EP1606974A1

EP1606974A1 - Method for treating an electric sound signal

Info

Publication number: EP1606974A1
Application number: EP04722309A
Authority: EP
Inventors: Georges Claude Vieilledent; Jérôme MONCEAUX; Jean-Michel Raczinski; Michel Corneloup; Yann Lecoeur
Original assignee: Arkamys SA
Current assignee: Arkamys SA
Priority date: 2003-03-20
Filing date: 2004-03-22
Publication date: 2005-12-21
Also published as: US20060215841A1; CN1762178A; FR2852779B1; WO2004086818A1; US7613305B2; CN1762178B; FR2852779A1

Abstract

A method for generating a sound (63, 64) giving a sensation of depth by applying, upon extraction, a transfer function quadrille onto electric signals on the left thereof (17) and right thereof (13). Said transfer functions simulate the trajectories taken by the sound associated with the electric signal to be treated in order to reach two receivers if said sound had been emitted in the air. The signals (23, 24, 27, 29) treated one by one by one of the four transfer functions of the quadrille are combined with each other, whereupon the sound signal thus obtained is mixed with the original electric signal to be treated (13, 17) after a temporal reset.

Description

Method for processing an electrical sound signal

The present invention relates to a method for processing an electrical sound signal. The object of the invention is, with this electrical sound signal, to produce a depth effect at the time of diffusion. In the invention, a stereophonic sound signal is preferably used, but a monophonic sound signal could be used. From a classic left to right sound, the process gives an effect of depth which transposes the listener into a three-dimensional space. The invention finds particularly advantageous, but not exclusively, applications in the processing of an original film soundtrack. It may however relate to the processing of any musical band, whether this is otherwise stored on a tape medium or on a disc. The invention is intended, among other things, for sound engineers who will be able, from a sound signal without depth, conventional and available on a commercial support, to apply transformations so as to give the sound volume and envelopment desired. The invention also relates to industrial applications which consist in installing on consumer devices elements, such as for example memories, which incorporate necessary and sufficient parameters for the implementation of sound processing according to the invention. Like the sound engineer, the end user will be able to use the settings proposed on his stereo, television or digital music player to give the depth he wants to the sound at the moment he wishes. A sound without depth, flat, gives the impression when one listens to it at a certain distance to come from a plan located opposite the listener. A sound with depth gives the impression, much more pleasant, of coming from sound sources arranged in several planes in depth with respect to the listener. We know that in the field of sound processing, it is necessary to carry out sound modifications or original sound recordings, in order to give the listener optimal listening comfort. This is the case, for example, with the sound of a film or an audio medium.

We know, from document EP-A-1 017 249, a process intended for the taking of sounds, their recording and their restitution and which reproduces the natural feeling of sound spaces. This method is implemented by means of a sound recording set, a recording medium and a broadcasting set. In this process, sound is taken simultaneously by two so-called right and left microphones. All the microphones are moved relative to a sound source, making the difference and the height of each microphone particularly different from the source. That is to say, we bring one microphone closer to the sound source when we move the other away and vice versa. This distance is carried out in such a way that any of the two faces of a virtual plane, which extends from one microphone to the other, moves away from one microphone or the other. The right microphone can thus become the left microphone. The two microphones can also be approached and distant simultaneously from said source. This process, which can be described as acoustic-analog, makes it possible to give an impression of depth to a well-defined type of sound: the sound for which the sound was taken by means of the two microphones, and for the position and the position variation of these two microphones at the time of sound recording.

This process has limitations. Indeed, depending on the way the microphones are moved during sound recording, the recorded sound has a particular hue. This shade, also called color, may appear more or less pleasant or more or less effective taking into account the desired effects. In addition, this shade is no longer editable.

In addition, given the nature of the process, it is necessary to carry out for each new sound to be processed a particular sound recording. This particular sound recording entails making as many new sound recordings as there are new sounds to be processed, without guarantee of the expected result. This last remark means that a buyer can dispose of unprocessed sound and processed sound simultaneously only if he acquires an unprocessed version and a treated version. In addition, the purchaser cannot simply switch from one version of the sound to the other, activating or not the transformation using a command button unless he has a double player.

The object of the invention is to remedy this problem of a multitude of sound recordings and of availability by making it possible to apply digital sound processing for deepening any sound from the outset. treat. The invention consists in digitally simulating a transformation which corresponds to the analog process of taking sound mentioned above. This simulation is made possible because, beforehand, the parameters of this transformation have been determined. The parameters of this transformation are established using a sound recording configuration. In this configuration, two speakers are placed in a room opposite an artificial head. The artificial head has two microphones simulating the two human ears. To determine the parameters, a digital detection of a white noise received by each of the microphones of the head is carried out. It is considered that for each of the loudspeakers, two propagation paths are possible to reach the microphones. This double path is broken down into a lateral path and a crossed path for each of the speakers. From this arrangement of speakers and microphones in space, we extract different filters, four in an example (when there are two speakers and two microphones), corresponding to the four possible paths of sound. We match a transformation filter between a detected sound and a sound emitted for each path. The simulation then consists of processing any initial sound by passing it through a filter whose parameters conform to the transformation. These filters can be applied to any type of sound, so as to digitally simulate the analog sound path. Finally, by additionally digitally combining the sound processed by the filters and the original sound, a feeling of depth is obtained which gives the listener the impression that the sound is three-dimensional. The listener can, with or without requesting the filters, switch from conventional listening (flat) to in-depth listening.

When combined, the original sound and the sound processed by the filters are preferably shifted in time.

The invention therefore relates to a method for processing an electrical sound signal in which the following steps are implemented:

- we process an electrical signal of his right and an electrical signal of his left to produce an electrical signal of his processed right and an electrical signal of his left processed, characterized in that to process - we simulate the production of a first signal electric from his treaty right from the electrical signal of his right,

- we simulate the production of a second electrical signal from its right processed from the electrical signal from its left,

- we simulate the production of a third electrical signal from its left treaty from the electrical signal from its left,

- we simulate the production of a fourth electrical signal from its left treaty from the electrical signal from its right, and

- we broadcast a sound corresponding to these four electrical sound signals processed. The invention will be better understood on reading the description which follows and on examining the figures which accompany it. These are presented for information only and in no way limit the invention. The figures show:

- Figure 1: a montage representing a digital processing used for sound processing according to the invention; - Figure 2: a schematic representation of a device used for the extraction of filter coefficients, characterizing the different paths taken by the sound emitted by two speakers to the microphones of the head;

- Figure 3: arrangements in space of the elements of the sound recording device of Figure 2 also showing a concept of cone of confusion associated with the human ear;

- Figure 4: a look of an example of a right side filter and a right / left cross filter;

- Figure 5: the preferred embodiment of each of the filters through an example; Figures 1, 2 and 5 show an embodiment of the invention. Other embodiments may exist and meet the definition of the invention.

