FR3093856A1 - Device for audio modification of an audio input signal, and corresponding method - Google Patents

Abstract

Device for audio modification of an audio input signal, and corresponding method The invention relates to a proposed device for audio modification (1), of an audio input signal (x) by an effect signal (z ), the audio modification device (1) comprising: - an input for receiving the audio input signal (x), - a processing means (4) of the effect signal configured to generate and supply the signal of effect (z), and - a convolution means (2) configured to convolve the audio input signal (x) with the effect signal (z), in order to obtain an audio output signal (y). In particular, the processing means (4) comprises a vibration sensor (6) supplying an audio effect signal (Z) and the processing means (4) is configured to generate the effect signal (z). from the audio effect signal (Z) supplied by the vibration sensor (6). The invention also relates to the corresponding method of audio modification of the audio input signal by an effect signal. Figure for the abstract: Fig. 1.

Description

Device for audio modification of an audio input signal, and corresponding method

The present invention relates to the field of audio processing of an input signal. In particular, the present invention relates to devices for modifying an audio input signal in order to provide desired audio effects.

It is known to modify an audio signal provided by an instrument in particular, in order to provide it with an additional sound effect, such as reverberation (in English: “reverb”) or repetitions and delays (in English: “delay”). .

Thus, document WO 2008/108968 describes a device, and the associated method, making it possible to create, on an input signal, an audio effect corresponding to the acoustics of a given place, for example a concert hall. deemed.

To this end, document WO 2008/108968 provides a set of impulse responses obtained in said given place, and convolves it with the audio input signal in order to obtain an output signal corresponding to what would be obtained in said given place.

However, such an implementation remains complex, in particular for obtaining the initial impulse responses.

There are also devices that allow the user to create the desired effects themselves to apply to the audio input signal. Such devices generally offer a plurality of parameters allowing the user to choose and adapt the desired effect to the input signal to which it will be applied.

Nevertheless, such devices remain long and tedious to adjust, in particular because of the number of parameters to be adjusted, and the precision of adjustment to be provided.

Among such devices, there are some that offer a button to press in order to adjust, in particular, a temporal parameter of the audio effect to be applied.

However, even for such a device, the adjustment proposed remains summary and is not entirely satisfactory for the user who must also adjust the other parameters in a conventional and tedious manner to obtain the desired effect.

The present invention aims to solve the various technical problems mentioned above. In particular, the present invention aims to provide a device for audio modification of an audio input signal which makes it possible to simply and intuitively adjust the various effect parameters to be applied to the audio input signal.

Thus, according to one aspect, there is provided a device for audio modification of an audio input signal by an effect signal, the audio modification device comprising:
- an input to receive the audio input signal,
- effect signal processing means configured to process and provide the effect signal, and
- a convolution means configured to convolve the audio input signal with the effect signal, in order to obtain an audio output signal.

In particular, the processing means comprises a vibration sensor providing an audio effect signal and the processing means is configured to process the effect signal from the audio effect signal provided by the vibration sensor.

Thus, thanks to the invention, it becomes easy and intuitive to create an effect signal to modify the audio input signal. More precisely, the effect signal is directly elaborated by the user using a vibration sensor which will provide the audio effect signal intended to be convolved with the audio input signal. The user can therefore easily choose the frequency, the repetition, and/or the variation in amplitude as a function of time of the audio effect by acting, in a corresponding manner, on the vibration sensor. The user will thus act to directly create the effect signal that he wishes to see applied to the audio input signal. The action of the user allowing the creation of the audio effect signal can in particular be manual.

In addition, the user will also be able to modify the effect signal applied to the audio input signal by specifically choosing the vibration sensor used to produce the audio effect signal.

The effect signal corresponds to the audio effect signal. In particular, the effect signal may thus be, at least in part, the audio effect signal provided by the vibration sensor.

Preferably, the vibration sensor is mounted on a structure capable of vibrating under the effect of an action, in particular manual action, of a user.

The user can thus choose the type of effect signal desired by choosing the structure likely to vibrate. It is then possible to experiment with different structures without being limited to a predefined choice.

Preferably, the processing means comprises triggering means receiving the audio effect signal as input, the triggering means being configured to make it possible to start, and possibly to stop, the processing of the effect signal from the audio effect signal.

The triggering means makes it possible to define the beginning, and possibly the end, of the audio effect signal which will be used to elaborate the effect signal. Thus, the triggering means is configured to delimit in time the audio effect signal used, so that the effect signal which will be convolved with the audio input signal also has a limited duration.

According to a first embodiment, the triggering means is configured to compare the amplitude of the audio effect signal to one or more determined values, and the triggering means is configured to make it possible to elaborate and supply the signal of effect from the audio effect signal when an amplitude of the audio effect signal is greater than or equal to a determined value.

