, with T being the sampling period, can be predicted by a weighted linear combination of its past values in the form of
where n is the time index that identifies a certain time sample of the signal, p is the prediction order, ar, with 1≤r≤p, are the linear prediction coefficients (and in this case the filter coefficients of an all-pole infinite impulse response (IIR) filter, G is the gain factor and un is some input signal that excites the model. By taking the z-transform of Eq. (2.6), the corresponding all-pole transfer function H(z) of the system is
where
z=e
j2πfT
=e
jωT.
The UR filter H(z) is called the synthesis or LPC filter, while the FIR filter A(z)=1−Σr=1Parz−11 is referred to as the inverse filter. Using the prediction coefficients ar as the filter coefficients of a FIR filter, a prediction of the signal sn can be obtained by
This results in a prediction error between the predicted signal ŝn and the actual signal sn which can be formulated by
with the equivalent representation of the prediction error in the z-domain being
E
p(z)=S(z)−Ŝ(z)=S(z)[1−P(z)]=S(z)A(z).
respectively.
With increasing prediction order p the energy of the residual decreases. Besides the number of predictor coefficients, the residual energy also depends on the coefficients themselves. Therefore, the problem in linear predictive coding is how to obtain the optimal filter coefficients ar, so that the energy of the residual is minimized. First, we take the total squared error (total energy) of the residual from a windowed signal block xn=sn·wn, where wn is some window function of width N, and its prediction {circumflex over (x)}n by
To minimize the total squared error E, the gradient of Eq. (2.14) has to be computed with respect to each ar and set to 0 by setting
This leads to the so-called normal equations:
Ri denotes the autocorrelation of the signal xn as
Eq. (2.17) forms a system of p linear equations, from which the p unknown prediction coefficients ar, 1≤r≤p, which minimize the total squared error, can be computed. With Eq. (2.14) and Eq. (2.17), the minimum total squared error Ep can be obtained by
A fast way to solve the normal equations in Eq. (2.17) is the Levinson-Durbin algorithm [19]. The algorithm works recursively, which brings the advantage that with increasing prediction order it yields the predictor coefficients for the current and all the previous orders less than p. First, the algorithm gets initialized by setting
E
0
=R
0.
Subsequently, for the prediction orders m=1, . . . , p, the prediction coefficients ar(m), which are the coefficients ar of the current order m, are computed with the partial correlation coefficients pm as follows:
With every iteration the minimum total squared error Em of the current order m is computed in Eq. (2.24). Since Em is positive and with Eo=Ro, it can be shown that with increasing order m the minimum total energy decreases, so that we have
0≤Em≤Em-1.
Therefore the recursion brings another advantage, in that the calculation of the predictor coefficients can be stopped, when Em falls below a certain threshold.
An important feature of LPC filters is their ability to model the characteristics of a signal in the frequency domain, if the filter coefficients were calculated on a time-signal. Equivalent to the prediction of the time sequence, linear prediction approximates the spectrum of the sequence. Depending on the prediction order, LPC filters can be used to compute a more or less detailed envelope of the signals frequency response. The following section is based on [11, 12, 13, 14, 16, 17, 20, 21].
From Eq. (2.13) we can see that the original signal spectrum can be perfectly re-constructed from the residual spectrum by filtering it with the all-pole filter H(z). By setting un=δn in Eq. (2.6), where δn is the Dirac delta function, the signal spectrum S(z) can be modeled by the all-pole filter {tilde over (S)}(z) from Eq. (2.7) as
With the prediction coefficients ar being computed using the Levinson-Durbin algorithm in Eq. (2.21)-(2.24), only the gain factor G remains to be determined. With un=δn Eq. (2.6) becomes
where hn is the impulse response of the synthesis filter H(z). According to Eq. (2.17) the autocorrelation {tilde over (R)}i of the impulse response hn is
By squaring hn in Eq. (2.27) and summing over all n, the 0th autocorrelation coefficient of the synthesis filter impulse response becomes
Since Ro=Σnsn2=E, the 0th autocorrelation coefficient corresponds to the total energy of the signal sn. With the condition that the total energies in the original signal spectrum S(z) and its approximation {tilde over (S)}(z) should be equal, it follows that {tilde over (R)}0=R0. With this conclusion, the relation between the autocorrelations of the signal sn and the impulse response hn in Eq. (2.17) and Eq. (2.28) respectively becomes {tilde over (R)}=Ri for 0≤i≤p. The gain factor G can be computed by reshaping Eq. (2.29) and with Eq. (2.19) as
Due to the duality between time and frequency it is also possible to apply linear prediction in the frequency domain on the spectrum of a signal, in order to model its temporal envelope. The computation of the temporal estimation is done the same way, only that the calculation of the predictor coefficients is performed on the signal spectrum, and the impulse response of the resulting all-pole filter is then transformed to the time domain.
In the literature many different definitions of transients can be found. Some refer to it as onsets or attacks [22, 23, 24, 25], while others use these terms to describe transients [26, 27]. This section aims to describe the different approaches to define transients and to characterize them for the purpose of this disclosure.