FIG. 1 illustrates by an arrangement the principle of the method for digital processing of an electrical sound signal of the invention. The assembly has two filters 1 and 2 to simulate the different sound paths. It also comprises in practice four summers 3, 4, 5 and 6 to add two by two the signals filtered by filters 1 and 2. At the output of these summers, and because in a preferred version the processing is frequency, two cells of inverse discrete Fourier transform 7 and 8 allow the signals to be transposed over time. Two transformers matrixes 9 and 10 make it possible to process the electrical signal applied to them as input and coming from cells 7 and 8. Two loudspeakers 11 and 12 make it possible to broadcast the sounds obtained delivered by the matrix transformers. An electrical signal of its right 13 is applied to input 14 of the filter

1. It is divided at the output of the filter, into an electrical signal of its processed right 15 and an electrical signal of its processed left 16. An electrical signal of its left 17 is applied via the connection 18 at input 19 of the filter 2. This signal 17 is divided at the output of filter 2 into an electrical signal processed by its right 20 and an electrical signal processed by its left 21. If the starting sound is monophonic, the electrical sound signals applied to inputs 14 and 19 are the same . We could also simplify by removing filter 2 and using for filter 1 a combination of the coefficients of filters 1 and 2. The four electrical signals 15, 16 and 20 and 21 observed at the output of filters 1 and 2 each correspond to the simulation of a path that would have taken the sound associated with the electrical signals of its original sound in the air. By doing so, we realize that we simply simulated numerically the acoustico-analog transformation of the cited state of the art. This simulation was applied to any starting sound associated with signals 13 and 17. We can even decide to implement the invention or not by connecting or not inputs 14 and 19 to filters 1 or 2 or to the loudspeakers. speakers 11 or 12. The connection can be made by switching generated by a single control button on a front of a device. In the invention, the four signals are preferably combined as follows. The first electrical signal of its processed right 15, obtained from the electrical signal of its original right is applied at input 23 of the adder 3 via a link 22. The second electrical signal of its processed right 20, obtained from the signal electrical signal from its original left, is applied to the second input 24 of the adder 3 via the link 25. At the output of the adder 3, an electrical signal of its right 26 is obtained obtained from the electrical signals of its right 13 and of its original left 17.

The third electrical signal of his treated left 21 obtained from the electrical signal of his original left is applied to input 27 of the adder 4 via connection 28. The fourth electrical signal from his treated left 16, obtained from the electrical signal from his right 13, is applied at input 29 of adder 4 via link 30. We then obtain at output from the summator 4 a signal 31 of his left processed, obtained from the electrical signals of his right 13 and his left 17 of origin.

In a preferred example, the signals 26 and 31 observable at the output of the two summers 3 and 4 are transposed in the frequency domain. In fact, filters 1 and 2 are applied to the frequency spectra of the input signals for greater ease of processing. We will explain later why such treatment is preferred.

The electrical signal of its processed right 26 obtained at the output of the adder 3 is applied to the input 32 of a cell 7 of inverse discrete Fourier transform via the connection 33, so as to obtain at the output of the cell 7, an electrical signal 34 of its treaty law transposed into the temporal domain.

Likewise, the electrical signal 31 from its processed left obtained at the output of the summator 4 is applied to the input 35 of a cell 8 of inverse discrete Fourier transform via a connection 36. At the output of cell 8 of discrete Fourier transform reverse we obtain an electrical signal 40 from its processed left transposed in time. In the rest of the presentation, we will speak of a discrete Fourier transform. It is however possible to use other types of transformation. We could use transform circuits in z or others. In addition, these transforms are discrete to suit a numerical calculation. However, an analog simulation would be possible.

The signal 34 is applied via a connection 39, at input 38 of the matrix transformer 9. The transformer 9 performs an operation of selecting a sub-matrix MD. The role of this matrix operation MD is to select a part of the samples of the electrical input signal. As will be seen later in Figure 5, some samples are redundant and they are not significant in the depth rendering of the final sound. The MD matrix operation solves this redundancy problem. Similarly, the signal 40 obtained at the output of the inverse discrete Fourier transform 8 is applied to the input 41 of a matrix cell. 10 containing an MG part via connection 42, so as to obtain at output 43 a signal which retains only the significant samples.

The electrical signal of its transposed and modified processed right obtained at output 44 of the matrix transformer 9 and the electrical signal of its transposed and modified processed right obtained at output 43 are then preferably combined respectively with the electrical signal of its transposed right. origin 13 and the electrical signal from its original left 17, as follows:

The electrical signal of its processed right, transposed and modified observable at 44 is taken at the interconnection 46 of the connection 45 connected to the output 44 of the matrix cell 9. This signal taken at 46 is applied at input 47 of the adder 5 via the junction 48. The electrical signal of his right 13 is taken at the interconnection 49 of the link connecting the electric signal of his right 13 to the input of the filter 1. This signal taken is applied at input 50 of the adder 5 via the connection 51. The output 52 of the adder 5 is connected to the input 53 of the speaker 11 via the connection 54.

The electrical signal from its processed left, transposed and modified, is taken at output 43 from the matrix cell 10 at the interconnection 54 of the link 55. This signal is applied at the input 56 of the adder 6 via the link.

57. The electrical signal from its left 17 is taken from the link 18 via the junction 58. This signal is applied to the second input 59 of the summator 6 via the junction 60. The output 61 of the summator 6 is applied in speaker 62 input 12.

The sound resulting from the sound diffusion 63 of the loudspeaker 11 as well as of the sound diffusion 64 of the loudspeaker 12 results from a combination, here additional, between the electrical signals of original sound 13 and 17 with the electrical signals of its processed treaties observable in 46 and 54. A time difference is preferably introduced between the original signals and the processed signals, so that each of the processed electrical signals is emitted in advance with respect to the electrical sound signals of origin. This combination of signals and this time difference provide a complementary feeling of depth to the listener. We could do without the original sounds.

Of course, in monophonic use, the signals intended for the inputs of speakers 11 and 12 are mixed and broadcast by a single speaker. It was found with the invention, in the context of such use, especially with a mobile phone, better intelligibility of the sounds broadcast. In particular for advertising messages accompanied by a background sound, they are better understood by the listener with the treatments of the invention than without these treatments. FIG. 2 is the analog equivalent of the essential system of the invention delimited in dotted lines in FIG. 1. From this arrangement, the transfer functions which are present in the filters 1 and 2 of FIG. 1 are deduced. This deduction forms the filter extraction phase. For this, there are in a room two speakers 65 and 66 and an artificial head 67 composed of two microphones 68 and 69 located on the head and oriented in directions forming an angle of 180 ° with respect to the other. They actually correspond to the ears of the artificial head 67.

The sound emitted from the loudspeaker 70 is divided into two acoustic waves using paths 71 and 72. The wave which takes paths 71 reaches one of the microphones 68 of the head 67 by the shortest path. acoustic 72 reaches the microphone 69 by the longest path 72. In the same way, the sound emitted at the output of the speaker 73 reaches the head via two paths: a part of the sound emitted goes from the output of the speaker 73 towards the left microphone 69 via the path 74, the other part of the sound emitted goes from the output of the speaker 73 to the right microphone of the head 68 via the path 75. The waves or acoustic fields which take the paths 71 and 74 constitute the lateral fields. The acoustic fields which take paths 72 and 75 constitute the crossed fields. Although the artificial head can be located anywhere in the room to simulate a particular sound path and perform an extraction phase, in a particular configuration, the artificial head 67 is located in the median axis of the two loudspeakers. speakers. An intermediate step therefore consists in placing the head very precisely on this median axis. For this, we send the same train of pulses corresponding to a dirac comb applied at the input of the loudspeaker 65 and simultaneously at the input of the loudspeaker 66. in theory a dirac is an instantaneous and infinite pulse, the comb pulses are here very brief and of great amplitude. The maximum amplitude of the dirac is called the dirac peak. During the diffusion of the pulse trains, signals received by microphones 68 and 69 are observed by means of a oscilloscope connected to the output of these microphones. The two channels of this oscilloscope are adjusted on the same time base. The signals observed have the appearance of a diracs comb whose amplitudes of peaks are varied. On each channel, the dirac peak of highest amplitude corresponds to the direct field and the dirac peak of directly lower amplitude corresponds to the cross field. The position of the artificial head 67 is varied until the direct fields and the crossed fields are synchronous, that is to say that the peaks corresponding to the direct field and the peaks corresponding to the crossed fields observable on the oscilloscope are aligned two by two. Thus the direct field received by the microphone 68 must be aligned in time with the direct field received by the microphone 69 and the cross field received by the microphones 68 must also be aligned with the cross field received by the microphone 69. setting of the preferred particular configuration, it is certain that the artificial head 67 is very exactly the same distance from the speakers 65 and 66.

Regarding the extraction phase, it should not be restricted to the implementation of a device involving two microphones and two speakers only. In general, if we use p speakers with q microphones, we multiply the cross paths. For each of the p speakers, q paths are possible to reach the q microphones. Such a device then leads to q coefficients for each of the loudspeakers. To establish these q coefficients, we isolate the p speakers one by one.