In this embodiment, the triggering means can be configured to automatically trigger, and optionally automatically stop, based on the amplitude values of the audio effect signal. As soon as the audio effect signal exceeds a first determined threshold, this can automatically trigger the triggering means in order to use the audio effect signal to elaborate the effect signal.

Preferably, the triggering means is configured to make it possible to stop the generation of the effect signal from the audio effect signal when an amplitude of the audio effect signal is less than or equal to a determined value.

Thus, as soon as the audio effect signal returns below a second determined threshold, this can automatically stop the triggering means. We thus obtain, automatically, a portion of the audio effect signal which is automatically detected and used to elaborate the effect signal.

According to a second embodiment, the triggering means is configured to be triggered, and possibly stopped, by the user, for example manually.

In this embodiment, which may or may not be combined with the first, the triggering means is actuated or stopped directly by the user: when the latter wants to achieve an effect, he then actuates the triggering means and comes, for example, to manipulate the structure carrying the vibration sensor in order to create an audio effect signal which will be used to make the effect signal. Once the effect has been achieved, the user then stops the triggering means, which stops the portion of the audio effect signal used to make the effect signal.

It is obviously possible to combine the two embodiments, in particular by providing for an activation, by the user, of the triggering means which will allow the production of the effect signal when the audio effect signal exceeds a first determined threshold. , and which will stop the generation of the effect signal either when the audio effect signal has passed below a second determined threshold, or when the user has stopped the triggering means, or when a duration of acquisition chosen beforehand will be elapsed.

Preferably, the triggering means is configured to stop when a determined duration has elapsed since the triggering of the triggering means.

In this embodiment, which is compatible with automatic triggering when the audio effect signal exceeds a determined threshold, or with triggering, for example manual, by the user, the triggering means is configured to stop automatically after a specified period. The triggering means thus makes it possible to obtain a duration effect signal corresponding to the determined duration.

According to one embodiment, the audio input signal comprises several channels, for example two, and the audio output signal comprises the same number of channels, for example two. In such an embodiment, the modification device elaborates a single and same effect signal and convolves it on each of the channels of the audio input signal to obtain the different audio output channels.

According to another embodiment, the modification device comprises several convolution means, for example two, and as many elaboration means configured to each provide an effect signal. Each elaboration means is associated with a convolution means to provide it with an effect signal. The output signal comprises as many channels as there are convolution means, each of the channels of the output signal being obtained by convolution of the audio input signal with each of the effect signals.

In this embodiment, the modification device makes it possible to create an audio output signal having more channels than the audio input signal, by convolving the audio input signal with different effect signals, to obtain the different channels of the audio output signal. The modification device according to the invention thus makes it possible to create a stereo sound from a mono audio sound, by applying a different effect to the two vibration sensors of the device in order to obtain two different effect signals.

Preferably, the processing means is configured to supply a first effect signal when a first audio effect signal is supplied by the vibration sensor, and is configured to supply, after the first effect signal, a second effect signal when a second audio effect signal is output from the vibration sensor after the first audio effect signal.

The modification device is configured to operate in real time, i.e. the effect signal applied to the audio input signal can be modified at any time by coming to use the structure carrying the vibration sensor to create a new audio effect signal. To this end, the processing means is configured to replace the effect signal used before the reuse of the vibration sensor, with a new effect signal processed from the new audio effect signal obtained during the reuse of the vibration sensor. It is thus possible to modify freely and at any time, the effect applied to the audio input signal.

Preferably, the elaboration means also comprises a transition means receiving the second audio effect signal and configured to modify the first effect signal into the second effect signal immediately or gradually.

The transition means makes it possible to manage effect signal changes when a new audio effect signal is supplied by the vibration sensor. Thus, in order to limit the impact of the change in the effect signal, the transition means may provide for a gradual change in the effect signal between the old effect signal and the new. Conversely, change can also take place immediately.

Preferably, the convolution means is a digital convolution means. The audio effect signal provided by the vibration sensor is an analog signal, and the processing means comprises an analog/digital converter of the audio effect signal configured to convert the audio effect signal from the vibration sensor into a signal digital.

The processing means is configured in particular to process the effect signal in a format compatible with the convolution means, regardless of the format of the audio effect signal supplied by the vibration sensor. In the present case, the processing means may comprise an analog/digital converter in order to obtain a digital effect signal from the analog audio effect signal.

According to another aspect, there is also provided a method of audio modification of an input audio signal by an effect signal, the method comprising:
- a stage for supplying the input audio signal,
- a stage of elaboration and supply of the effect signal,
and
- a convolution step of the input audio signal with the effect signal, in order to obtain the output audio signal.

