EP3881565A1 - Method for operating an audio device - Google Patents

Abstract

The invention relates to a method for operating an audio device, in particular for carrying out a morphing process, wherein: audio output data are produced from audio input data containing at least one sample and/or containing at least one block of samples by means of at least one function stored in a data device; at least one parameter of the at least one function can be and/or is changed during operation of the audio device; at least one piece of update information of the at least one parameter, which update information indicates a state of change (12, 13) of the at least one parameter, is updated after a change has occurred; the audio output data are produced in dependence on the update information of the at least one parameter by means of the at least one changed or the at least one unchanged parameter of the at least one function.

Description

 DESCRIPTION

Method for operating an audio device

The invention relates to a method for operating an audio device of a motor vehicle, in particular for performing a morphing process, audio output data containing at least one sample and / or at least one block of samples being generated by means of at least one function stored in a data device, at least one parameter of which at least one function in the operation of the audio device can be changed and / or is changed.

Methods for operating audio devices are generally known from the prior art, for example for operating audio devices in motor vehicles. It is also known that audio output data, for example raw data or intermediate data, are used to generate audio output data, that is to say data which enable audio signals to be output, for example via loudspeakers in the interior of the motor vehicle. In this case, the audio device has, for example, a data device in which at least one function is stored which specifies how audio output data are to be generated from the audio input data. In other words, the at least one function contains at least one regulation by means of which audio output data can be generated from the audio input data.

Furthermore, it is known that the at least one function has at least one, in particular several, for example a multiplicity of parameters which can be changed and / or changed during operation of the audio device. Examples of such parameters can be the amplification / attenuation of individual frequencies or frequency ranges in the audio spectrum or a “gain function”. It is also possible that the sound distribution or the distribution of the individual signals from a large number of output devices, such as loudspeakers, is matched to one another or an existing tuning is changed. In principle, it is thus possible, by changing one or more of such parameters, to generate the audio output data based on the To influence audio input data in a targeted manner. The user of the audio devices can thereby adapt the generation of the audio output data to his preferences, in particular it is possible to make sound settings according to the wishes of the user.

The change in the parameters is preferably not carried out abruptly, but rather in accordance with a change function, in order to carry out the change in the parameters step by step or continuously and therefore more pleasant for the user, in particular to prevent distortions. Such a change in parameters is generally referred to as “morphing”. It is possible to change the parameter from an initial value to a target value.

In such a morphing process (change process), in which one or more parameters of the function are changed to a new target value, resources of the data device are used or used, in particular with regard to the available processor power. The data device, which is also used to generate the audio output data from the audio input data, is thus additionally burdened in a morphing process. In particular, when changing a complex sound module that has a large number of parameters or a plurality of functions with a large number of parameters, the required processor power can exceed the available processor power, so that the data device is (temporarily) overloaded.

On the one hand, this can lead to the morphing process not being completely completed with regard to individual (multiple) parameters. This can also lead to incorrectly generated audio output data, for example fragments, which can lead to unpleasant and disruptive noises, for example distortions, and are therefore perceived by the user of the audio devices as unpleasant.

Usually, the data device used to generate the audio output data and to carry out the morphing process is designed accordingly in order to keep sufficient resources available, so that such overloads or peaks in the resource requirement do not lead to an overload. Disadvantageously, this means that more powerful processors or several processors must be kept in the data device, which are not used in normal operation, but are only provided as security for such overload scenarios.

The invention is therefore based on the object of specifying a method for operating an audio device which, on the other hand, is more efficient, in particular overloading the data devices by morphing processes being avoided.

The object is achieved by a method for operating an audio device according to claim 1. Advantageous refinements are the subject of the dependent claims.

The invention is based on the knowledge that at least one update information of the at least one parameter indicating a change state of the at least one parameter is updated after the change has taken place, the audio output data depending on the update information of the at least one parameter by means of the at least one changed or the at least one unchanged parameter of the at least one function.