In the simple and preferred case with two speakers and two microphones, this establishment is carried out on the basis of a sound pick-up different from that of the acoustic-analog process above. Indeed, in the acoustic-analog process studied in the state of the art, the original sounds are emitted at the same time. In contrast, to extract the transfer functions of the filters of the invention, white noise acoustic signals are applied, separately and successively, to each of the speakers 65 and 66. White noise is used in this extraction step filters because white noise also makes it possible to use a maximum sequence length (MLS) method which notably prevents outside noise from disturbing the experience.

Firstly and for a diffusion configuration, an electrical right white noise signal SBD 76 is produced. This signal SBD 76 is applied at input 77 of loudspeaker 65. An acoustic signal of right white noise is then emitted at output 70 of loudspeaker 65 and gives rise to an electrical signal of modified white noise detected by microphone 68 because of the lateral path 71. Likewise, a modified white noise electrical signal is detected by the microphone 69 because of the cross path 72. The sound detected by the microphones is not white due to the propagation chain followed by the starting white noise . This is why we qualify this detected sound as modified white noise. From the two signals detected by the microphones 68 and 69 of the head on the basis of the electrical signal of straight white noise emitted, the transformation coefficients HDD 78 of filter 1 and HDG 79 of filter 1 can respectively be determined. These coefficients result for example from 'a frequency division, frequency component to frequency component, point to point complex, between the frequency spectra of the electrical signals detected by the microphones and that of the original straight white electrical signal. Two sets of coefficients HDD 78 and HDG 79 are thus obtained. The components of the spectra of the different signals of the extraction phase are complex points in the mathematical sense. Each point in fact gives an indication of the phase and the amplitude of the signal to which it relates. This frequency division corresponds in fact for HDD 78 to a first intercorrelation of the electrical signal of right white noise in input with the electrical signal of right white noise modified in the microphone 68. One carries out then for HDG 79 a second intercorrelation between the electrical signal of white noise applied at the input of loudspeaker 77, with the electric signal of modified left white noise processed detected by the microphone 69. In a second step, an electrical signal of left white noise is only emitted at input 80 of loudspeaker 66 SBG 81 via the link 82. The signal of its white left is emitted by the output 73 of the loudspeaker 66. It is detected by a microphone 68 of the head 67 an electrical signal received white modified right which has borrowed the path 75. Microphone 69 detects a left modified white electrical signal received which has taken path 74. A third set of HGD coefficients is produced 200 linked to filter 2, by making a point-to-point frequency division between the spectrum of the white electrical signal received modified right at 68 and the spectrum of the white electrical signal transmitted left SBG 81. A fourth set of HGG 201 coefficients linked to filter 2, by making a point-to-point frequency division between the spectrum of the white electrical signal received on the left at 69 and the spectrum of the white electrical signal transmitted on the left. In fact, there is again an intercorrelation in order to obtain these two filters. Filters are preferably used whose spectral filtering length is a power of two because the algorithms used for the cross-correlation and the discrete Fourier transform use models optimized for this particular case.

These four sets of coefficients of four transfer functions form a quadrille of coefficients. It is these quadrilles and their characteristics which give a certain color and a certain depth to the processed sound. Indeed, the coefficients of the transfer functions of the filters take into account the chain taken by the sound, namely the preamplifier of the speaker 65 (or 66), the amplifier of the speaker 65 (or 66), the propagation in the environment and the characteristics of the microphones. For each system, and for each configuration in space, the sound associated with a quadrille can therefore be different.

Figure 3 precisely, illustrates the fact that the transfer functions obtained during the extraction phase of Figure 2 depend on the geometry of the device in space. Two loudspeakers 83 and 84 as well as an artificial head 85 composed of two microphones 86 and 87 disoriented on the head by 180 ° from one another are arranged in a room 90. The head 85 has two cones of confusion 88 and 89 which are characteristic of the human ear. The opening of the cones of confusion is between fifteen and twenty-five degrees. All the points of the section of the cone of confusion 88 or 89, have an identical inter-aural delay. When a sound is emitted in one of the cones of confusion, the listener has difficulty in locating the source of this sound. This phenomenon turns out to be interesting for particular sound recordings. For each position of the speakers in room 90, the head 85 produces a different listening sensation. That is, it detects different electrical signals of sound, and this results in quadrilles of different nature, with different coefficients for each position. Called system configuration, the set of parameters corresponding to a fixed or mobile position of the speakers and a fixed or mobile position microphones. Once positioned, the elements of a configuration preferably remain static during the sound recording which results in the determination of the coefficients of the filters. The position of the speakers 83 and 84, that of the head 85 and the microphones 87 and 86, as well as their orientation are all parameters which taken separately play on the nature of the electrical sound signal which is picked up by the microphones. Indeed, the variation in the distance from the head 85 to the speakers 83 and 84 amounts to varying the time the sound travels through the air. For example, the quadrille obtained for the configuration of elements 83, 84 and 85 in room 90 does not give the same sound during processing as the quadrille obtained from a configuration in which head 85 has been moved back, 301, raised, 302 or lowered 303, or turned on itself 304 or 305. The quadrilles can still be changed if one or both speakers are moved in x, y or z directions. The dimensions of the room 90 also have an influence on the sound detected by the microphones 86 and 87. By modifying the dimensions of the room, 90 becoming 203, the nature of the reflections of the sound emitted by the speakers 83 and 84 is modified. on the walls of the room. In room 90 and room 203, speakers and microphones have identical relative positions. As the wall perpendicular to the x axis of room 203 is smaller than that of room 90, the reflections are more numerous along the y axis in room 203 than in room 90. The quadrilles which are linked to the The nature of the acoustic wave detected, its power and its frequency, are therefore different from one room to another. By modifying the orientation of the speakers 83 and 84 or the microphones of the head, the angle of reception of the sound by the microphones of the head is modified. The shape of the received wave is therefore further modified.

It is noted that the further the head 85 is moved away from the speakers 83, 84, the more the squares obtained give a marked effect of depth. By placing the two speakers symmetrically on either side of the head in the cone of confusion, we get a feeling of envelopment and maximum immersion that would be difficult to obtain with other positions.

From all these sound recordings of different natures, we retain the particular or singular configurations which produce the quadrilles making the best listening effect in depth of the sound. If necessary, we can retain several quadrilles (corresponding to several configurations).

FIG. 4 represents in theory two particular sets of coefficients of one of the two filters obtained after the extraction phase described in FIG. 2. FIG. 4 illustrates a processing which is carried out on the filters to make them more efficient. . For this purpose, coefficients of raw filters are determined according to the intercorrelations seen above. Then, from these raw coefficients, the impulse response of these filters is established, by an inverse discrete Fourier transform. We therefore return here, for the calculation of the filters (not for their use), in the time domain. Such an impulse response is shown in Figure 4. The diagram for the HDD filter 91 gives the appearance of the impulse response. This impulse response makes it possible to deduce the corresponding lateral field. Note on this filter the presence of an amplitude corresponding to the direct field 92. This amplitude ADDM is the largest of the amplitudes. The direct field corresponds to the field which, from the sound source, travels the shortest way to the receiver. We also observe amplitudes of first reflections 93 which are still significant. Finally, diffuse field amplitudes 94 which are increasingly weak. The weaker ones do not play a large role in the processing of the sound because they are drowned in the measurement noise. The HDD impulse response 91 has a sampling period TE in relation to the pitch of the initial Fourier transform and to the initial temporal sampling of the signal.

The HDG 96 diagram gives the appearance of the impulse response of the cross field from an electrical signal of its right. Its appearance is very similar to that of the impulse response of HDD 91 because the two sets of coefficients were obtained from the same white noise. The amplitude of the direct field 97 which corresponds to the acoustic field directly received by the microphone is again the most important of the filter. The first reflections 98 give amplitudes which are significant and the weakest of the amplitudes of the diffuse field 99 are of little interest in the processing of the sound because they are embedded in the measurement noise. The sampling period is preferably the same as for HDD 91: it is worth TE, reference 100.