During the step of producing and supplying the effect signal, action is taken, in particular manually, to create vibrations forming an audio effect signal, and the effect signal is produced from the effect signal sound.

Preferably, one acts with a desired frequency, repetition and/or amplitude depending on the desired audio modification to be made to the input audio signal. More precisely, we act in such a way as to create the effect signal that we wish to see applied to the audio input signal.

Figure 1 is a schematic representation of a first embodiment of a modification device according to the present invention;

FIG. 2 is a flowchart of an example embodiment of the method according to the present invention; and

Figure 3 is a second embodiment of a modification device according to the present invention, in which the output signal comprises more channels than the input signal.

Figure 1 schematically illustrates an audio modification device 1, according to the present invention. The modification device 1 thus receives at input an audio input signal x , and supplies at output an audio output signal y . The audio output signal y is in particular obtained by convolution of the audio input signal x by an effect signal z .

The modification device 1 thus comprises a convolution means 2 receiving the audio input signal x and the effect signal z as input, and supplying the audio output signal y as output.

Furthermore, the modification device 1 comprises a means for generating the effect signal 4 making it possible to generate the effect signal z . For this purpose, the processing means 4 comprises a vibration sensor 6 configured to supply an audio effect signal Z from which the effect signal z is processed . In particular, the effect signal z can be, at least in part, the audio effect signal Z .

In order to provide the audio effect signal Z , the vibration sensor 6 can be mounted on any type of structure capable of vibrating (not shown). It can thus be a support holding a membrane by its periphery, or holding a cord by its two ends, or it can be a vibrating element such as a blade or a plate. The excitation of the membrane, of the cord, of the blade or of the plate then makes it possible to obtain, at the output of the vibration sensor, an audio effect signal Z .

The elaboration means 4 then supplies an effect signal z which corresponds to the audio effect signal Z. The user can therefore perform directly on the structure capable of vibrating, the effect to be applied to the input audio signal x .

However, and in order to adapt the audio effect signal Z to the convolution means 2 and/or in order to make the modification device 1 easier to use, the elaboration means 4 can comprise various additional means making it possible to get effect signal z from audio effect signal Z .

Thus, the processing means 4 can comprise a triggering means 8. The triggering means 8 makes it possible to delimit the portion of the audio effect signal Z which is used to form the effect signal z . The trigger means 8 can thus prevent an unintentional audio effect signal Z from modifying the effect signal z applied to the audio input signal x .

The trigger means 8 can thus be configured to be activated, and possibly stopped, directly by the user, for example manually. When enabled, it means that the user wants the effect applied to the vibration sensor to be used to form the effect signal z . The user thus directly delimits the beginning and the end of the effect applied to the vibration sensor, to be taken into account to modify the audio input signal x .

Alternatively, or in combination with the embodiment described above, the trigger means 8 can be configured to trigger, and possibly stop, the production of the effect signal z from the audio effect signal Z when this last exceeds a single determined first, and possibly falls below a second determined threshold. The trigger means 8 therefore makes it possible to choose when the audio effect signal Z can be used to form the effect signal Z .

Likewise, insofar as the effect signal z can be changed at any time by supplying a new audio effect signal Z , the elaboration means 4 can also comprise a transition means 10 configured to change the old effect signal z into the new effect signal z , suddenly or gradually. The transition means 10 can thus limit the impact on the output signal y of the change in the effect signal z .

It should be noted that the audio input signal x and the audio output signal y can be mono or stereo signals. In the second case, it is understood that the effect signal z is applied, in the same way, to each of the channels of the audio input signal x in order to form each of the channels of the audio output signal y .

Obviously, the elaboration means 4 can also comprise other elements (not shown) making it possible to elaborate the effect signal z from the audio effect signal Z . Thus, the processing means 4 can comprise an analog/digital converter, in particular for converting an analog audio effect signal Z into a digital signal that can be processed by the convolution means 2 and possibly the triggering means 8 and/or the transition medium 10.

It should also be noted that the different elements of the production means 4, in particular the trigger means 8 and the transition means 10 can be mounted in a different order from that shown in Figure 1.

FIG. 2 represents a flowchart of the implementation of the modification method according to the invention. Thus, in a first step 12, an audio input signal is supplied, then, in a second step 14, an audio effect signal is supplied. In particular, during step 14, action is taken, for example manually, to create vibrations forming an audio effect signal.

In a third step 16, an effect signal corresponding to the audio effect signal is produced, and it is convolved, in a fourth step 18, with the audio input signal, in order to obtain an audio output signal.

FIG. 3 represents a second embodiment of a modification device 1 according to the present invention. In this second embodiment, the audio input signal x is a mono signal, and the audio output signal is a stereo signal y , y' .