Accordingly, the invention is based on the fact that when one or more parameters of the at least one function are changed, for example as components of a so-called “sound module”, up-to-date information is provided which indicates the (current) change state of the parameter. Depending on the actuality information, a decision can be made as to whether the changed parameter is used to generate the audio output data from the audio input data by means of the function, or whether an unchanged parameter, i.e. ultimately the output value of the parameter of the function for generating the audio output data, is used. In other words, the essence of the invention is to be seen in the fact that a morphing process is or can be carried out in blocks, whereby distortions of the audio data which are to be changed by the morphing process can be prevented.

Accordingly, it is possible to gradually (or continuously) so that, in contrast to an abrupt change in the respective parameters from the initial value to the target value, no unpleasant (perceptible) change effects are generated, such as disturbing audible artifacts. Instead, the change from baseline to target can be smooth. The change can be interrupted, for example if there is not enough processor power available, so that the audio input data can be generated in real time in audio output data and this process cannot be impaired or even interrupted by the morphing process.

Accordingly, it can be decided according to the invention to use the unchanged parameter of the function in order to generate the audio output data and thus temporarily pause / interrupt the morphing process until sufficient processor power is available to continue the morphing process. In the context of this application, the term “interrupt” relates to a temporary pause or suspension of the morphing process, for example a pause for one or more blocks of the signal. This effectively prevents the execution of the morphing process or all morphing processes from simultaneously leading to an overload of the processor, which leads to an impairment of the generation of the audio output data. Signal artifacts or perceptible impairments of the output audio signal can thus be prevented, so that the user of the audio device does not perceive any disturbing noises when operating the audio devices.

As described above, the method according to the invention prevents distortions. Under certain circumstances, the application of the method can result in the duration of the morphing process being extended. For example, the duration of a morphing process can be extended by a few milliseconds, for example from 40 ms to 50 ms. However, such an extension is usually not noticeable to a user.

The term “audio output data” denotes audio data, in particular intermediate audio data, which can be provided after the change by means of the function, for example in order to subsequently, possibly after further change, to be output via at least one loudspeaker.

The at least one parameter of the at least one function can preferably be changed on the basis of a change function generated in the data device or another control device, in particular a morphing function. The change function or the morphing function specifies how the morphing process is carried out. For example, it is possible to change the parameter continuously or step by step from the initial value to the target value. The way in which the parameter is changed, for example linearly, exponentially or following any other function, is determined by the change function.

According to a particularly preferred embodiment of the method according to the invention, it can be provided that the up-to-date information of at least one parameter or at least one parameter block of parameters is updated. The morphing process can be carried out step by step or sample-wise. The step-by-step and sample-wise implementation of a morphing process is shown by way of example in FIG. 3. Several samples can be combined to form a so-called parameter sample block, which means that the at least one parameter sample block has several samples, that is, values of the parameter.

An exemplary sample-wise implementation of a morphing process is designated in FIG. 3 with a plurality of frames 21 being shown. Each frame can have a defined number of samples (N samples, seven in this example). When the morphing process is carried out on a sample basis, the value of the parameter for each sample (of the parameter sample block) is changed so that the parameter can have a defined value for each sample. For example, all N samples of a frame 21 can be combined to form a parameter sample block.

In addition, a step-by-step change of the parameter is shown in FIG. 3 with reference number 22. The parameter is constant over all samples of the same frame 21, the parameter being changed step by step for each frame 21. The actuality information can be changed or updated accordingly if the at least one parameter sample block has been changed to a defined part, in particular completely, by means of the change function. In other words, the current information can be updated depending on the change state of the parameter sample block. Accordingly, several samples can be combined to form a parameter sample block, whereby the individual values of the parameter, which the parameter sample block contains, can be changed one after the other using the change function in order to be changed from an initial value to a target value, for example with intermediate values being reached in the meantime.

The actuality information can then be updated when the parameter or the entire parameter sample block has been changed to a defined part, in particular completely. Accordingly, the parameter or the entire parameter sample block is used in a modified form in signal processing, in particular real-time audio signal processing, as soon as all samples of the parameter sample block are at the same level, i.e. have reached the target value or a defined intermediate value, for example, which is indicated by the current information. If the parameter sample block is incompletely updated, then only a few samples of the parameter sample block are updated or changed while other samples are still at the level of the initial value or an "older" intermediate value. The value of the previous parameter sample block, which was last changed by the actuality information, is, for example used with unchanged or intermediate samples.