Some earlier definitions of transients describe them solely as a time domain phenome-non, for example as found in Kliewer and Mertins [24]. They describe transients as signal segments in the time-domain, whose energy rapidly rises from a low to a high value. To define the boundaries of these segments, they use the ratio of the energies within two sliding windows over the time-domain energy signal right before and after a signal sample n. Dividing the energy of the window right after n by the energy of the preceding window results in a simple criterion function C(n), whose peak values correspond to the beginning of the transient period. These peak values occur when the energy right after n is substantially larger than before, marking the beginning of a steep energy rise. The end of the transient is then defined as the time instant where C(n) falls below a certain threshold after the onset.
Masri and Bateman [28] describe transients as a radical change in the signals temporal envelope, where the signal segments before and after the beginning of the transient are highly uncorrelated. The frequency spectrum of a narrow time-frame containing a percussive transient event often shows a large energy burst over all frequencies, which can be seen in the spectrogram of a castanet transient in
Herre [20] and Zhang et al. [30] characterize transients with the degree of flatness of the temporal envelope. With the sudden increase of energy across time, a transient signal has a very non-flat time structure, with a corresponding flat spectral envelope. One way to determine the spectral flatness is to apply a Spectral Flatness Measure (SFM) [31] in the frequency domain. The spectral flatness SF of a signal can be calculated by taking the ratio of the geometric mean Gm and the arithmetic mean Am of the power spectrum:
|Xk| denotes the magnitude value of the spectral coefficient index k and K the total number of coefficients of the spectrum Xk. A signal has a non-flat frequency structure if SF→0 and therefore is more likely to be tonal. Opposed to that, if SF→1 the spectral envelope is more flat, which can correspond to a transient or a noise-like signal. A flat spectrum does not stringently specify a transient, whose phase response has a high correlation opposed to a noise signal. To determine the flatness of the temporal envelope, the measure in Eq. (2.31) can also be applied similarly in the time domain.
Suresh Babu et al. [27] furthermore distinguish between attack transients and frequency domain transients. They characterize frequency domain transients by an abrupt change in the spectral envelope between neighboring time-frames rather than by an energy change in the time domain, as described before. These signal events can be produced for example by bowed instruments like violins or by human speech, by changing the pitch of a presented sound.
A differentiation between the concepts of transients, onsets and attacks can be found in Bello et al. [26], which will be adopted in this thesis. The differentiation of these terms is also illustrated in
This section gives a basic introduction to psychoacoustic concepts that are used in perceptual audio coding as well as in the transient enhancement algorithm described later. The aim of psychoacoustics is to describe the relation between “measurable physical properties of sound signals and the internal percepts that these sounds evoke in a listener” [32]. The human auditory perception has its limits, which can be exploited by perceptual audio coders in the encoding process of audio content to substantially reduce the bitrate of the encoded audio signal. Although the goal of perceptual audio coding is to encode audio material in a way that the decoded audio signal should sound exactly or as close as possible to the original signal [1], it may still introduce some audible coding artifacts. The background to understand the origin of these artifacts and how the psychoacoustic model utilized by the perceptual audio coder will be provided in this section. The reader is referred to [33, 34] for a more detailed description on psychoacoustics.
Simultaneous masking refers to the psychoacoustic phenomenon that one sound (maskee) can be inaudible for a human listener when it is presented simultaneously with a stronger sound (masker), if both sounds are close in frequency. A widely used example to describe this phenomenon is that of a conversation between two people at the side of a road. With no interfering noise they can perceive each other perfectly, but they need to raise their speaking volume if a car or a truck passes by in order to keep understanding each other.
The concept of simultaneous masking can be explained by examining the functionality of the human auditory system. If a probe sound is presented to a listener it induces a travelling wave along the basilar membrane (BM) within the cochlea, spreading from its base at the oval window to the apex at its end [17]. Starting at the oval window, the vertical displacement of the travelling wave initially rises slowly, reaches its maxi-mum at a certain position and then declines abruptly afterwards [33, 34]. The position of its maximum displacement depends on the frequency of the stimulus. The BM is narrow and stiff at the base and about three times wider and less stiff at the apex. This way every position along the BM is most sensitive to a specific frequency, with high frequency signal components causing a maximum displacement near the base and low frequencies near the apex of the BM.