In order to form the stereo output signal, the modification device 1 comprises a second elaboration means 4', with a second vibration sensor 6', a second trigger means 8' and a second transition means 10', for provide a second effect signal z' . The modification device 1 also includes a second convolution means 2' configured to convolve the audio input signal x with the second effect signal z' .

By thus convolving the input signal x with two different effect signals z, z' , it is thus possible to obtain two different audio output signals y, y' which can be used as the two channels of a signal of stereo output.

Thus, thanks to the means of elaboration of the effect signal, it becomes easy and intuitive for the user to directly create the effect signal that he wishes to see applied to the audio input signal. He just needs to use the vibration sensor, for example with a structure likely to vibrate, and apply the desired rhythmic and/or melodic phrase to it, to see it applied to the audio input signal. He can also choose the type of vibration sensor and/or structure likely to vibrate to use, to modify its effects. Finally, the invention allows quick and simple modification of the audio input signal, which also allows modification in real time, with a change of the effect signal, when the user wishes, by providing a new audio effect signal.

Claims (10)

Device for audio modification (1) of an audio input signal ( x ) by an effect signal ( z ), the audio modification device (1) comprising:
- an input to receive the audio input signal ( x ),
- a means for producing the effect signal (4) configured to produce and supply the effect signal ( z ),
and
- a convolution means (2) configured to convolve the audio input signal ( x ) with the effect signal ( z ), in order to obtain an audio output signal ( y ),
characterized in that the elaboration means (4) comprises a vibration sensor (6) supplying an audio effect signal ( Z ) and in that the elaboration means (4) is configured to generate the signal of effect ( z ) from the audio effect signal ( Z ) supplied by the vibration sensor (4).
Modification device (1) according to Claim 1, in which the vibration sensor (6) is mounted on a structure capable of vibrating under the effect of an action, in particular manual, of a user.
Modification device (1) according to one of claims 1 or 2, in which the elaboration means (4) comprises a trigger means (8) receiving as input the audio effect signal ( Z ), the means of trigger (8) being configured to allow to start, and possibly to stop, the elaboration of the effect signal ( z ) from the audio effect signal ( Z ).
A modifier (1) according to claim 3, wherein the trigger means (8) is configured to compare the amplitude of the audio effect signal ( Z ) to one or more determined values, and wherein the trigger means (8) is configured to make it possible to construct and output the effect signal ( z ) from the audio effect signal ( Z ) when an amplitude of the audio effect signal ( Z ) is greater than or equal to a determined value.
A modifying device (1) according to claim 4, wherein the generating means (4) is configured to stop generating the effect signal ( z ) from the audio effect signal ( Z ) when a amplitude of the audio effect signal ( Z ) is less than or equal to a determined value, or when a determined time has elapsed since the triggering of the trigger means (8).
Modification device (1) according to claim 3, 4 or 5, in which the trigger means (8) is configured to be triggered by the user, for example manually, and to be stopped by the user, for example manually , or to stop when a determined time has elapsed since the triggering of the trigger means (8).
Modification device (1) according to one of claims 1 to 6, comprising several convolution means (2, 2 '), for example two, and as many elaboration means (4, 4') configured to each provide a effect signal ( z , z ' ), in which each elaboration means (4, 4') is associated with a convolution means (2, 2 ') to provide it with an effect signal ( z , z' ), in which the output signal ( y , y ' ) comprises as many channels as there are convolution means (2, 2'), each of the channels of the output signal ( y , y ' ) being obtained by convolution of the signal d 'audio input ( x ) with each of the effect signals ( z , z' ).
Modification device (1) according to one of claims 1 to 7, in which the processing means (4) is configured to provide a first effect signal (z ) when a first audio effect signal ( Z ) is supplied by the vibration sensor (6), and is configured to provide, after the first effect signal ( z ), a second effect signal ( z ) when a second audio effect signal ( Z ) is output from the vibration sensor (6) after the first audio effect signal ( z ).
A modifying device (1) according to claim 8, wherein the generating means (4) also comprises a transition means (10) receiving the second audio effect signal ( Z ) and configured to modify the first audio effect signal. effect ( z ) into the second effect signal ( z ) immediately or gradually.
A method of audio modifying an input audio signal ( x ) by an effect signal ( z ), the method comprising:
- a step (12) of supplying the input audio signal ( x ),
- a step (14, 16) of production and supply of the effect signal ( z ),
and
- a step (18) of convolution of the input audio signal ( x ) with the effect signal ( z ), in order to obtain an output audio signal ( y ),
characterized in that, during the step (14, 16) of generating and supplying the effect signal ( z ), one acts (14), in particular manually, to create vibrations forming an audio effect signal ( Z ), and developing (16) the effect signal ( z ) from the audio effect signal ( Z ).