Advantageously, it is not necessary to reserve or reserve additional memory space in order to store the last parameter sample block or the last changed value, since the same memory location in which the parameter sample block or the last value is stored can be used. In the event that only individual values of a parameter sample block have been completely changed and the remaining values have not been changed, the last valid value (of the last completely changed parameter sample block) is, as described above used until the change of the current parameter sample block is completed.

It is also possible to use the last modified (valid) samples of the parameter sample block, which is currently only partially changed, for the morphing process. In this case, the actuality information must include further information, for example index information of the last modified (valid) sample of the parameter sample block. The value of the last modified (valid) sample is used for the unchanged samples of the parameter sample block. In this embodiment, however, additional memory is used and the complexity of the morphing algorithm increases accordingly.

Thus, in the method according to the invention it can preferably be provided that the at least one changed parameter or the at least one changed parameter sample block of the function for generating the audio output data is used if the current information of the corresponding parameter sample block corresponds to a defined value, in particular the most current value. In this way, it can be decided on the basis of the current information whether the at least one changed sample or the at least one changed parameter sample block is used to generate the audio output data, or whether the parameter sample block does not have the most up-to-date current information and therefore another, in particular unchanged parameter sample block is used to generate the audio output data . The term “changed” or “unchanged” denotes the state before or after the (a) change using the change function, whereby of course several intermediate stages / intermediate values can be taken in a morphing process, so that the parameter sample block from an initial value taking one or several intermediate levels / intermediate values can be changed to a target value. The term “unchanged” is therefore also to be understood as the last intermediate value of a parameter sample block that was completely taken in, the term “unchanged” not necessarily denoting the initial value.

In this case, one of the intermediate values or the initial value can also be "unchanged" with regard to a subsequent intermediate value or the target value be designated or considered. Ultimately, the entire parameter sample block can advantageously be used to generate the audio output data if all samples / entries of the parameter sample block correspond to the defined value, in particular the most current value of the current information.

According to a further preferred embodiment of the method, it can be provided that the up-to-date information is based on a time, in particular the system time of the audio device. In the context of this application, “system time” is understood to mean that time which is carried out in a processor, for example the processor of the data device, preferably the processor time. By using the time, in particular the system time, as up-to-date information, it can be ensured that the parameters have a certain change state, or by specifying the up-to-date information, it can be determined at which process time which parameter sample block is in which change state. Accordingly, it can be decided whether the parameter sample block is “current” and can be used or whether it has been changed incompletely and thus cannot be used to generate the audio output data.

When carrying out the method according to the invention, the change in the at least one parameter of the at least one function preferably has a lower priority than the generation of the audio output data. As described above, the generation of the audio output data has the highest priority, since an impairment of the generation of the audio output data leads to audible sound artifacts or a direct absence of the audio signal that is output via the at least one output device. Thus, according to the invention, the change in the at least one parameter is prioritized lower so that the generation of the audio output data always has priority.

The generation of the audio output data can, for example, be carried out in real time and the change of the at least one parameter of the at least one function can be carried out in non-real time, in particular in “quasi real time”. The term “non-real time” refers to processes that are not performed in real time. The term “non-real time” thus refers to processes that have lower priority than real-time processes. This ensures that the generation of the audio output data is carried out in real time and that the audio output data are also available in real time. If processor power is available in addition to the generation of the audio output data, the at least one parameter can be changed in non-real time, in particular in quasi real time. For example, a morphing process can take place between the generation of two blocks of audio output data.

Accordingly, the change in the at least one parameter can be temporarily paused or suspended / interrupted by the generation of the audio output data, since the generation of the audio output data enjoys a higher priority. It can thus be ensured that, in contrast to an execution of the change of the at least one parameter in real time, which would entail a reservation of processor power, the change in non-real time does not make such a reservation necessary. This means that the processor performance that is freed up or free in real time can be used for other real time applications or calculations, for example for processing audio data or (especially in the area of mobile devices) a reduction in the clock frequency of the processor in order to save energy, in particular to save the energy source or to protect the device's battery. As a result, the data device can be dimensioned smaller, since the resources for executing morphing processes need not be kept available in real time. Instead, these processes are carried out in non-real-time, so that, for example, the processor is not overloaded, but instead the available processor power is used, for example between two real-time applications.