This specific frequency is often referred to as the characteristic frequency (CF) [33, 34, 35, 36]. This way the cochlea can be regarded as a frequency analyzer with a bank of highly overlapping bandpass filters with asym-metric frequency response, called auditory filters [17, 33, 34, 37]. The passbands of these auditory filters show a non-uniform bandwidth, which is referred to as the critical bandwidth. The concept of the critical bands was first introduced by Fletcher in 1933 [38, 39]. He assumed, that the audibility of a probe sound that is presented simultaneously with a noise signal is only dependent on the amount of noise energy that is close in frequency to the probe sound. If the signal-to-noise ratio (SNR) in this frequency area is under a certain threshold, i.e. the energy of the noise signal is to a certain degree higher than the energy of the probe sound, then the probe signal is inaudible by a human listener [17, 33, 34]. However, simultaneous masking does not only occur within one single critical band. In fact, a masker at the CF of a critical band can also affect the audibility of a maskee outside of the boundaries of this critical band, yet to a lesser extent [17]. The simultaneous masking effect is illustrated in
Masking is not only effective if the masker and maskee are presented at the same time, but also if they are temporally separated. A probe sound can be masked before and after the time period where the masker is present [40], which is referred to as pre-masking and post-masking. An illustration of the temporal masking effects is shown in
The purpose of perceptual audio coding is to compress an audio signal in a way that the resulting bitrate is as small as possible compared to the original audio, while maintaining a transparent sound quality, where the reconstructed (decoded) signal should not be distinguishable from the uncompressed signal [1, 17, 32, 37, 41, 42]. This is done by removing redundant and irrelevant information from the input signal exploiting some limitations of the human auditory system. While redundancy can be removed for example by exploiting the correlation between subsequent signal samples, spectral coefficients or even different audio channels and by an appropriate entropy coding, irrelevancy can be handled by the quantization of the spectral coefficients.
The basic structure of a monophonic perceptual audio encoder is depicted in
Despite the goal of perceptual audio coding to produce a transparent sound quality of the decoded audio signal, it still exhibits audible artifacts. Some of these artifacts that affect the perceived quality of transients will be described below.
There is only a limited amount of bits available for the bit allocation process to provide for the quantization of an audio signal block. If the bit demand for one frame is too high, some spectral coefficients could be deleted by quantizing them to zero [1, 43, 44]. This essentially causes the temporary loss of some high frequency content and is mainly a problem for low-bitrate coding or when dealing with very demanding signals, for example a signal with frequent transient events. The allocation of bits varies from one block to the next, hence the frequency content for a spectral coefficient might be deleted in one frame and be present in the following one. The induced spectral gaps are called “birdies” and can be seen in the bottom image of
Another common compression artifact is the so-called pre-echo [1, 17, 20, 43, 44]. Pre-echos occur if a sharp increase of signal energy (i.e. a transient) takes place near the end of a signal block. The substantial energy contained in transient signal parts is distributed over a wide range of frequencies, which causes the estimation of comparatively high masking thresholds in the psychoacoustic model and therefore the allocation of only a few bits for the quantization of the spectral coefficients. The high amount of added quantization noise is then spread over the entire duration of the signal block in the decoding process. For a stationary signal the quantization noise is assumed to be completely masked, but for a signal block containing a transient the quantization noise could precede the transient onset and become audible, if it “extends beyond the pre-masking [ . . . ] period” [1]. Even though there are several proposed methods dealing with pre-echos, these artifacts are still subject to current research.
There are several approaches to enhance the quality of transients that have been proposed over the past years. These enhancement methods can be categorized in those integrated in the audio codec and those working as a post-processing module on the decoded audio signal. An overview on previous studies and methods regarding the transient enhancement as well as the detection of transient events is given in the following.
An early approach for the detection of transients was proposed by Edler [6] in 1989. This detection is used to control the adaptive window switching method, which will be described later in this chapter. The proposed method only detects if a transient is present in one signal frame of the original input signal at the audio encoder, and not its exact position inside the frame. Two decision criteria are being computed to determine the likelihood of a present transient in a particular signal frame. For the first criterion the input signal x(n) is filtered with a FIR high-pass tilter according to Eq. (2.5) with the filter coefficients b=[1, −1]. The resulting difference signal d(n) shows large peaks at the instants of time where the amplitude between adjacent samples changes rapidly. The ratio of the magnitude sums of d(n) for two neighboring blocks is then used for the computation of the first criterion:
The variable m denotes the frame number and N the number of samples within one frame. However, c1(m) struggles with the detection of very small transients at the end of a signal frame, since their contribution to the total energy within the frame is rather small. Therefore a second criterion is formulated, which calculates the ratio of the maximum magnitude value of x(n) and the mean magnitude inside one frame:
If c1 (m) or c2 (m) exceed a certain threshold, then the particular frame m is determined to contain a transient event.
Kliewer and Mertins [24] also propose a detection method that operates exclusively in the time-domain. Their approach aims to determine the exact start and end samples of a transient, by employing two sliding rectangular windows on the signal energy. The signal energy within the windows is computed as
where L is the window length and n denotes the signal sample right in the middle between the left and right window. A detection function D(n) is then calculated by
Peak values of D(n) correspond to the onset of a transient, if they are higher than a certain threshold Tb. The end of a transient event is determined as “the largest value of D(n) being smaller than some threshold Te directly after the onset” [24].
Other detection methods are based on linear prediction in the time-domain to distinguish between transient and steady-state signal parts, using the predictability of the signal waveform [45]. One method that uses linear prediction was proposed by Lee and Kuo [46] in 2006. They decompose the input signal into several sub-bands to compute a detection function for each of the resulting narrow-band signals. The detection functions are obtained as the output after filtering the narrow-band signal with the inverse filter according to Eq. (2.10). A subsequent peak selection algorithm determines the local maximum values of the resulting prediction error signals as the onset time candidates for each sub-band signal, which are then used to determine a single transient onset time for the wide-band signal.