After having thus transformed the sets of coefficients HDD 91 and HDG 96 into a temporal form, the samples resulting from this transformation to modify these filters. At the end of this modification, the modified impulse responses in the frequency domain are retransposed, in order to obtain frequency coefficients of filters and then use the corresponding filters as conventional frequency filters. The part of the description which follows indicates how this modification is made to the impulse responses to give more color to the sounds thus subsequently filtered.

In the example, it can be seen that the direct field 92 of the HDD time filter 91 and the direct field 97 of the HDG 96 time filter are shifted in time by a duration TR, 101, called inter-aural duration. A first step is to readjust the filters in relation to each other by aligning the direct fields or by choosing a deviation TR appropriate to the desired sound environment. To vary or delete the duration TR, it is possible to introduce or remove null samples between the first significant sample, 92 or 97, and the original zero over the durations 102 or 103. This introduction or this removal results in spreading out more or less the sound in space.

A second step consists in normalizing the temporal filters of the impulse responses. We first look for the maxima of the impulse response fields. In the example, we seek the maximum of HDD 91 which corresponds to ADDM, 104, and we seek the maximum of HDG 96 which here corresponds to ADGM, 105. We then seek the maximum of these two maxima. The maximum found is reduced to one and the level of the other impulse components of the filters is normalized. In the case where the levels of the impulse components of the filters are too disparate, normalization by reducing a maximum to one is no longer possible because it would make the diffuse field of one of the filters 94 and 99 too large.

Normalization by the power of the impulse response from the quadratic mean can then be envisaged by applying an identical window to the entire filter, and by calculating its power. We then compensate the levels to obtain identical power on the four window filters.

To produce certain sound effects, time masks can also be applied to the impulse responses of the HDD 91 and HGD 96 filters. For example, we can from HDD 91 extract only the direct field and deduce a frequency filter determined solely from of this direct field. This frequency filter is then applied to the electrical signal 13. It is also possible to apply a rectangular mask 195 which eliminates the coefficients whose rank is greater than a given rank, or else a mask ending in the form of an exponential 196 in order to modify a specific part of the filter.

A random alteration of the amplitudes of certain samples can also be carried out, always with the aim of creating a particular sound atmosphere.

It is also possible to eliminate certain samples whose amplitude is less than a threshold, for example L1 106 or L2 107. This threshold may correspond to the noise level. In fact, samples whose level is lower than the noise level do not have a great influence on the quality of the sound processing given by the filter.

It is also possible to delete certain samples, especially the weakest ones, by performing a truncation, so that the treatment can adapt to the device actually used to carry it out. Indeed, the size of the filter must be able to adapt to the industrialization constraint, for example to the size of the memory available in the processing system or even to the computing capacity of the processor. In practice, filters of sixteen kilo coefficients are used, each coefficient being quantized over sixty four bits. We thus have in the impulse response sixteen kilos samples, which can lead in the frequency domain to sixteen kilos coefficients. If the resources of the system are low, the number of coefficients can be reduced to four kilos or two kilos. Below these values the results of the treatment are always present but less well controlled.

For the processing of the original signal by filters with temporal coefficients, the coefficients of these temporal filters are first transposed in the frequency domain by means of discrete Fourier transform cells 111-114. The signal thus processed may however appear unacceptable and require additional equalization processing. Rather than performing such complementary equalization processing on the electrical signal of sound 13, the invention provides for incorporating equalization functions in cells located upstream from the Fourier transform cells 111-114. Equalization functions modify the coefficients of the filters in amplitude and in phase over all or part of the impulse response. We have discovered that phase control is a critical point in all filtering related to spatialization and depth of sound. For example, one can modify in phase and in amplitude the coefficients of the direct field and the first reflections while leaving the coefficients of the diffuse field unchanged.

The purpose of these equalization functions may be to improve the spectral rendering of a filter or a sound by correcting or compensating for certain defects which may be linked to the taking of sound. For example, a listener may want to increase the amplitudes of certain frequency components so as to bring out one color of sound more than another. For this purpose, the cells located upstream from cells 111-114 can be configured for some or all of the frequency ranges by weighting coefficients. In equalization, all the frequency components of the four filters can even be adjusted independently by providing for independently modifying the weighting coefficients of the cells. This independence gives the possibility of modifying all the characteristics of the amplitude and phase levels of the different filters. Rather than using cells upstream from 111-114 cells, it would be possible to incorporate equalization functions directly into 111-114 cells. It would also be possible to configure cell 110 or cells 7 and 8 by weighting coefficients. These alternatives are nevertheless more complicated and limiting than the use of independent cells making it possible to achieve equalization before the transposition of the coefficients of the filters in the frequency domain.

FIG. 5 represents by a functional block 600 a possible embodiment of the circuit which exploits the extracted filter coefficients. Signal processing is carried out by cutting the data to be processed into N data blocks which are multiplied by N packets of coefficients. In this case, we focus on the realization of HDD 78, with four packets of coefficients, here N being four. The filter coefficients of HDD78 are present in filter 1 of FIG. 1. They make it possible, from the signal applied at input 14, to obtain the electrical signal of its processed 15 at output. The coefficients of a filter, therefore of the HDD 78 filter, are sixteen kilos and are each defined on four bytes. With N being four, these coefficients are divided into four packets of coefficients of four kilo coefficients each. The input signal which is processed by HDD78 is an electrical sound signal cut into blocks of four kilos words. Each word represents a sample of data coded also on four bytes. In the assembly, four separate processing stages are produced which are combined by a summator 130.

In general, to process, the circuit of FIG. 5 performs a discrete Fourier transform of the data blocks, through a cell 110, of the signal 13 transmitted by a link 132 to a memory 109. A signal transposed in the frequency domain observable at output 136. This transposed signal is then multiplied by the filter coefficients of a filter.

The coefficients of this filter are contained in the example in four read only memories, HDD1 118, HDD2 119, HDD3 120 and HDD4 121. These coefficients are multiplied to the signal available at output 136 via operators. The multiplied signal obtained, in the example after the summator 130, is then transposed in time by an inverse discrete Fourier transform modeled in the example by cell 7 of FIG. 1.

To multiply the input signal by the filter coefficients, in the frequency domain, the electrical sound signal to be processed 13 is grouped into groups of two consecutive blocks in time. These groups of two transformed blocks are then transmitted to a delay line 400 at four outputs 136, 152, 163 and 180. The delay available at output 136 is zero. In practice, line 400 has only three delay cells 115, 116, 117. The transform of each of these groups of two blocks is carried out beforehand using the discrete Fourier transform circuit 110. The filter coefficients are split into N packets which correspond to the four packets of coefficients of example HDD1 118, HDD2 119, HDD3 120 and HDD4 121. These packets can be contained in read only memories, one could consider calculating them at the fly.

In order to control the phase of the electrical sound signal, the ^' coefficient packages used, HDD1 118, HDD2 119, HDD3 120 and HDD4 121 in the example are packets of finite impulse response filter coefficients. The number of coefficients of this type of filter is finite.

Like the N blocks of the input signal, the N packets of filter coefficients are transposed in the frequency domain by means of discrete Fourier transform cells 111-114. After transposition, the N blocks of the electrical input signal and the N packets of filter coefficients are multiplied two by two through multiplication operators 126-129 of the circuit of the example where N is four. Transposing the different signals to be processed in the frequency domain, the blocks of the input signal and the coefficients packets, has the effect of facilitating a convolution by transforming it into a simple multiplication in the frequency domain. This same convolution would have been difficult to calculate in the time domain and it would have required more system resources, especially more memory. The N results obtained are then added together by the summator 130. By doing so, the filtering has been broken down into N multiplications. It's easier.