The function may also include a sound set with a variety of parameters. In the context of this application, a “sound set” is understood to mean a function which has a number of modules for generating audio output data from audio input data, for example the action on a number of frequencies in the signal spectrum. A change in the complete sound set therefore requires a high amount of calculation due to the changes in the individual functions and their parameters in accordance with the change function. Executing the morphing process in non-real-time ensures that sufficient processor power is available for the real-time applications, for example the generation of the audio output data, or the processor performance does not have to be dimensioned unnecessarily high in order to intercept peaks that can occur during the execution of the morphing process can. Instead, the modification of the parameters is carried out in non-real time, whereby the modification of the parameters can be interrupted by the real-time applications. Accordingly, several blocks of non-real-time applications may be necessary to completely change the parameters of the function from their initial value to the target value. Such a change, however, takes place in the range of milliseconds or seconds, and the function for generating the audio output data is always available for each completed (partial) change, the parameters depending on the actuality information, as described above, can be used. The function can therefore be used at any point in time in the real-time application to generate audio output data from the audio input data, the function used for the generation, in particular its parameters, being selected as a function of the actuality information.

The at least one parameter of the function can preferably be changed as a function of the load on a control device, in particular at least one processor, of the audio device. It can be taken into account to what extent the processor power of the control device is already being used, in particular to what extent it is being used by higher-priority applications. Depending on the extent to which the control device is currently busy, it can be decided to carry out the change in the parameter of the function or to suspend the change until corresponding resources are available. This can also prevent the processor from becoming overloaded, which can lead to the undesirable effects already described above.

The method according to the invention can preferably comprise the following steps: Generating a change function for at least one parameter of at least one function

 - Change, in particular block-by-block change, of the at least one parameter in non-real time

 Generation of audio output data from audio input data using the most recently changed parameter based on the actuality information of the parameter

Accordingly, a change function is first generated or provided to morph at least one parameter of at least one function, i.e. to change according to the change function. The at least one parameter, in particular the block of parameters, can subsequently be changed by means of the change function, the change of the at least one parameter sample block being carried out in non-real time. Subsequently, audio output data can be generated from audio input data using the most recently changed parameter sample block based on the current information of the parameter sample block.

In addition, the invention relates to audio devices, in particular for a motor vehicle, a control device being provided which is designed to carry out the method according to the invention as described above.

The invention further relates to a motor vehicle comprising an audio device according to the invention.

The invention is explained in more detail below on the basis of exemplary embodiments with reference to the figures. The figures are schematic representations and show:

1 shows a time sequence of the generation of the audio output data;

2 shows one in two change states according to a change function;

3 shows a time sequence for the generation of the audio output data. 1 shows three blocks 1, 2 and 3, which are plotted along a time axis 4. Three frames 23, 24 and 25 are shown as examples on the time axis 4. Blocks 1-3 describe the generation of audio output data from audio input data by means of a function or a sound set, comprising a large number of functions. The function can be, for example, a “gain function” or any other function by means of which audio output data are obtained from the audio input data. Of course, the specific selection of the function or an interaction of several functions depends on the specific settings of the audio device (not shown) that the user selects, so that depending on the (sound) settings made by the user (or automatically by the audio device) other sound sets or functions and their parameters can be selected.

Blocks 1 - 3 are processed in real time, i.e. the generation of the audio output data is given the highest priority, so that the generation of the audio output data can interrupt other, lower-priority applications or processes. By dividing the applications into real time and non-real time ("real time" and "non-real time"), it is possible to run processes that require processor power in addition to the generation of the audio output data without impairing the generation of the audio output data.

For example, there is a “window” between blocks 1 and 2 and between blocks 2 and 3, in which no audio output data has to be generated. Processor power is therefore free in this “window” or processor power can be made available in order to carry out other (lower-priority) processes. In this example, at the end of frames 23, 24, 25, after the real-time blocks 1, 2, 3, processor power is free to carry out non-real-time processes. Such another process can be, for example, a change process, in particular a morphing process, in which at least one parameter of the function by means of which the audio output data are generated can be changed. For the morphing process, blocks 5 and 6 are shown as examples, which also have a certain length along the time axis 4. As described above, the time period between blocks 1 and 2 or between blocks 2 and 3 defines a time window in the processor power for other processes Can be made available. Accordingly, morphing processes can be carried out in non-real time in this time window. Blocks 5 and 6 schematically represent parameter sample blocks.

