FR3031638A1 - DECOMPRESSION METHOD AND CORRESPONDING DEVICE - Google Patents

Abstract

The present invention relates to a method of decompressing the dynamics of an input audio signal. The method comprises: a) a step (22) for determining a magnitude representative of the amplitude of the initial audio signal, b) a step (24) for comparing said magnitude representative of the amplitude of the initial audio signal (x ) with respect to a threshold, c) a step (26) of amplifying the input audio signal when the magnitude representative of the amplitude of the original audio signal is greater than said threshold, to obtain the output audio signal, d) a step (28) for determining a magnitude representative of the dynamics of the output signal, e) a step (30) of comparing said magnitude representative of the dynamics of the output signal with a set value, and f) a step (32) of modifying step a) and / or step b) as a function of the difference between the value of said quantity representative of the dynamics of the output signal and the setpoint value.

Description

BACKGROUND OF THE INVENTION The present invention relates to methods and devices for processing sound signals. In particular, the present invention relates to methods and devices for modifying the sound dynamics of an audio signal, and more particularly relates to methods and devices for decompressing a compressed audio signal. The sound dynamics of an audio signal makes it possible to characterize the range of variation of the sound level of the audio signal. The sound dynamics can thus be defined as the difference between the loudest and the weakest sound, measured in decibels (dB), possibly in relation to the noise level. A more usual way to quantify the sound dynamics of a signal is to use the peak factor, or the peak-to-average power ratio ("PAPR"). The value considered can be the loudness of the audio signal (sound level felt by the user), or the rms value of the acoustic pressure, the rms value of the electrical signal corresponding to the audio signal, or any characteristic quantity of the sound level of the sound. audio signal.

It is known to use an audio compressor (or in English: DRC for "dynamic range compression") to limit the sound dynamics of an audio signal. More particularly, audio compression is a sound processing technique that attenuates loud sounds and amplifies weak sounds, which leads to a reduction in sound dynamics. An audio compressor (hereinafter referred to as "compressor") is thus a non-linear amplifier having a gain of less than 1 for sound levels above a certain threshold (called the compression threshold). Generally, the gain of the compressor is equal to 1 for the sound levels below the determined threshold. Furthermore, the compressor 3031638 2 may be characterized by several other parameters, such as, for example, the attack and return time, the rounding of the transfer function of the compressor at the determined threshold, etc. These parameters make it possible to attenuate the impact of the effect of the compressor on the audio rendering of the compressed audio signal. An example of a compressor is the "brick wall" limiter, which makes it possible to cap the sound levels of the audio signal to a limit value. This produces a "clipped" audio signal between a minimum value and a maximum value determined by the threshold of the "brick wall" limiter. We also speak of audio signal "cut" when it was compressed by a limiter type "brick wall". Audio compressors can be used, for example, to protect the loudspeakers from too high peaks of the audio signal: such peaks are thus attenuated by the compressor and avoid damaging the loudspeakers. Audio compressors are also widely used to "densify" the audio signal: such a treatment is thus implemented in the music industry (recording studios, mixers or even 20 radios) because it increases the subjective sensation of sound volume. A signal can in particular be compressed at several levels: first at the mixing stage, mastering, and then at the broadcasting stage by the radio. Thus, depending on the compression parameters used to compress a sound signal, and in particular the compression ratio and the temporal constants, it is possible to obtain a sound signal having a very low sound dynamic: we can then speak of a signal " overcompressed ".