The frame of the input signal divided into blocks and observable at the output of the cell 110, is transmitted to the delay line 400 with four outputs. Each of the cells 115-117 delays by a block of sample the signal which is applied to it as input. By doing so, the input frame is split into N blocks, four in the example that are observable at interconnection points 139, 154, 166 and 182. In addition, cells 115-117 avoid the superimposition of the results of convolution at the time the sum is made. This keeps processing consistent, while having divided the filter coefficients of HDD 78 into N packets.

The transform of signal 13 can be calculated on each of the signals observable on the N outputs of the delay line 400, by placing in the example discrete Fourier transform cells 500-503 on links 141, 156, 168, 182 We can also, and this is the preferred solution, calculate the Fourier transform for the entire frame by placing a discrete Fourier transform cell 110 upstream of the delay line.

To split the frame into blocks, an electrical input signal, 13 in the example, of capacity proportional to the N th of the frame is stored. In a preferred embodiment, double blocks which overlap one on top of the other by half, are formed by a memory 109 to split the input frame into N blocks. In the example, the capacity of the memory 109 which is here a buffer memory, is twice the size of a block of the electrical signal of its 13. The buffer memory of eight kilos words of four bytes is thus divided into two blocks of four kilos words each. This realization makes it possible to have successive groups (over time) of two blocks of data overlapped one on the other by fifty percent. The groups of data blocks at the output of the memory 109 therefore have a size of eight kilo words. By halving the size of the input buffer (eight kilos words instead of sixteen kilos words), and adapting an overlap, the circular buffer 109 reduces the latency of the processing. The latency time is the time that elapses between the entry into the processing system of the first sample to be processed and its actual processing by the system. This latency time is linked to the filling time of the input buffer. This processing technique introducing recovery of the samples therefore allows rapid processing of the input signals to be filtered. In the invention, a recovery with a rate of fifty percent is used, although this is not the only possible value. One could consider, for example, using an overlay of twenty-five or thirty-three percent. A Fourier transform of these double blocks is then carried out, as we have seen, via the discrete Fourier transform cell, 110 and via the link 135.

The N packets of filter coefficients: HDD1 118, HDD2 119, HDD3 120 and HDD4 121 in the example, are supplemented by constant samples using filling cells 122 to 125. In practice, the complement is carried out by null samples introduced by zero padding cells but one could introduce samples of constant value, not zero, in order to vary the effects to be produced on the original sound to be processed. We then obtain N double packets observable in the example at output 144, 157, 171 and 185 of cells 122-125 of the circuit of the example where N is four. Cells 122 - 125 are zero padding cells. These 122-125 cells are used so as to be able to multiply two signals although they are not the same size. The zero padding cells indeed complete with zero samples the signals which are applied to them as input until the latter reach a size allowing an operation to be carried out. Thus at the outputs of the stuffing cells, signals of eight kilos words are observed while the signals applied to the inputs 142, 153, 169 and 183 were only four kilos words long. This complement of samples is necessary so that the multiplication is physically achievable between the N double blocks of the input signal and the N packets of filter coefficients. Indeed, a multiplication is possible, only if the sizes of the sampled signals available on the different inputs of the multiplier are identical to each other.

The calculation with the double blocks covered and with the packets of coefficients packed with zero leads to a redundancy. It is advisable, taking into account this choice of treatment (one could have done otherwise), to extract the significant results. We extract from these double multiplied blocks, blocks multiplied using a matrix operation. This matrix operation is carried out in the example, through matrix cells 9 and 10 making a selection of a part of the incoming block so as to eliminate the redundancy of samples due to the use of a circular buffer memory which generates double processing of samples. The signal 13 is thus transformed into signal 15. This transformation corresponds to the HDD 78 filtering. To correspond to the other filters HDG 79, HGD 200 and HDG 2001, starting from the signals 13 and 17 (cf. FIG. 1), the assembly of the FIG. 5 comprises three other functional blocks 601, 602, 603 like the functional block 600 which has just been described. The same type of processing grouping together a signal combination, an inverse discrete Fourier transform, and a matrix operation is performed on the other signals 13 and 17 in order to simulate the paths of sounds in the air. Signal 16 is obtained in the example from a filtering carried out on signal 13. Signals 21 and 20 are obtained from two filterings carried out on signal 17 of filter 2. The three blocks 601 - 603 have a structure similar to that of block 600.

With the development of the process of the invention, N which is equal to four in the preferred embodiment, can be increased. In fact, the larger N, the smaller the size of the input buffer for a filter of given length. Therefore, the latency time decreases when N increases. In these conditions, we can consider processing in near real time the original sound signal (without depth). In particular, it is possible to envisage using the processing of sound signals of the invention for sounds corresponding to images transmitted live. The impulse responses of the filters and the input signal can also be divided into blocks of variable size. The smallest block defines the latency. It preferably corresponds to the start of the impulse response of the filter. For example, you can start by processing 128 time samples, then in the next step by processing 256, then 512 and so on, increasing the size until the end of the impulse response. More generally, for example, a first block of N points is processed, the rest of the processing is on 2N points, the continuation on 4N, etc. until the end of the answer. Other variants, more effective for real-time processing, are possible: N, N, 2N, 2N, 4N, 4N, etc. More generally when talking about blocks, although they are preferably of equal sizes they can be of unequal sizes. By having several simulation quadrilles, it is possible to provide users, in memories such as 118 to 121, complementary, with filters corresponding to other configurations. It is thus envisaged to make available to users about twenty different configurations (and associated filters). In addition, a user may want to combine the effects of more than one grid. In the invention, provision is then made to add the respective coefficients of two quadrilles (and to standardize the addition by a division by two) or of more than two quadrilles. The memories 118 to 121 are then loaded by the coefficients resulting from this combination.

FIG. 6a shows signals 601-615 obtained in an alternative embodiment of the filter 600 of FIG. 5.

Signals 601-615 are represented here in a time domain but, as will be seen below, all the calculations for processing the input signal 113 by the HDD filter 78 are performed in the frequency domain, using Fourier transform cells.

In this variant, the filter coefficients of the HDD filter 78 are divided into four time slots of variable length coefficients, ie here four slots HDD1-HDD4 of length M, 2M, 4M and 8M points. The number of temporal samples composing these slices is multiple of a power of two because the computation of the discrete Fourier transform is faster and simple to implement with such a number of samples. In practice, the HDD1-HDD4 slices of coefficients, successive in time, have an increasingly large length. The electrical signal 113 of its input sound is divided into blocks x1-x8 whose size is equal to that of the smallest coefficient slice, i.e. here the HDD1 slice which is of size M.

We then calculate a Fourier transform of the blocks x1-x8 and these HDD1-HDD4 slices of coefficients, using Fourier transform cells. We then obtain transformed blocks and transformed slices.

The signal HDD1-HDD8 slices are then convoluted by blocks x1-x8 of the same length as each of the slices. Thus, the first slice HDD1 which has a length of M samples or points is convoluted by the block x1 of length M samples or points, then by the blocks x2, x3, x4, x5, x6, x7 and x8. The second HDD2 tranche which has a length of 2M points is convolved by double blocks x1x2, x3x4, x5x6 and x7x8 of length 2M points. These convolutions are carried out in the frequency domain (circular convolution), by multiplication of the Fourier transforms of the blocks. By multiplying the transformed blocks by the transformed slices, we obtain multiplied blocks in this spirit. A multiplied block in the frequency domain corresponds to a convoluted block 601-615 in the time domain. The Fourier transforms are taken of double order of the length of the time blocks so that the circular convolution is identified with the linear convolution.

The multiplied blocks corresponding to the convoluted blocks 601-615 have a length twice as long as the lengths of the initial blocks.

The convolution of the blocks x1-xδ by the HDD1-HDD4 slices induces convolved blocks 601-615 which are shifted in time with respect to each other. Thus, for a convoluted block of a given size, its next is shifted in time.