However, if a morphing process, for example according to block 5, were to be carried out completely, this would exceed the existing time window and thus possibly impair the generation of the audio output data according to block 2. In this case, for example, an overload of the processor could occur if the sum of the processor power required exceeds the available processor power. Thus, the error-free or continuous generation of the audio output data in real time would no longer be ensured. Thus, distortions or other impairments of the audio output via at least one output device, for example a loudspeaker in the interior of a motor vehicle (not shown), could be perceptible to the user and thus impair the comfort of the user.

In order to avoid this, the morphing process of block 5 is carried out in non-real time, so that if block 5 cannot be processed in the time window available between blocks 1 and 2, block 2, that is to say the one running in real time Generation of the audio output data according to block 2, can be interrupted. This is represented by a hatched part 7 of block 5, since only part 8 of block 5 can be processed in the available time window, so that the morphing process is interrupted by the generation of the audio output data according to block 2 and part 7 of block 5 "Remains" and block 5 was therefore not completely changed.

As can also be seen from FIG. 1, the portion 7 of block 5 can be processed in frame 24 in the next available time window, namely between blocks 2 and 3 processed in real time and the corresponding parameter or parameter set of the function according to block 5 thus be completed in this time window. Since in the time window between block 2 and block 3, processor power is available for more than the change in part 7 of block 5, a further part 9 of the next block 6 can be processed in non-real time. Again, there is not enough time for that in non-real time running morphing process to fully implement block 6, so that the portion 10 of block 6 can in turn be processed in the time window following block 3.

After block 5 and block 6, in particular portions 7, 8, 9 and 10 are consequently only partially processed or processed as soon as the next block 2, 3 of audio output data has to be generated in real time and the corresponding function must therefore be available , the morphing process is interrupted or "frozen". The interruption of the morphing process or the freezing of the morphing process is explained below with reference to FIG. 2.

2 shows a diagram of a change function 11 of a parameter in two change states 12, 13 or in two so-called “frames”. The change function 11 determines how the parameter is to be changed in blocks (of course, several parameters are also possible) from an initial value 14 to a target value 15. The change function 11 can be chosen arbitrarily, the change function 11 shown being to be understood merely as an example. Within the first available time window (change status 12), the parameter can then be changed completely from the initial value 14 to an intermediate value 16. In the change state 13, the parameter according to the change function 11 cannot be changed completely from the intermediate value 16 to the target value 15, since, for example, a real-time application takes up the processor power, so that the parameter sample block cannot be changed completely. For example, only the first four samples in the parameter sample block are changed, the remaining four samples still remaining in the change state 12, that is to say that the last four samples have not yet been processed and their values are unchanged from the last frame. Accordingly, part 17 of the parameter sample block is in a changed form and part 18 of the parameter sample block is still in the change state 12. If the function based on the change state 13 were used to generate the audio output data, the incomplete change of the parameter sample block would lead to undesired sound effects. The line designated by reference number 19 represents the course of the morphing function in the change state 13, the Intermediate value 16 is kept constant. Of course it is also possible that the complete next parameter sample block is available unchanged. In this case, the last valid value can also be used.

In this case, as described above, the morphing process is frozen or interrupted, i.e. that instead of using the partially completed parameter sample block of the change state 13 for the generation of the audio output data by means of the function, the intermediate value 16 is used. The parameter is thus kept constant at the intermediate value 16 and used for the next block to generate the audio output data. Therefore, the process is also known as "freezing" the morphing process. As soon as in the next available time window, i.e. after the next real-time process has ended, processor power is again available for non-real-time use, the parameter sample block shown in change state 13, in particular part 18 of the parameter sample block, can also be changed in order to arrive at the target value 15. The parameter sample block can then be used to generate the audio output data. In other words, instead of using the partially modified parameter sample block for the generation of the audio output data, the parameter is kept constant at the intermediate value 16 and only after the parameter sample block has been completely changed in both parts 17, 18 is the parameter sample block used to generate the audio output data in blocks , ie the morphing process continues.