303 16 3 8 3 However, such a treatment is criticized by some users because it alters the sound reproduction of the original work, or may introduce distortions in the final sound signal. Finally, this compression treatment of sound dynamics is applied almost systematically, during the recording of the work, but also during the passage in radio, without the opinion of the user who no longer has then the possibility of having access to the original work. A need to be able to access the initial audio signal, before compression, has thus begun to be felt, without it being possible to do so easily. Indeed, audio compression is a nonlinear process, which is difficult to reverse. Nevertheless, there exist methods for decompressing a compressed audio signal, from the compression parameters (compression threshold, attack time, return time, ...) applied to the initial audio signal. The compression parameters must then be transmitted with the compressed audio signal. However, such transmission of information is not always possible: either because the compression parameters are not known, or because the transmission means does not allow such an addition of information. Moreover, the results obtained are not always satisfactory in fact. There are also methods of reversing the compression. Such a method is for example described in the patent application WO2014 / 135914: it makes it possible to restore a sound dynamic higher than that of the compressed audio signal, and to obtain a final audio signal close to the user of the audio signal. initially, without requiring the transmission, with the compressed audio signal, of information relating to the compression. However, similar to compression methods, such a decompression method includes many parameters characterizing its action on the compressed audio signal, which is often difficult and tedious for the user to adjust, especially when it is is not a specialist in audio processing. OBJECT AND SUMMARY OF THE INVENTION The present invention aims at solving the various technical problems stated above. In particular, the present invention aims at providing a decompression method, and the corresponding device, for obtaining a final signal faithful to the initial one, while being easy to parameterize for the user. The present invention aims in particular to provide a decompression method, and the corresponding device, for obtaining a final signal with a sound dynamics desired by the user. Thus, in one aspect, there is provided a method of decompressing the dynamics of an input audio signal, the input audio signal having been obtained by compressing the dynamics of an initial audio signal, the method of decompression for obtaining an output audio signal having an audio dynamic greater than or equal to that of the input audio signal. The method comprises: a) a step of determining a magnitude representative of the amplitude of the initial audio signal, b) a step of comparing said magnitude representative of the amplitude of the initial audio signal with respect to a threshold, c ) a step of amplifying the input audio signal when the magnitude representative of the amplitude of the original audio signal is greater than said threshold, so as to obtain the output audio signal, d) a step of determining a magnitude representative of the dynamics of the output signal, e) a step of comparing said magnitude representative of the dynamics of the output signal with a set value, and f) a step of modifying step a) of determining and / or comparison step b), as a function of the difference between the value of said quantity representative of the dynamics of the output signal and the setpoint value.

Thus, thanks to the method according to the invention, it is possible to increase the dynamics of the output signal easily, by setting a setpoint representative of the sound dynamics of the output audio signal, to obtain a modification of parameters. decompression method such as the decompression threshold and / or the catch-up gain, which leads to the same effect. In particular, to ensure an adequate sound reproduction, the method provides a control loop relating to the sound dynamics of the output signal, which is the magnitude that wants to change the user, to adapt the parameters of the decompression process. More concretely, the regulation loop 15 measures the dynamics of the output signal and compares it with a setpoint value to modify the parameters of the decompressor and obtain an output signal having a dynamics close to the setpoint value. Preferably, the magnitude representative of the dynamic of the output signal is the peak factor, calculated for example in the short or long term, the peak-to-average power ratio (PAPR), calculated for example in the short term. or in the long term, the true-peak-toloudness ratio (TPLR), calculated for example in the short or long term, or even the ratio of the maximum value to the value. minimum of the input audio signal, calculated for example in the short or long term. The quantities given are exemplary quantities for characterizing the sound dynamics of the output audio signal, particularly in the short term, to continuously adapt the processing applied to the input audio signal. Preferably, the modification step f) comprises modifying the threshold value of the comparison step b), as a function of the difference between the value of said quantity representative of the dynamics of the output signal and the value deposit. According to this embodiment, the number of peaks of the input audio signal that will be amplified is modified to increase the sound dynamics of the output signal.