For example, a convoluted block 609 of length 2P x M points, P being a positive integer (here P = 2), is delayed by a duration corresponding to (2 (P-1) -1 x M) points (here 1) relative to the start of the block. Thus, the transformed x1-x8 blocks are multiplied by the transformed HDD1-HDD4 slices of coefficients, so that the convoluted blocks 601-615 are aligned by overlap. See for this purpose, for example the overlap of the convoluted blocks 601 and 602 which partially overlap for the duration of the sample x2. Likewise 611, 610 and 606 overlap for the duration of the x6x7 samples.

The filter is considered to be a sum of four sub-filters associated with the time-delayed HDD1-HDD4 slices. It is then possible to deduce the overall impulse response of the HDD filter 78 by adding in frequency the various multiplied blocks which overlap then by carrying out the inverse Fourier transform of the sum.

In practice, to calculate a Fourier transform of order 2P x M, we keep in memory the Fourier transforms of order 2 (P-1) x M. Thus, with this process, once the transforms of the block x1 and the block x2 of length 2M points have been calculated, these transforms are combined in order to obtain the Fourier transform of x1x2 of length 4M points. In other words, instead of calculating a Fourier transform of length 4M points, only a complementary Fourier transform of length 2M points is calculated. This calculation method optimizes data processing times for long Fourier transform calculations. However, it is difficult to perform inverse operations to compute inverse Fourier transforms. Indeed, the recovery of multiplied blocks transposed in time leads to difficulties in identifying a part of a signal useful for reconstruction. By reconstruction is meant to transpose the blocks multiplied in time, and to recombine them so as to obtain an overall response from the filter. More precisely, during reconstruction, it is not possible to measure an offset between the multiplied blocks which lie in the frequency domain as it can be measured in the time domain. This complexity results in a loss of time in the calculations.

Thus in conventional reconstruction methods, to calculate an inverse discrete Fourier transform of a block of a given length, the inverse discrete transform of this block is directly calculated. On the other hand, in the invention, to calculate faster, we replace a inverse discrete Fourier transform of a given block of length, by a half-order inverse Fourier transform.

Over a given period, only a part of the multiplied blocks has an influence on the reconstruction of the output signal. Thus, for the convolved blocks corresponding to the multiplied block 612, 613 and 614 which overlap, only the part on which they overlap has a contribution over an interval delimited in time by the multiplied block transposed in time 612.

Also, in the invention, convoluted blocks are grouped, for example 613 and 614, of length 2P x M points in order to obtain a first block of length 2 (P-1) x M points (621, FIG. 6b) to be added. with another convoluted block of length 2 (P-1) x M points (620 figure 6b). With this grouping, we obtain a second block (623 Figure 6b) of length 2 (P- 1) x M points thanks to which we compensate for an error in time made on the calculation of the first block.

Thus, in the method according to the invention, a direct discrete transform of a given order can be replaced by a direct discrete Fourier transform of a half order. But one can also replace an inverse discrete Fourier transform of a given order by an inverse discrete Fourier transform of order half in order to carry out the reconstruction of the filter.

In the method according to the invention, it is therefore always possible to calculate direct discrete Fourier transforms and inverse discrete Fourier transforms on blocks having lengths half of those desired.

FIG. 6b gives an example of a temporal reconstruction of the output of the filter using the method according to the invention. More precisely, FIG. 6b shows an example of reconstruction for convoluted blocks of length 8M and 4M points. This figure is described in the context of the present invention relating to sound processing but can be the subject of independent protection taking into account that the technical effect of increasing the speed of calculations is thus obtained in all fields.

The segments of FIG. 6b, the ends of which are lines, correspond to signals which lie in the time domain. The segments whose ends are rectangles represent signals which are in the frequency domain.

For the reconstruction of the output signal of the HDD filter 78 in a time interval TR associated with block 612, a first time contribution comes from the convolved block 612 and a second time contribution comes from an overlap of the two convolved blocks 613 and 614 (see also Figure 6a). Indeed, in the time domain, the convolved blocks 613 and 614 are respectively made up of two halves a, b and c, d and overlap by half over the interval TR. The contribution of the convolved blocks 613 and 614 on the interval TR is thus of (b + c) In the reconstruction according to the invention, therefore, in the frequency domain, the multiplied blocks of length 2P x M points corresponding to blocks are combined convoluted overlapping by half, and one obtains a combined frequency block of length 2P x M points. We then divide this combined block into two blocks of length 2 (P-1) x M points and we only calculate the inverse transform of one of them, the other being simply added to a transform of order 2 ( P-1) x M resulting from the processing of time signal blocks of length 2 (P-2) x M points.

More precisely, we use the multiplied blocks 617 to 619 associated respectively with the convolved blocks 612, 613 and 614. We modulate the multiplied block 618 of size 8M which overlaps in time with block 614. To modulate, we multiply by minus one the odd components of the multiplied block 618 and by plus one the other components. We thus change the sign of all the odd components.

We then obtain a modulated block 620 of length 8M points. The frequency modulation is equivalent to permuting the two halves a and b of the convoluted block 613. This modulated block 620 is then added to block 619 with which it overlaps by half in time. A combined block 621 of length 8M points is then obtained. This block is representative of the time components b + c in its first part and a + d in its second part.

Then, a first sub-sampling is carried out in which the even components of the combined block 621 of length 8M points are selected. We then obtain an even block 622 of length 4M points which we multiply by 1/2 before adding it to block 617 which gives the compensation block 623. As the discrete Fourier transform is periodic, this addition in the frequency domain amounts to adding temporally the signal b + c + (d + a) over the interval TR.

In parallel, a second subsampling is carried out in which the odd components of the combined block 621 of size 8M are selected and an odd block 624 of length 4M points is obtained. An inverse transform of this odd block 624 is carried out and an inverted odd block 625 is obtained which is in the time domain. This inverted odd block 625 contains the signal ((b + c) - (d + a)) W (n), W (n) being a weighting factor represented by a sequence of 4M complex numbers. The signal ((b + c) - (d + a)) W (n) corresponds in fact to a signal ((b + c) - (d + a)) multiplied by a complex exponential.

We then multiply this inverted odd block 625 by the conjugate complex sequence of W (n) and divide the result obtained by 2. We obtain a normalized odd block 626 of length 4M points, which contains the real time signal 1/2 (( b + c) - (d + a)). This signal is added to the time output of the filter over the interval TR.

Compared to the real contribution (b + c) of blocks 613 and 614 on the interval TR, one thus introduced an error of 1/2 ((b + c) + (d + a)). But this error is exactly compensated by the combination of blocks 617 and 622, which replaces block 617 with the compensation block 623.

Thus, in the invention, we are reduced to an inverse discrete Fourier transform of order 2P x M to process an inverse discrete Fourier transform of order 2 (P + 1) x M. It is the same for all orders because there are several levels in the processing of blocks by tranches. This results in a considerable reduction in computation time.

In practice, we start by calculating the inverse discrete transforms of the longest multiplied blocks, ie the multiplied blocks of length 16M points for the example. In general, the calculations of the inverse transforms are carried out in a real-time architecture comprising independent processors which process each multiplied block. In addition, a counter system is used which makes it possible to determine at each instant how many multiplied signal blocks must be added for each time interval.

In another implementation of the method, a block frame is used comprising repetitions of blocks such as M, M, 2M, 2M, 4M, 4M, 8M, 8M for the example. This repetition of blocks makes it possible to better distribute the computational load of the processors so as to have a computation delay all the greater as the Fourier transforms are of high order.

As a variant, the coefficients of the HDD filter 78 are not divided into four slices. Indeed, the division of the coefficients of the HDD filter 78 into slices depends on a length of the impulse response of the HDD filter

78 and therefore of the number of filter coefficients of the HDD filter 78. Thus, in other exemplary embodiments, the filter coefficients of the filter

HDD 78 can be split into five or six different ranges of coefficients.