The approach of Niemeyer and Edler [23] works on a complex time-frequency representation of the input signal and determines the transient onsets as a steep increase of the signal energy in neighboring bands. Each bandpass signal is filtered according to Eq. (2.3) to compute a temporal envelope that follows sudden energy increases as the detection function. A transient criterion is then computed not only for frequency band k, but also considering K=7 neighboring frequency bands on either side of k.
Subsequently, different strategies for the enhancement of transient signal parts will be described. The block diagram in
By applying the STFT, the input signal sn is first divided into multiple frames of length N, that are overlapping by L samples and are windowed with an analysis window function wn,m to get the signal blocks xn,m=sn−Wn,m. Each frame xn,m is then transformed to the frequency domain using the Discrete Fourier Transform (DFT). This yields the spectrum Xk,m of the windowed signal frame xn,m, where k is the spectral coefficient index and m is the frame number. The analysis by STFT can be formulated by the following equation:
with
i=(m−1)·(N−L), m∈+ and 0≤k<K, k∈.
(N−L) is also referred to as the hop size. For the analysis window Wn,m a sine window of the form
has been used. In order to capture the fine temporal structure of the transient events, the frame size has been chosen to be comparatively small. For the purpose of this work it was set to N=128 samples for each time-frame, with an overlap of L=N/2=64 samples for two neighboring frames. K in Eq. (4.2) defines the number of DFT points and was set to K=256. This corresponds to the number of spectral coefficients of the two-sided spectrum of Xk,m. Before the STFT analysis, each windowed input signal frame is zero-padded to obtain a longer vector of length K, in order to match the number of DFT points. These parameters give a sufficiently fine time-resolution to isolate the transient signal parts in one frame from the rest of the signal, while providing enough spectral coefficients for the following frequency-selective enhancement operations.
In Embodiments, the methods for the enhancement of transients are applied exclusively to the transient events themselves, rather than constantly modifying the signal. Therefore, the instants of the transients have to be detected. For the purpose of this work, a transient detection method has been implemented, which has been adjusted to each individual audio signal separately. This means that the particular parameters and thresholds of the transient detection method, which will be described later in this section, are specifically tuned for each particular sound file to yield an optimal detection of the transient signal parts. The result of this detection is a binary value for each frame, indicating the presence of a transient onset.
The implemented transient detection method can be divided into two separate stages: the computation of a suitable detection function and an onset picking method that uses the detection function as its input signal. For the incorporation of the transient detection into a real-time processing algorithm an appropriate look-ahead is needed, since the subsequent pre-echo reduction method operates in the time interval preceding the detected transient onset.
For the computation of the detection function, the input signal is transformed to a representation that enables an improved onset detection over the original signal. The input of the transient detection block in
First, the energy of several neighboring spectral coefficients of Xk,m are summed up for each time-frame m, by taking
where K denotes the index of the resulting sub-band signals. Therefore, XK,m consists of 7 values for each frame m, representing the energy contained in a certain frequency band of the spectrum Xk,m. The border frequencies flow and fhigh, as well as passband bandwidth Δf and the number n of connected spectral coefficients, are displayed in Table 4.1. The values of the bandpass signals in XK,m are then smoothed over all time-frames. This is done by filtering each sub-band signal XK,m with an IIR low-pass filter in time direction according to Eq. (2.2) as
{tilde over (X)}
K,m
=a·{tilde over (X)}
K,m-1
+b·X
K,m
, m∈
+.
{tilde over (X)}K,m is the resulting smoothed energy signal for each frequency channel K. The filter coefficients b and a=I−b are adapted for each processed audio signal separately, to yield satisfactory time constants. The slope of {tilde over (X)}K,m is then computed via high-pass (HP) filtering each bandpass signal in XK,m by using Eq. (2.5) as
where SK,m is the differentiated envelope, bi are the tilter coefficients of the deployed FIR high-pass filter and p is the filter order. The specific filter coefficients bi were also separately defined for each individual signal. Subsequently, SK,m is summed up in frequency direction across all K, to get the overall envelope slope Fm. Large peaks in Fm correspond to the time-frames in which a transient event occurs. To neglect smaller peaks, especially following the larger ones, the amplitude of Fm is reduced by a threshold of 0.1 in a way that Fm=max(Fm−0.1, 0). Post-masking after larger peaks is also considered by filtering Fm with a single pole recursive averaging filter equivalent to Eq. (2.2) by
{tilde over (F)}
m
=a·{tilde over (F)}
m-1
+b·F
m, where {tilde over (F)}0=0
and taking the larger values of {tilde over (F)}m and Fm for each frame m according to Eq. (2.3) to yield the resulting detection function Dm.