Preferably, the amplification step c) comprises multiplying the input audio signal by a gain value greater than or equal to 1. A gain greater than 1 makes it possible to increase the dynamics of the output signal. The initial audio signal can be amplified by a retrofit gain after compression of the dynamic, to obtain the input audio signal. The amplification by a catch-up gain can be used after a dynamic compression step, in order to obtain a greater intensity of the compressed signal. Such amplification is applied to the entire compressed signal, which makes it possible not to increase the dynamics of the compressed signal but only its intensity. Preferably, the determining step a) comprises determining the magnitude representative of the amplitude of the initial audio signal by considering a determined value of catch-up gain. In this case, the magnitude representative of the amplitude of the audio signal is modulated to take account of any amplification by a catch-up gain. More precisely, the magnitude representative of the amplitude of the initial audio signal may be reduced, for example multiplied by a factor of between 0 and 1, in order to limit the effect of the amplification by a catch-up gain.

Preferably, the modification step f) comprises the modification of the determined value of the catch-up gain of the determining step a), as a function of the difference between the value of said quantity representative of the dynamics of the signal of the output and the value of 5 setpoint. In this embodiment, the number of peaks of the input audio signal which will be amplified is also modified, but by modifying the magnitude representative of the amplitude of the initial audio signal and not by modifying the threshold. Thanks to the method according to the invention, the decompression parameters are modified as a function of the difference between the dynamics of the output signal and that required by the user. It can thus accelerate the obtaining of the dynamics desired by the user. Preferably, the step e) of comparing said magnitude representative of the dynamics of the output signal with a set value, comprises determining the difference or ratio between said two values. Such determinations make it possible to account for the difference between the output value and the setpoint value, and can be applied directly to the parameters of the decompression process to minimize said difference.

Preferably, step f) of modification does not modify the steps a) of determination and b) of comparison when the value of said magnitude representative of the dynamics of the output signal is greater than or equal to the setpoint value. According to this mode of implementation, the method does not alter the input signal when the sound dynamics thereof is already greater than or equal to the setpoint value. This limits the processing applied to the input signal, and thus possible distortions or over-decompression. Preferably, the input audio signal is an audio signal which has been at least dynamically compressed by a limiter, in particular of the "brick wall" type. This is the case where the initial audio signal has been clipped to a maximum value corresponding to the threshold of the "brick wall" type limiter. In this case, the parameters of the compressor are known: indeed, a "brick wall" type limiter has a very short attack time, a short return time and a very high compression ratio. The processing applied during the decompression can then be done more efficiently, in order to obtain an output signal close to the initial audio signal. Preferably, step a) comprises determining the magnitude representative of the amplitude of the initial audio signal from the input signal and of modeling the compression of the dynamics of the initial audio signal having obtained the input signal. Thus, the decompression method estimates, from the input audio signal, the times during which the original audio signal was compressed, to decompress in a second time.

According to another aspect, the invention also relates to an output audio signal obtained by the method described above. In another aspect, the invention also relates to a device for decompressing the dynamics of an input audio signal, the input audio signal having been obtained by compressing the dynamics of an initial audio signal, and the decompression device for obtaining an output audio signal having an audio dynamic greater than or equal to that of the input audio signal. The device comprises: a first means for determining a magnitude representative of the amplitude of the initial audio signal; a first means for comparing said magnitude representative of the amplitude of the initial audio signal with respect to a threshold; means for amplifying the input audio signal when the magnitude representative of the amplitude of the original audio signal is greater than a threshold, so as to obtain the output signal, - a second means for determining a magnitude representative of the dynamics of the output signal; - a second means for comparing said magnitude representative of the dynamics of the output signal with a set value; and - a means for modifying the first determination means and / or the first means. comparison, as a function of the difference between the value of said magnitude representative of the dynamics of the output signal and the setpoint value.

Preferably, the modifying means is configured to modify the threshold value of the first comparison means, as a function of the difference between the value of said quantity representative of the dynamics of the output signal and the setpoint value. Preferably, the amplifying means is configured to multiply the input audio signal by a gain value greater than 1. The initial audio signal can be amplified by a gain after compression of the dynamic, to obtain the audio signal. input. Preferably, the first determination means determines the quantity representative of the amplitude of the initial audio signal by considering a determined value of catch-up gain. Preferably, the modifying means is configured to modify the determined value of the retrofit gain considered by the first determination means, as a function of the difference between the value of said magnitude representative of the dynamics of the output signal and the value of setpoint. Preferably, the second means for comparing said magnitude representative of the dynamics of the output signal with a set value, is configured to determine the difference or the ratio between said two values.