In order to decide whether the changed parameter sample block, for example in change state 13 or the “unchanged” parameter sample block, for example in change state 12, is to be used to generate the audio output data, each parameter sample block can carry current information that indicates the change state 12, 13 of the parameter sample block parameter sample block. In this case, the system time, that is to say a processor time, of the processor used, in particular the processor of the data device on which the processing of the audio output data or the morphing process is carried out, can be used as actual information. In this case, only when the morphing process has been completed, the entire parameter sample block for the present change state is the current system time entered in a location provided for this purpose, in particular a storage location, of the parameter sample block. This enables the system to identify the current status and how current the respective parameter sample block is. Only when each parameter in the parameter sample block has the current value of the system time or the most current value, can the parameter sample block be used to generate the audio output data. If this is not the case, the parameter sample block that is last to be designated or qualified as current, that is to say the one that last completed the morphing process, can be used to use its last parameter value.

The corresponding parameter value (cf. the intermediate value 16) is therefore used constantly for the subsequent block (cf. dashed line in change state 13). As soon as the subsequent parameter sample block has completed the morphing process, it is used to generate the audio output data. This process is repeated until the parameter has been changed (morphed) in blocks (or in samples) from the initial value 14 to the target value 15.

The morphing process can be carried out, in particular, depending on the available processor power, whereby, of course, the execution of the generation of the audio output data can always be given higher priority, namely in real time than the changing of the parameter or the execution of the morphing process, which is preferably carried out in Non-real time, especially in quasi real time.

Of course, instead of the block-wise morphing process described in relation to FIG. 2, a sample-wise morphing process can also be carried out. The audio device (not shown) on which the described method according to the invention is carried out can be particularly preferably arranged in a motor vehicle.

Claims

PAT EN TAN SPEECH

1. A method for operating an audio device, in particular for carrying out a morphing process, audio output data containing at least one sample and / or at least one block of samples being generated by means of at least one function stored in a data device, with at least one parameter of the at least one function in the Operation of the audio device is changeable and / or changed, characterized in that at least one update information indicating a change state (12, 13) of the at least one parameter of the at least one parameter is updated after the change has taken place, the audio output data depending on the current information of the at least one Parameters are generated by means of the at least one changed or the at least one unchanged parameter of the at least one function.

2. The method according to claim 1, characterized in that the at least one parameter of the at least one function is changed on the basis of a change function (11) generated in the data device or a control device, in particular a morphing function.

3. The method according to claim 2, characterized in that the

Actuality information of at least one parameter or at least one parameter sample block of parameters is updated if the parameter or the at least one parameter sample block has been changed to a defined part, in particular completely, by means of the change function.

4. The method according to any one of the preceding claims, characterized in that the at least one changed parameter or the at least one changed parameter sample block of the function for generating the audio output data is used if the current information of the corresponding parameter or parameter sample block corresponds to a defined value, in particular the most current value corresponds.

5. The method according to any one of the preceding claims, characterized in that the current information is based on a time, in particular the system time of the audio device.

6. The method according to any one of the preceding claims, characterized in that the change in the at least one parameter of the at least one function has a lower priority than the generation of the audio output data.

7. The method according to any one of the preceding claims, characterized in that the generation of the audio output data is carried out in real time and the change of the at least one parameter of the at least one function is carried out in non-real time, in particular in quasi real time.

8. The method according to any one of the preceding claims, characterized in that the function comprises a sound set with a variety of parameters.

9. The method according to any one of the preceding claims, characterized in that a change in the at least one parameter the function as a function of the load on a control device, in particular at least one processor, of the audio device.

10. The method according to any one of the preceding claims, characterized by the steps:

 Generating a change function (11) for at least one parameter of at least one function

 - Change, in particular block-by-block change, of the at least one parameter in non-real time

 Generation of audio output data from audio input data using the most recently changed parameter based on the actuality information of the parameter

1 1. Audio device, in particular for a motor vehicle, characterized by a control device which is designed to carry out the method according to one of the preceding claims.

12. Motor vehicle comprising an audio device according to claim 1 1.