Essentially, the onset picking method determines the instances of the local maxima in the detection function Dm as the onset time-frames of the transient events in S. For the detection function of the castanets signal in
First of all, the amplitude of the peak values in Dm needs to be above a certain threshold thpeak, to be considered as onset candidates. This is done to prevent smaller amplitude changes in the envelope of the input signal sn, that are not handled by the smoothing and post-masking filters in Eq. (4.5) and Eq. (4.7), to be detected as transient onsets. For every value Dm=i of the detection function Dm, the onset picking algorithm scans the area preceding and following the current frame I for a larger value than Dm=i. If no larger value exists Ib frames before and Ia frames after the current frame, then I is determined as a transient frame. The number of “look-back” and “look-ahead” frames Ib and Ia, as well as the threshold thpeak, were defined for each audio signal individually. After the relevant peak values have been identified, detected transient onset frames, that are closer than 50 ms to a preceding onset, will be discarded [50, 51]. The output of the onset picking method (and the transient detection in general) are the indexes of the transient onset frames mi, that are used for the following transient enhancement blocks.
The purpose of this enhancement stage is to reduce the coding artifact known as pre-echo that may be audible in a certain time period before the onset of a transient. An overview of the pre-echo reduction algorithm is displayed in
Before estimating the actual width of the pre-echo, tonal frequency components pre-ceding the transient are being detected (200). After that, the pre-echo width is determined (240) in an area of Mlong frames before the transient frame. With this estimation a threshold for the signal envelope in the pre-echo area can be calculated (260), to reduce the energy in those spectral coefficients whose magnitude values exceed this threshold. For the eventual pre-echo reduction, a spectral weighting matrix is computed (450), containing multiplication factors for each k and m, which is then multiplied elementwise with the pre-echo area of Xk,m.
The subsequent detected spectral coefficients, corresponding to tonal frequency components before the transient onset, are utilized in the following pre-echo width estimation, as described in the next subsection. It could also be beneficial to use them in the following pre-echo reduction algorithm, to skip the energy reduction for those tonal spectral coefficients, since the pre-echo artifacts are likely to be masked by present tonal components. However, in some cases the skipping of the tonal coefficients resulted in the introduction of an additional artifact in the form an audible energy increase at some fre-quencies in the proximity of the detected tonal frequencies, so this approach has been omitted for the pre-echo reduction method in this embodiment.
First, a linear prediction analysis is performed on each complex-valued STFT coefficient k across time, where the prediction coefficients ak,r are computed with the Levinson-Durbin algorithm according to Eq. (2.21)-(2.24). With these prediction coefficients a prediction gain Rp,k [52, 53, 54J can be calculated for each k as
where σxk2 and σEkk are the variances of the input signal Xk,m and its prediction error Ek,m respectively for each k. Ek,m is computed according to Eq. (2.10). The prediction gain is an indication on how accurate Xk,m can be predicted with the prediction coefficients ak,r with a high prediction gain corresponding to a good predictability of the signal. Transient and noise-like signals tend to cause a lower prediction gain for a time-domain linear prediction, so if Rp,k is high enough for a certain k, then this spectral coefficient is likely to contain tonal signal components. For this method, the threshold for a prediction gain corresponding to a tonal frequency component was set to 10 dB.
In addition to a high prediction gain, tonal frequency components should also contain a comparatively high energy over the rest of the signal spectrum. The energy εi,k in the potential pre-echo area of the current i-th transient is therefore compared to a certain energy threshold. εi,k is calculated by
The energy threshold is computed with a running mean energy of the past pre-echo areas, that is updated for every next transient. The running mean energy shall be denoted as
i
=b·
i-1+(1−b)·εi-1, with b=0.7.
Hence a spectral coefficient index k in the current pre-echo area is defined to contain tonal components, if
R
p,k>10 dB and εi,k>0.8·
The result of the tonal signal component detection method (200) is a vector ktonal,i for each pre-echo area preceding a detected transient, that specifies the spectral coefficient indexes k which fulfill the conditions in Eq. (4.11).
Since there is no information about the exact framing of the decoder (and therefore about the actual pre-echo width) available for the decoded signal sn, the actual pre-echo start frame has to be estimated (240) for every transient before the pre-echo reduction process. This estimation is crucial for the resulting sound quality of the processed signal after the pre-echo reduction. If the estimated pre-echo area is too small, part of the present pre-echo will remain in the output signal. If it is too large, too much of the signal amplitude before the transient will be damped, potentially resulting in audible signal drop-outs. As described before, Mlong represents the size of a long analysis window used in the audio encoder and is regarded as the maximum possible number of frames of the pre-echo spread before the transient event. The maximum range Mlong of this pre-echo spread will be denoted as the pre-echo search area.