This method of reconstructing the output signal can be implemented in applications other than the processing of an electrical sound signal and can therefore constitute an invention in itself.

Figure 6c shows according to this variant an embodiment of the HDD filter with a structure on several floors. Filter coefficients

HDD of the example were cut into five slices of length M, 2M,

4M, 8M and 16M points. An input signal is cut into blocks of length M points.

On a stage A, a first step 631 performs a Fourier transformation of a multiplied block 630, of size 2P points, here 32 points.

Then in a second step 632, a modulation of the multiplied block is carried out by multiplying by -1 the negative components of the multiplied block. In a third step 633, the result of this modulation is added to an unmodulated multiplied block of size 32 points whose corresponding block over time overlaps with the block corresponding to the result of the multiplication over time. We get a combined block.

In a fourth and a fifth step 634 and 635 which are preferably carried out in parallel, the odd components and the even components of the combined block are isolated and an odd block and an even block are obtained respectively.

In a sixth step 636, an inverse discrete Fourier transformation of the odd block is carried out and the inverted odd block obtained is multiplied by the complex coefficient which is the conjugate of the complex number W (n). One multiplies the result of this multiplication by 1/2 and one then obtains a normalized odd block which one adds to the temporal output of the filter on the interval TR.

In a seventh step 637, the even block is added with an auxiliary block (617 FIG. 6b) multiplied by length 16 points whose corresponding block in time is aligned with the block corresponding to the even block in time. This auxiliary block is produced by a transformation of

Fourier 638 on 2 (P-1) points (here on 16 points).

The addition block obtained in the seventh step is removed and processed in a second stage B. More specifically, operations 631-637 are repeated in 639-643 on the addition block of length 16 points. In step 640 of stage B, the same multiplied block of size 16 is added which was added in step 637 of stage A. The odd normalized block obtained at the end of step 643 of stage B is also added to the reconstructed signal. A total of five stages is thus produced so as to add in a last step 645 a multiplied block of length 2 points to the last even block obtained.

In practice, steps such as 649, 650 and 651 can be performed at each useful moment of the method in which the blocks of signals corresponding to multiplied blocks are delayed and synchronized during the operations carried out using steps 633 and 645 .

In practice, each stage corresponds to a cell. A cell can correspond to an electronic circuit dedicated to particular functions. A cell can be produced from logic gates. As a variant, a cell corresponds to a program memory inside which instructions are stored associated with a microprocessor.

FIG. 7 shows an implementation of the method according to the invention for electrical sound signals coming from a car radio.

In this implementation, different delays t1-t4 are introduced into frequency bands of the right and left sound electrical signals processed 701 and 702 so as to center and focus an overall sound image obtained.

More specifically, an electrical signal of its right 113 and an electrical signal of its left 117 are processed by means of a filter 700 corresponding to that which includes the elements circumscribed inside the discontinuous lines in FIG. 1 as well as the summers 5 and 6. We obtain at the output of this filter 700 an electrical signal 701 of its processed right which can be observed at the output of the summator 5 and an electrical signal 702 of its processed left observable at the output of the summator 6 of FIG. 1. Then, for each signal 701 and 702 processed, the high frequency components and the low frequency components are filtered using a high pass filter 703 and a low pass filter 704. Thus, at the output of the high pass filter, for the electrical signal of its processed right 701, an electrical signal 705 of its high frequency is obtained. And at the output of the low pass filter, an electrical signal 706 of its low frequency is then obtained.

A first delay t1 is then introduced into the electrical signal 705 of its high frequency using a first delay cell 707.1. And a second delay t2 is introduced into the electrical signal 706 of its low frequency. At the output of the first delay cell 707.1, a delayed high frequency electrical signal 708 is then obtained. And, at the output of the second delay cell 707.2, an electrical signal 709 of its delayed low frequency is obtained.

The electrical signal 708 of its delayed high frequency and the electrical signal 709 of its delayed low frequency are then summed by means of an adder 710. The summed signal 711 obtained from the adder is then broadcast via a first loudspeaker 712. This first loudspeaker 712 comprises two sub-loudspeakers 713 and 714 which diffuse distinctly the high frequency sound signals and the low frequency sound signals. The filters 703 and 704, the cells 707.1 and 707.2 with delay and the adder 710 are elements of a first processing cell 715. A second cell 715 is applied to the electrical signal 702 of its processed left. The durations of the delays introduced by this second cell 715 can be identical or different from the durations of the delays t1 and t2 introduced by the first cell 715.

By combining the processing of the sound by the filter 700 and by introducing delays in the different frequency bands of the sound processed using the cells 715, one gives the sensation to a listener that the sound coming from the car speakers is at both high, centered with respect to the windshield. Sound from speakers also appears to be from a source sound located behind the windshield while this sound is simply broadcast by speakers that are located close to the ground. This feeling of elevation, centering and virtual provenance of a sound source can be obtained by combining the uses of the filter 700 and the cells 715. In a particular embodiment, the more the electric sound signals are broadcast by loudspeakers located the closer to a target, the longer the delays introduced into these signals. The further the electric sound signals are broadcast by loudspeakers located far from a target, the shorter the delays introduced into these signals. This target can be the driver or a passenger of the vehicle.

FIG. 7 gives an exemplary embodiment in which a delay is introduced into a high band of high frequency and a low band of frequency. These frequency bands each correspond to a frequency band of one of the sub-speakers that the broadcast speakers 712 and 714 comprise. However, for cars comprising speakers having more than two sub-speakers, delays can be introduced for any frequency band. Thus, certain cars equipped with a high-end audiophonic installation include loudspeakers which include three sub-loudspeakers diffusing respectively a high frequency sound signal, a medium frequency sound signal and a low frequency sound signal. For these speakers of these luxury cars, three filters are used inside the cell 715. In one example, these three filters correspond to a high pass filter, a band pass filter and a low pass filter . This method of introducing a delay in a frequency band of a sound signal can be implemented independently of the filter 700 and can therefore constitute an invention in itself.

Claims

1 - Process for processing an electrical sound signal in which the following steps are implemented:

- We process an electrical signal of his right (13) and an electrical signal of his left (17) to produce an electrical signal of his processed right (53) and an electrical signal of his processed left (62), characterized in that to treat

- we simulate (600) the production of a first electrical signal of its right processed (15) from the electrical signal of its straight (13), - we simulate (603) the production of a second electrical signal of its processed right (20) from the electrical signal of his left (17),

- we simulate (602) the production of a third electrical signal from its left treaty (21) from the electrical signal from its left (17),

- we simulate (601) the production of a fourth electrical signal from its left treaty (16) from the electrical signal from its right (13), and

- A sound (63, 64) corresponding to these four processed electrical sound signals is broadcast.

2 - Method according to claim 1, characterized in that, to simulate - there is produced (70) with an acoustic diffusion system (65), and from an electrical white noise signal (76), a sound signal white straight acoustic,

- We detect with an acoustic detector (68,69) a corresponding acoustic signal received, in the form of an electrical signal received white modified by its right and an electrical signal received white modified by its left corresponding to the reception of the signal acoustics of its white right,

a right frequency spectrum corresponding to a right white noise electrical signal is produced, and two received frequency spectra, respectively corresponding to the white received electrical signal modified by its right, and to the white received electrical signal modified by its left,

a first set of frequency filter coefficients is produced from the right frequency spectrum and from the frequency spectrum of the white electrical signal received modified by its right,

- a second set of frequency filter coefficients is produced from the right frequency spectrum and from the frequency spectrum of the signal electric receipt white modified from his left,

- producing (73) with an acoustic diffusion system (66) and from an electrical white noise signal (81), a white acoustic signal from the left, - detecting with an acoustic detector (68,69) a corresponding acoustic signal received, in the form of a white received electrical signal modified from its left and a white received electrical signal modified from its right corresponding to the reception of the white acoustic signal from its left. a left frequency spectrum corresponding to a left white electrical noise signal is produced, and two received frequency spectra, respectively corresponding to the white received electrical signal modified by its left and to the white received electrical signal modified by its right,

a third set of frequency filter coefficients is produced from the left frequency spectrum and from the frequency spectrum of the white electrical signal received modified from its left,

- a fourth set of frequency filter coefficients is produced from the left frequency spectrum and from the frequency spectrum of the white electrical signal received modified by its right, - these four sets of coefficients form a quadrille of sets of coefficients,

- And, to process, the electrical signals of its right and left are filtered with frequency filters whose parameters are given by this quadrille. 3 - Method according to claim 2, characterized in that

- the sets of coefficients are produced from two spectra by a complex division component to component of the complex points of these components in each of these spectra.