Preferably, the first determination means determines the magnitude representative of the amplitude of the initial audio signal from the input signal and a modeling of the compression of the dynamics of the initial audio signal which made it possible to obtain the signal. input.

BRIEF DESCRIPTION OF THE DRAWINGS The invention and its advantages will be better understood on reading the detailed description of a particular embodiment, taken by way of non-limiting example and illustrated by the appended drawings in which: FIG. 1 is a diagrammatic representation of a decompression device according to the invention; FIG. 2 is a flowchart of a first exemplary embodiment of the method according to the invention, and FIG. 3 is a flowchart. a second exemplary mode of implementation of the method according to the invention. DETAILED DESCRIPTION OF THE INVENTION FIG. 1 schematically illustrates a decompression device 1 of the sound dynamics of an input signal according to the present invention. The decompression device 1 thus receives as input an input signal y, and provides an output signal z. The input signal is obtained by compressing an initial signal x. In the remainder of the description, it is considered that the different signals (initial x, input y and output z) are audio signals. However, the invention is not limited to this type of signal, but can be applied to any signal undergoing compression and for which the initial dynamic is desired.

Likewise, it is considered in the remainder of the description that the input signal is a cut signal, that is to say that the signal has been obtained by compression of the initial signal x by a type limiter. "Brickwall". Finally, in the remainder of the description, the sampled representations (x (n), y (n) and z (n)) will be used to designate, respectively, the initial signal x, the signal d input y and the output signal z. The decompression device 1 comprises a decompression means 2 of the input signal y (n), in particular as a function of a magnitude representative of the amplitude of the initial signal x (n). More specifically, the decompression means 2 comprises a means 4 for determining a magnitude V (n) representative of the amplitude of the initial signal x (n), from the input signal y (n) and from a M means of retrofit gain greater than or equal to 1. The purpose of means 4 is notably to detect the instants for which the input signal x (n) has been cut by the brick wall limiter to obtain the input signal y (n), and to take into account a possible amplification of the initial signal compressed by a catch-up gain (M greater than 1). The magnitude V (n) of the initial signal x (n) can thus be the envelope, the sound intensity, the sound intensity felt by the user or any other quantity representative of the amplitude of the input signal. (not). The magnitude V (n) can thus be determined as follows: -) where: is the estimate of the envelope of the initial signal x (n), [3 is an attenuation factor strictly greater than 0 and less or equal to 1, and p is an integer representing the type of detector. More precisely, p is equal to 1 for a peak detector, and p is equal to 2 for an effective value detector.

The decompression means 2 also comprises means 6 for comparing the magnitude V (n) of the initial signal with a threshold value S. The comparison means 6 receives, in particular, the magnitude V (n) of the signal of the input signal. input x (n) determined by the means 4, and the threshold value S. The comparison means 6 then determines a signal representative of the instants for which the magnitude V (n) of the initial signal x (n) is greater than the value of the threshold S, and outputs, an amplification function G (n) which is an instant gain of amplification. The amplification function G (n) is equal to the value of the amplification gain for the 10 instants where the quantity V (n) is greater than the value of the threshold S and is equal to 1 (zero gain) for the others. moments. Thus, a variable gain G (n) is obtained at output that makes it possible to amplify the input signal y (n) during the instants for which the magnitude V (n) of the initial signal x (n) is greater than the value of the threshold S.