The detection algorithm only uses the HF content of Xk,m above 3 kHz, since most of the energy of the input signal is concentrated in the LF area. For the specific STFT parameters used here, this corresponds to the spectral coefficients with k≥18. This way, the detection of the pre-echo onset gets more robust because of the supposed absence of other signal components that could complicate the detection process. Furthermore, the tonal spectral coefficients ktonal, that have been detected with the previously described tonal component detection method, will also be excluded from the estimation process, if they correspond to frequencies above 3 kHz. The remaining coefficients are then used to compute a suitable detection function that simplifies the pre-echo estimation. First, the signal energy is summed up in frequency direction for all frames in the pre-echo search area, to get magnitude signal Lm as
kmax corresponds to the cut-off frequency of the low-pass filter, that has been used in the encoding process to limit the bandwidth of the original audio signal. After that, Lm is smoothed to reduce the fluctuations on the signal level. The smoothing is done by filtering Lm with a 3-tap running average filter in both forward and backward directions across time, to yield the smoothed magnitude signal {tilde over (L)}m. This way, the filter delay is compensated and the filter becomes zero-phase. {tilde over (L)}m is then derived to compute its slope Lm′ by
L
m
′={tilde over (L)}
m
−{tilde over (L)}
m-1
Lm′ is then filtered with the same running average filter used for Lm before. This yields the smoothed slope {tilde over (L)}m, which is used as the resulting detection function Dm=Dm{tilde over (L)}m to determine the starting frame of the pre-echo.
The basic idea of the pre-echo estimation is to find the last frame with a negative value of Dm, which marks the time instant after which the signal energy increases until the onset of the transient.
The estimation of the pre-echo start frame mpre is done by employing an iterative search algorithm. The process for the pre-echo start frame estimation will be described with the example detection function shown in
With A+ and A−, the candidate pre-echo start frame at line 2 will be defined as the resulting start frame Mpre, if
A
−
>a·A
+.
The factor a is initially set to a=0.5 for the first iteration of the estimation algorithm and is then adjusted to a=0.92·a for every subsequent iteration. This gives a greater emphasis to the negative slope area A−, which is used for some signals that exhibit stronger amplitude variations in the magnitude signal Lm throughout the whole search area. If the stop-criterion in Eq. (4.15) does not hold (which is the case for the first iteration in the top image of
The following execution of the adaptive pre-echo reduction can be divided into three phases, as can be seen in the bottom layer of the block diagram in
Y
k,m
=X
k,m
·W
k,m.
The goal of the pre-echo reduction method is to weight the values of Xk,m in the previously estimated pre-echo area, so that the resulting magnitude values of Yk,m lie under a certain threshold thk. The spectral weight matrix Wk,m is created by determining this threshold thk for each spectral coefficient in Xk,m over the pre-echo area and computing the weighting factors used for the pre-echo attenuation for each frame m. The computation of Wk,m is limited to the spectral coefficients between kmin≤k≤kmax, where kmin is the spectral coefficient index corresponding to the closest frequency to fmm=800 Hz, so that Wk,m=1 for k<kmin and k>kmax. fmin was chosen to avoid an amplitude reduction in the low-frequency area, since most of the fundamental frequencies of musical instruments and speech lie beneath 800 Hz. An amplitude damping in this frequency area is prone to produce audible signal drop-outs before the transients, especially for complex musical audio signals. Furthermore, Wk,m is restricted to the estimated pre-echo area with mpre≤m≤mi−2, where mi is the detected transient onset. Due to the 50% overlap between adjacent time-frames in the STFT analysis of the input signal sn, the frame directly preceding the transient onset frame mi is also likely to contain the transient event. Therefore, the pre-echo damping is limited to the frames m≤mi−2.
As stated before, a threshold thk needs to be determined (260) for each spectral coefficient Xk,m, with kmin≤k≤kmax, that is used to determine the spectral weights needed for the pre-echo attenuation in the individual pre-echo areas preceding each detected transient onset. thk corresponds to the magnitude value to which the signal magnitude values of Xk,m should be reduced, to get the output signal Yk,m. An intuitive way could be to simply take the value of the first frame mpre of the estimated pre-echo area, since it should correspond to the time instant where signal amplitude starts to rise constantly as a result of the induced pre-echo quantization noise. However, |Xk,m
where Mpre is the number of frames in the pre-echo area. The weighted envelope after multiplying |{tilde over (X)}k,m| with Cm is shown as the dashed gray curve in both diagrams of
The resulting threshold thk is used to compute the spectral weights Wk,m used to decrease the magnitude values of Xk,m′. Therefore a target magnitude signal |{tilde over (X)}k,m| will be computed (450) for every spectral coefficient index k, that represents the optimal output signal with reduced pre-echo for every individual k. With |{tilde over (X)}k,m|, the spectral weight matrix Wk,m can be computed as
Wk,m is subsequently smoothed (460) across frequency by applying a 2-tap running average filter in both forward and backward direction for each frame m, to reduce large differences between the weighting factors of neighboring spectral coefficients k prior to the multiplication with the input signal Xk,m. The damping of the pre-echoes is not done immediately at the pre-echo start frame mpre to its full extent, but rather faded in over the time period of the pre-echo area. This is done by employing (430) a parametric fading curve fm with adjustable steepness, that is generated (440) as
where the exponent 10c determines the steepness of fm.
This effectively reduces the values of |Xk,m| that are higher than the threshold thk, while leaving values below thk untouched.