4 - Method according to one of claims 2 to 3, characterized in that, to diffuse

- coefficients of four time filters (91-99) are produced from the coefficients of the first, second, third and fourth frequency filters, respectively.

5 - Method according to claim 4, characterized in that - one modifies (195,196) the coefficients of the time filters by all or part of the following operations:

- normalization of the temporal filters of a quadrille, in maximum of direct field or in quadratic average of diffuse field,

- time registration (101) of the time filters with respect to each other,

- time shift of the samples of a time filter,

- masking of certain samples of the time filter (195, 196),

- alteration of the amplitudes of certain samples of a time filter. 6 - Method according to one of claims 4 to 5, characterized in that

- in the coefficients of a time filter, those whose rank is greater than a given rank are eliminated, and or

- in the coefficients of a time filter, those whose value is below a threshold are eliminated (106,107). 7 - Method according to one of claims 2 to 6, characterized in that

- We produce squares of sets of coefficients for different configurations (301-305) of the acoustic diffusion system and or for different rooms (90,203) in which the acoustic diffusion system (83-85) is placed for the production of the coefficients.

8 - Method according to claim 7, characterized in that

- one of the configurations is a cone of confusion configuration (88, 89).

9 - Method according to one of claims 1 to 8, characterized in that to diffuse

- the electric sound signals processed by the filters (26,31) are combined with the original untreated electric sound signals (13, 17),

- and you get an electrical signal from your right handset and an electrical signal from your left handset. 10 - Method according to claim 9, characterized in that to combine

- a time difference is introduced between the electrical acoustic signals processed by the filters and the original untreated electrical signals. 11 - Method according to one of claims 9 to 10 characterized in that than

- the right and left combined sound electrical signals are filtered on given frequency bands and,

- a delay is introduced on each of these frequency bands. 12 - Process according to claim 11 characterized in that

- the electrical signals from the right and left combined sound are filtered using a high-pass filter, and

- electrical signals of its high frequency are obtained,

- the right and left combined sound signals are filtered using a low pass filter and

- we get low frequency electrical signals

13 - Process according to claim 12 characterized in that

- a first delay is introduced into the electrical signals of its low frequency and - a second delay is introduced into the electrical signals of its high frequency.

14 - Process according to claim 13 characterized in that

- The first delay introduced into the electrical signal of its low frequency obtained from the electrical signal of its right handset is different from the first delay introduced into the electrical signal of its low frequency obtained from the electrical signal of its left handset.

- The second delay introduced into the electrical signal of its high frequency obtained from the electrical signal of its right handset is different from the second delay introduced into the electrical signal of its high frequency obtained from the electrical signal of its left handset.

15 - Method according to one of claims 1 to 14, characterized in that to filter

- a signal transform of an electrical sound signal is carried out and a transformed signal is obtained, - the transformed signal is multiplied by filter coefficients and a multiplied signal is obtained,

- the signal multiplied by an inverse transform is transformed,

- the filter coefficients are coefficients of filters with finite impulse response (118-121). 16 - Process according to claim 15, characterized in that for perform the transform

- we split a frame of the electrical sound signal into N blocks,

- the transform of each of the blocks is carried out,

- the filter coefficients are split into N packets of coefficients, - the N blocks of input data are multiplied two by two by the N packets of filter coefficients, and

- the multiplied blocks are added to obtain the multiplied signal.

17 - Method according to claim 16, characterized in that to split the frame and calculate the transform thereof - the transform of each of the N blocks is successively calculated, and

- the transformed blocks are transmitted to a delay line with N outputs.

18 - Method according to one of claims 16 to 17, characterized in that to split the frame into N blocks

- An electrical sound signal is stored in a circular buffer memory of capacity proportional to the nth of the frame of the electrical sound signal.

19 - Method according to one of claims 16 to 18, characterized in that

- to split a frame of the signal into N blocks, double blocks are formed which overlap one on the other by half,

- the transform of each of these double blocks is carried out,

- the N packets of coefficients are completed by constant samples to obtain double packets,

each of the N double blocks is multiplied by one of the N double packets and multiplied double blocks are obtained, and

- Multiplied blocks are extracted from multiplied double blocks.

20 - Method according to one of claims 1 to 19, characterized in that to simulate,

an artificial head is placed which includes the two acoustic detectors (68,69) in a median axis of two acoustic diffusion systems (65,66),

- an electrical signal in the form of a dirac comb is applied simultaneously to the input of the two acoustic diffusion systems,

- direct fields and crossed fields received by the acoustic detectors are aligned two by two by varying the position of the head artificial.

21 - Method according to one of claims 1 to 20, characterized in that to diffuse,

- Equalization functions are incorporated in cells located upstream of Fourier transform cells.

22 - Process according to claim 21, characterized in that

- the frequency components of the four frequency filters obtained from the four modified time filters are adjusted independently. 23 - Method according to one of claims 1 to 22 characterized in that to diffuse,

- the phase and / or the amplitude of the coefficients of the time filters (91-99) are modified over all or part of the impulse response.

24 - Process according to claim 15, characterized in that to carry out the transform

- the time filtering coefficients are split into Q slices (HDD1- HDD4) of coefficients of progressive length M, 2M, 4, ... (2 ^Λ (Q-1)) M points.

- the transformation of each of these slices is carried out and transformed slices are obtained,

- we split a frame of the electrical sound signal into blocks (x1-x8) of length M points,

- one performs the transform of each of these blocks and one obtains transformed blocks, - one multiplies the transformed blocks by the transformed slices and one obtains multiplied blocks corresponding by inverse transformation to blocks of signals which overlap two by two by half in time.

25 - Method according to claim 24 characterized in that to perform the reverse transformations of the multiplied blocks

- modulating (632) a first multiplied block (618), of length 2P x M points, a time block (613) corresponding in time to this first multiplied block, a second multiplied block corresponding in time to a second time block , this first and this second time block overlapping by half in time, and - we obtain a modulated block (620) of length 2P x M points, then

- we add (633) this modulated block of length 2P x M points to the second block, and

- a combined block (621) of length 2P x M points is obtained. 26 - Process according to claim 25 characterized in that to modulate

- the odd components of a multiplied block of length 2M points are multiplied by -1 whose block corresponding to it over time overlaps with another, and by +1 the even components. 27 - Method according to one of claims 25 to 26 characterized in that to perform the reverse transformations of the multiplied blocks of length 2M points

- we select (604) the even components of the combined block of length 2P x M points and - we obtain an even block of length 2 (P-1) x M points

- this even block is multiplied by 1/2 and we add (607) the result of this multiplication to an auxiliary multiplied block of length 2 (P-1) x M points and

- a compensation block (623) is obtained, 27 - Method according to one of claims 25 to 26 characterized in that to carry out the reverse transformations of the multiplied blocks of size (2P) M,

- we select (605) the odd components of the combined block of size 2P x M points and - we obtain an odd block (624) of length 2 (P-1) x M points,

- an inverse transform (606) of this odd block of length (2 (P-1)) M points is made and

- we obtain an inverted odd block (625) which is located in the time domain, then, - we multiply (606) this inverted odd block (625) by a complex coefficient conjugate with a complex coefficient W (n) and

- we obtain a normalized inverted odd block (626) of length 2 (P-1) x M points.