Finally, the decompression means 2 comprises an amplification means 8, receiving as input: the input signal y (n) and the variable gain G (n) supplied by the comparison means 6, and delivers, as output , the output signal z (n). Thus, the decompression means 2 makes it possible to amplify the input signal y (n) by multiplying it by the gain G at each instant for which the magnitude V (n) of the initial signal x (n) is greater to the value of the threshold S. An output signal z (n) is thus obtained in which the instants corresponding to the peaks of the initial signal x (n) have been amplified: the output signal z (n) thus obtained therefore has a sound dynamics 25 greater than that of the input signal y (n). An example of decompression means 2 is described in particular in application WO2014 / 135914: the threshold S is then 101- / 20, where L is a threshold value in decibel, and the gain G is the function I-1-1 [ y (n), 6] representing the inverse transfer function of the limiter used to compress the initial signal x (n). According to the invention, the decompression device 1 also comprises a regulation loop making it possible to regulate in particular the threshold S or the retrofit gain M of the decompression means 2, in order to obtain an output signal z (n) presenting a dynamic close to that desired by the user. For this purpose, the decompression device 1 comprises a means 10 for determining the dynamics of the output signal z (n). The means 10 thus receives as input the output signal z (n) and outputs a signal representative of the dynamics of the output signal z (n). The output signal of the means 10 may for example be obtained by calculating the short or long-term peak factor C of the output signal z (n), ie: P2-1PR where: PAPR is the peak to average power ratio, ZRms corresponds to the rms value of the output signal z (n) and I corresponds to the absolute value of the peak of the output signal z (n) . In particular, in the short term, may be a peak representing the maximum value of the output signal over a duration of, for example, 400 ms. In the long term, may be a peak representing the maximum value of the output signal over a longer duration up to the total duration of the output signal z (n). Similarly, in the short term, Z Rms may be an effective value given by the root mean square of the output signal over a duration of, for example, 400 ms. In the long term, ZRms can be an effective value given by the root mean square of the output signal over the entire duration of the output signal from the start of measurement to the present.

The peak factor C is then transmitted to a comparison means 12 which also receives a set value U given by the user. The comparison means 12 makes it possible to compare the peak factor and the setpoint U, for example by calculating the ratio between these two magnitudes: U / C. The value obtained makes it possible to determine whether the parameters of the amplification means must be modified, and by how much. Finally, the decompression device 1 comprises a modification means 14, receiving as input the U / C ratio supplied by the comparison means 12, and outputting one or more modified parameter values of the amplification means 8, by For example, if the value of the U / C ratio is equal to or smaller than 1, this means that the dynamic range of the output audio signal z (n) is at a value satisfactory to the user, and that it is not necessary to further modify the amplification of the input signal y (n). On the other hand, if the value of the U / C ratio is greater than 1, then the dynamics of the output signal z (n) is not sufficient, and the modifying means 14 will modify the parameters of the amplification means 2 in order to obtain a larger dynamic output. For example, the modifying means 14 can lower the threshold value S used by the comparison means 6 in order to amplify a greater time interval of the input signal y (n), or else lower the gain value of catching M considered by the determining means 4, which leads to increasing the value of the representative magnitude V (n) of the initial signal. In both cases, the action of the modifying means 14 makes it possible to increase the dynamics of the output signal z (n), that is to say the value C. The regulation loop of the decompression device 1 thus allows to vary the dynamics of the output signal z (n) until an output signal having a velocity greater than or equal to that desired by the user is obtained. The latter can therefore obtain an output audio signal according to his desires without having to modify and adjust various decompression parameters. On the contrary, thanks to the device according to the present invention, the regulation loop makes it possible to automatically manage the wish of the user, reliably and quickly. Figure 2 illustrates a flowchart of an exemplary decompression method according to the invention. As shown in FIG. 2, the decompression method 20 comprises a first step 22 of determining a magnitude representative of the amplitude of the initial signal x (n), for example from the input signal y (n). ), a second step 24 of comparing said magnitude representative of the amplitude of the initial signal x (n) with a threshold value S, and a third step 26 of amplifying the input signal y (n) when the magnitude representative of the amplitude of the initial signal is greater than the threshold. In a fourth step 28, the decompression method 20 determines a magnitude representative of the dynamics of the output signal z (n). Such a magnitude may be for example the peak factor, as previously described.