A transient event acts as a masking sound that can temporally mask preceding and following weaker sounds. A pre-masking model is also applied (420) here, in a way that the values of |Xk,m| should only be reduced until they fall under the pre-masking threshold, where they are assumed to be inaudible. The used pre-masking model first computes a “prototype” pre-masking threshold maskm,iproto, that is then adjusted to the signal level of the particular masker transient in Xk,m. The parameters for the computation of the pre-masking thresholds were chosen according to B. Edler (personal communication, Nov. 22, 2016) [55]. maskm,iproto is generated as an exponential function as
maskm,iproto=L·exp(m·a), m≤0.
The parameters L and α determine the level, as well as the slope, of maskm,iproto. The level parameter L was set to
L=L
fall+0=50 dB+10 dB=60 dB.
tfall=3 ms before the masking sound, the pre-masking threshold should be decreased by Lfall=50 dB. First, tfall needs to be converted into a corresponding number of frames mfall, by taking
where (N−L) is the hop size of the STFT analysis and fs is the sampling frequency. With L, Lfall and mfall Eq. (4.21) becomes
so the parameter a can be determined by transforming Eq. (4.24) as
The resulting preliminary pre-masking threshold maskm,iproto is shown in
For the computation of the particular signal-dependent pre-masking threshold maskk,m,i in every pre-echo area of Xk,m, the detected transient frame mi as well as the following Mmask frames will be regarded as the time instances of potential maskers.
Hence, maskm,iproto is shifted to every mim≤mi+Mmask and adjusted to the signal level of Xk,m with a signal-to-mask ratio of −6 dB (i.e. the distance between the masker level and maskm,iproto at the masker frame) for every spectral coefficient. After that, the maximum values of the overlapping thresholds are taken as the resulting pre-masking thresholds maskk,m,i for the respective pre-echo area. Finally, maskk,m,i is smoothed across frequency in both directions, by applying a single pole recursive averaging filter equivalent to the filtering operation in Eq. (2.2), with a filter coefficient b=0.3.
The pre-masking threshold maskk,m,i is then used to adjust the values of the target magnitude signal |X̆k,m| (as computed in Eq. (4.20)), by taking
The resulting spectral weights Wk,m are then computed (450) with Xk,m and |X̆k,m| according to Eq. (4.18) and smoothed across frequency, before they are applied to the input signal Xk,m. Finally, the output signal Ykm of the adaptive pre-echo reduction method is obtained by applying (320) the spectral weights Wk,m to Xk,m via element-wise multiplication according to Eq. (4.16). Note that Wk,m is real-valued and therefore does not alter the phase response of the complex-valued Xk,m.
The methods discussed in this section aim to enhance the degraded transient attack as well as to emphasize the amplitude of the transient events.
Besides the transient frame mi, the signal in the time period after the transient gets amplified as well, with the amplification gain being faded out over this interval. The adaptive transient attack enhancement method takes the output signal of the pre-echo reduction stage as its input signal Xk,m. Similar to the pre-echo reduction method, a spectral weighting matrix Wk,m is computed (610) and applied (620) to Xk,m as
Y
k,m
=X
k,m
·W
k,m.
However, in this case Wk,m is used to raise the amplitude of the transient frame mi and to a lesser extent also the frames after that, instead of modifying the time period preceding the transient. The amplification is thereby restricted to frequencies above fmin=400 Hz and below the cut-off frequency fmax of the low-pass filter applied in the audio encoder. First, the input signal Xk,m is divided into a sustained part Xk,msust and a transient part Xk,mtrans. The subsequent signal amplification is only applied to the transient signal part, while the sustained part is fully retained. Xk,msust is computed by filtering the magnitude signal |Xk,m| (650) with a single pole recursive averaging filter according to Eq. (2.4), with the used filter coefficient being set to b=0.41. The top image of
X
k,m
trans
=|X
k,m
|−X
k,m
sust.
The transient part Xk,mtrans of the corresponding input signal magnitude |Xk,m| the top image is displayed in the bottom image of
Wk,m is then smoothed (690) across frequency in both forward and backward direction according to Eq. (2.2), before enhancing the transient attack according to Eq. (4.27). In the bottom image of
Opposed to the adaptive transient attack enhancement method described before, this method aims to sharpen the attack of a transient event, without increasing its amplitude. Instead, “sharpening” the transient is done by applying (720) linear prediction in the frequency domain and using two different sets of prediction coefficients ar for the inverse (720a) and the synthesis filter (720b) to shape (740) the temporal envelope of the time signal sn. By filtering the input signal spectrum with the inverse filter (740a), the prediction residual Ek,m can be obtained according to Eq. (2.9) and (2.10) as
The inverse filter (740a) decorrelates the filtered input signal Xk,m both in the frequency and the time domain, effectively flattening the temporal envelope of the input signal sn. Filtering Ek,m with the synthesis filter (740b) according to Eq. (2.12) (using the prediction coefficients arsYnth) perfectly reconstructs the input signal Xk,m if arsynth=arflat. The goal for the attack enhancement is to compute the prediction coefficients arflat and arsYnth in a way that the combination of the inverse filter and the synthesis filter exaggerates the transient while attenuating the signal parts before and after it in the particular transient frame.