Next, the decompression method 20 comprises a fifth step 30 of comparing said magnitude representative of the dynamics of the output signal with a desired value U desired by the user. Finally, in a sixth step 32, the threshold used in the second comparison step 24 is modified to modify the amplification of the input signal y (n) as a function of the difference between the value of said magnitude representative of the dynamics of the output signal and the setpoint value U, and the decompression method 20 starts again at the first step 22, so as to lead to an output signal having a dynamic close to the setpoint value. FIG. 3 illustrates a flowchart of a second example of a decompression method 34 according to the invention. In this second example, the references identical to those of FIG. 2 designate the same steps. As shown in FIG. 3, the decompression method 34 comprises a first step 36 of determining a magnitude representative of the amplitude of the initial signal x (n), for example from the input signal y (n) and a determined value of a retrofit gain M, a second step 24 of comparing said magnitude representative of the amplitude of the initial signal x (n) with a threshold value S, and a third step 26 of amplifying the input signal y (n) when the quantity representative of the amplitude of the initial signal is greater than the threshold.

In a fourth step 28, the decompression method 34 determines a magnitude representative of the dynamics of the output signal z (n). Such a magnitude may be for example the peak factor, as previously described. Then, the decompression process 34 comprises a fifth step 30 for comparing said magnitude representative of the dynamics of the output signal with a desired value U desired by the user. Finally, in a sixth step 38, the determined value of the retrofit gain M used in the first determination step 36 is modified to modify the amplification of the input signal y (n) as a function of the difference between the value of said magnitude representative of the dynamics of the output signal and the setpoint value U, and the decompression process 34 starts again at the first step 36, so as to lead to an output signal having a dynamic close to the value deposit. The method according to the invention thus makes it possible to modify an input signal so as to obtain an output signal having the sound dynamics desired by the user. The invention thus facilitates the processing of the signal applied to the input audio signal, while allowing the user to obtain the desired sound dynamics. Moreover, the processing is not limited to the dynamics of the input signal, and it is also possible to obtain an output signal having a higher dynamics than the initial signal, according to the user's tastes. . In addition, the invention allows to decompress the input signal without additional information, and can therefore be applied to any existing signal. However, the invention is not limited to an uninformed decompression device, and the invention can also be implemented with an input signal having additional information relating to the initial signal or the compression method. such information can be used to determine the times during which the initial signal has an amplitude greater than a given threshold value.

Claims (16)