The LPC shaping method works with different framing parameters as the preceding enhancement methods. Therefore the output signal of the preceding adaptive attack enhancement stage needs to be resynthesized with the ISTFT and the analyzed again with the new parameters. For this method a frame size of N=512 samples is used, with a 50% overlap of L=N/2=256 samples. The DFT size was set to 512. The larger frame size was chosen to improve the computation of the prediction coefficients in the frequency domain, wherefore a high frequency resolution is more important than a high temporal resolution. The prediction coefficients arflat and arsYnth are computed on the complex spectrum of the input signal Xk,m
W
i
=c
i, 0≤i≤kmax−kmin,
with cflat=0.4 and csynth=0.94. The top image
This describes the filtering operation with resulting shaping filter, which can be interpreted as the combined application (820) of the inverse filter (809) and the synthesis filter (810). Transforming Eq. (4.32) with the FFT yields the time-domain filter transfer function (TF) of the system as
with the FIR (inverse/flattening) filter (1−Pn) and the IIR (synthesis) filter An. Eq. (4.32) can equivalently be formulated in the time-domain as the multiplication of the input signal frame sn with the shaping filter Hnshape as
y
n
=s
n
·H
n
shape.
The prediction gain Rp is calculated from the partial correlation coefficients ρm, with 1≤m≤p, which are related to the prediction coefficients ar, and are calculated along with ar in Eq. (2.21) of the Levinson-Durbin algorithm. With ρm, the prediction gain (811) is then obtained by
The final TF Hnshape the adjusted amplitude is displayed in
Furthermore examples of embodiments particularly relating to the first aspect are set out subsequently:
17. Method of post-processing (20) an audio signal, comprising:
18. Computer program for performing, when running on a computer or a processor, the method of example 17.
Although some aspects have been described in the context of an apparatus, it is clear that these aspects also represent a description of the corresponding method, where a block or device corresponds to a method step or a feature of a method step. Analogously, aspects described in the context of a method step also represent a description of a corresponding block or item or feature of a corresponding apparatus.
Depending on certain implementation requirements, embodiments of the invention can be implemented in hardware or in software. The implementation can be performed using a digital storage medium, for example a floppy disk, a DVD, a CD, a ROM, a PROM, an EPROM, an EEPROM or a FLASH memory, having electronically readable control signals stored thereon, which cooperate (or are capable of cooperating) with a programmable computer system such that the respective method is performed.
Some embodiments according to the invention comprise a data carrier having electronically readable control signals, which are capable of cooperating with a programmable computer system, such that one of the methods described herein is performed.
Generally, embodiments of the present invention can be implemented as a computer program product with a program code, the program code being operative for performing one of the methods when the computer program product runs on a computer. The program code may for example be stored on a machine readable carrier.
Other embodiments comprise the computer program for performing one of the methods described herein, stored on a machine readable carrier or a non-transitory storage medium.
In other words, an embodiment of the inventive method is, therefore, a computer program having a program code for performing one of the methods described herein, when the computer program runs on a computer.
A further embodiment of the inventive methods is, therefore, a data carrier (or a digital storage medium, or a computer-readable medium) comprising, recorded thereon, the computer program for performing one of the methods described herein.
A further embodiment of the inventive method is, therefore, a data stream or a sequence of signals representing the computer program for performing one of the methods described herein. The data stream or the sequence of signals may for example be configured to be transferred via a data communication connection, for example via the Internet.
A further embodiment comprises a processing means, for example a computer, or a programmable logic device, configured to or adapted to perform one of the methods described herein.
A further embodiment comprises a computer having installed thereon the computer program for performing one of the methods described herein.
In some embodiments, a programmable logic device (for example a field programmable gate array) may be used to perform some or all of the functionalities of the methods described herein. In some embodiments, a field programmable gate array may cooperate with a microprocessor in order to perform one of the methods described herein. Generally, the methods may be performed by any hardware apparatus.
While this invention has been described in terms of several embodiments, there are alterations, permutations, and equivalents which will be apparent to others skilled in the art and which fall within the scope of this invention. It should also be noted that there are many alternative ways of implementing the methods and compositions of the present invention. It is therefore intended that the following appended claims be interpreted as including all such alterations, permutations, and equivalents as fall within the true spirit and scope of the present invention.
Number | Date | Country | Kind |
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17164332.3 | Mar 2017 | EP | regional |
17183135.7 | Jul 2017 | EP | regional |
This application is a continuation of copending International Application No. PCT/EP2018/025084, filed Mar. 29, 2018, which is incorporated herein by reference in its entirety, and additionally claims priority from European Application No. 17164332.3, filed Mar. 31, 2017, and from European Application No. 17183135.7, filed Jul. 25, 2017, which are both incorporated herein by reference in their entirety.
Number | Date | Country | |
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Parent | PCT/EP2018/025084 | Mar 2018 | US |
Child | 16573519 | US |