REVENDICATIONS1. A method (20, 34) of decompressing the dynamics of an input audio signal (y), the input audio signal (y) having been obtained by compressing the dynamics of an initial audio signal (x), the decompression method for obtaining an output audio signal (z) having an audio dynamic that is greater than or equal to that of the input audio signal (y), and comprising: a) a step (22, 36) for determining a quantity representative of the amplitude of the initial audio signal (x), b) a step (24) for comparing said magnitude representative of the amplitude of the initial audio signal (x) with respect to a threshold (S), c) a step (26) of amplifying the input audio signal 15 when the magnitude representative of the amplitude of the initial audio signal (x) is greater than said threshold, so as to obtain the output audio signal (z), d) a step (28) of determining a representative magnitude (C) of the dynamics of the output signal (z), e) a step (30) of comparing said magnitude representative of the dynamics of the output signal (z) with a set value (U), and f) a step (32, 38) of modifying step a) and / or of step b) as a function of the difference between the value of said magnitude representative of the dynamics of the output signal (z) and the setpoint value (U). 2. The decompression method (20, 34) according to claim 1, wherein the representative magnitude (C) of the dynamics of the output signal is the peak factor, calculated for example in the short or long-term, the peak-to-rms ratio, calculated for example in the short or long term, the true peak to loudness ratio, calculated for example in the short or long term, or the ratio of the maximum value to the minimum value of the input audio signal, calculated for example in the short or long term. The decompression method (20) according to claim 1 or 2, wherein the modifying step f) (32) comprises modifying the threshold value (S) of step b) (24) according to the difference between the value of said representative quantity (C) of the dynamics of the output signal and the setpoint value (U). The decompression method (34) of any one of claims 1 to 3, wherein the initial audio signal (x) has optionally been amplified by a gain after compression of the dynamic to obtain the input audio signal. (y), and wherein step a) (36) comprises determining the magnitude representative of the amplitude of the initial audio signal (x) by considering a determined value of catch-up gain. The method (34) of claim 4, wherein the modifying step f) (38) comprises modifying the determined value of the catch-up gain of step a) (36), as a function of the deviation between the value of said representative quantity (C) of the dynamics of the output signal and the setpoint value (U). 6. Method (20, 34) according to any one of claims 1 to 5, wherein the step e) (30) for comparing said magnitude representative of the dynamics of the output signal to a value of 3031638 20 set, includes determining the difference or ratio between said two values. The method (20, 34) of any one of claims 1 to 6, wherein the modifying step f) (32, 38) does not modify steps a) and b) when the value of said magnitude representative (C) of the dynamics of the output signal is greater than or equal to the set value (U). 10 8. Method (20, 34) according to any one of claims 1 to 7, wherein the input audio signal (y) is an audio signal which has been at least dynamically compressed by a limiter, including type "brick" wall ". 15 The method (20) according to any one of claims 1 to 8, wherein step a) (22, 36) comprises determining the magnitude representative of the amplitude of the initial audio signal (x) from the an input signal (y) and a compression modeling of the initial audio signal (x) dynamics having obtained the input signal (y). An output audio signal (z) obtained by the method of any of claims 1 to 9. 11.Device (1) for decompressing the dynamics of an input audio signal (y), the input audio signal having been obtained by compressing the dynamics of an initial audio signal (x), the decompression (1) for obtaining an output audio signal (z) having an audio dynamic greater than or equal to that of the input audio signal (y), characterized in that it comprises: 3031638 21 - a first means determining (4) a magnitude representative of the amplitude of the initial audio signal (x), - a first comparing means (6) of said magnitude representative of the amplitude of the initial audio signal (x) with respect to a threshold, - amplification means (8) of the input audio signal (y) when the magnitude representative of the amplitude of the initial audio signal (x) is greater than a threshold, so as to obtain the output signal (z), 10 - a second means for determining (10) a magnitude representative of the dynamics of the output signal, - second comparison means (12) of said magnitude representative of the dynamics of the output signal at a set point, and - means for modifying (14) the first determining means (4) and / or the first comparison means (6) as a function of the difference between the value of said quantity representative of the dynamics of the output signal and the setpoint value. 20 12.The decompression device (1) according to claim 11, wherein the modifying means (14) is configured to modify the value of the threshold (S) of the first comparison means (6), as a function of the difference between the value of said magnitude representative of the dynamics of the output signal and the set value. The decompression device (1) according to any one of claims 11 to 12, wherein the initial audio signal (x) has optionally been amplified by a retrofit gain after compression of the dynamic to obtain the audio signal of input 3031638 22 (y), and wherein the first determining means (4) determines the magnitude representative of the amplitude of the initial audio signal (x) by considering a determined value of catch-up gain. 5 14.Dispositif (1) according to claim 13, wherein the modifying means (14) is configured to change the determined value of the catch-up gain considered by the first determination means (4), according to the difference between the value of said magnitude representative of the dynamics of the output signal and the setpoint value. The device (1) according to any one of claims 11 to 14, wherein the second comparing means (12) of said magnitude representative of the dynamics of the output signal to a set value is configured to determine the difference or the ratio between the two values. The device (1) according to any one of claims 11 to 15, wherein the first determining means (4) determines the magnitude representative of the amplitude of the initial audio signal (x) from the input signal. (y) and a modeling of the compression of the dynamics of the initial audio signal (x) which made it possible to obtain the input signal (y). 25