EP4311270A1 - Method for operating a binaural hearing aid system and binaural hearing aid system - Google Patents

Abstract

The invention relates to a method for operating a binaural hearing aid system (6) and to such a hearing aid system (6), in which an acoustic audio signal (AS) is received which comes from an acoustic audio source (2), in which one from an electronic audio source ( 12) streamed electronic audio signal (ES) is received, which is based on the acoustic audio signal (AS) of the acoustic audio source (2), wherein at least in an acoustic operating mode the acoustic audio signal (AS) and the electronic audio signal (ES) are processed together and an output signal (S) with a directional effect is generated from both audio signals (AS, ES), the location of the acoustic audio source (2) being localized on the basis of the acoustic audio signal (AS) and the directional effect being generated. This creates good spatial hearing perception.

Description

The invention relates to a method for operating a binaural hearing aid system and such a binaural hearing aid system.

Binaural hearing aid systems regularly include two hearing aids, which are worn by a hearing aid wearer on the left ear and on the right ear and which exchange information with each other.

In the present case, hearing aids are understood to mean, in particular, hearing aid devices that are user-specifically configured to compensate for individual, user-specific hearing damage. Hearing aids and, in particular, hearing aid devices each fundamentally have a receiver for an audio signal, a signal processing unit for processing the received audio signal and for outputting a processed, electronic output signal, and a receiver through which the output signal is delivered to the hearing aid wearer. The output signal emitted is usually an acoustic output signal. The listener is typically an electroacoustic transducer (loudspeaker) that converts the electronic output signal of the signal processing unit into an acoustic output signal and delivers this to the hearing aid wearer.

Binaural hearing aid systems are used in particular to create a spatial effect for the hearing aid wearer, with the output signal containing a directional effect for directed hearing. This presents the hearing aid wearer with a hearing situation that is as realistic as possible, so that he can, for example, perceive an audio source with spatial resolution. This means that the Output signal is prepared in such a way that the hearing aid wearer generates an auditory perception in which the audio source is placed in a specific spatial direction.

The generation of the directional effect for directed hearing is basically known. Different techniques can be used for this. For example, time delays and/or level differences are inserted between the output signal delivered to the hearing aid wearer at the left ear and the output signal at the right ear. Additionally or alternatively, the phase relationships of the two output signals emitted are also changed. Furthermore, the electronic audio signals can be transformed using an approximate Head Related Transfer Function (HRTF).

To generate the directional effect, the received audio signals are first analyzed by the signal processing unit with regard to the location of the audio source, so that the location of the audio source is identified based on the received audio signals. Based on this information, the electronic output signal with the directional effect is then delivered to the listener.

The location information is regularly determined on the basis of received acoustic audio signals, for example based on time delays between two audio signals received on the left and right hearing aid.

From the EP 2 819 437 A1 a hearing aid system can be seen, which is designed to receive streamed, electronic audio signals. Based on these electronic audio signals, the electronic audio source is located and an output signal with a directional effect is generated based on the received electronic audio signal.

Based on this, the invention is based on the object of enabling improved hearing perception for a hearing aid wearer in a binaural hearing aid system.

• ein akustisches Audiosignal empfangen wird, welches von einer akustischen Audioquelle stammt,
• ein von einer elektronischen Audioquelle gestreamtes elektronisches Audiosignal empfangen wird, welches auf dem akustischen Audiosignal der akustischen Audioquelle beruht, wobei zumindest in einem akustischen Betriebsmodus
• das akustische Audiosignal und das elektronische Audiosignal gemeinsam verarbeitet werden und aus beiden Audiosignalen ein korreliertes Ausgangssignal mit einem Richtungseffekt für ein gerichtetes Hören erzeugt und an einen Hörer abgegeben wird, wobei
• auf Basis der akustischen Audiosignale der Ort der Audioquelle lokalisiert und der Richtungseffekt erzeugt wird.

The object is achieved according to the invention by a method for operating a binaural hearing aid system, in which

• an acoustic audio signal is received which comes from an acoustic audio source,
• an electronic audio signal streamed from an electronic audio source is received, which is based on the acoustic audio signal of the acoustic audio source, at least in an acoustic operating mode
• the acoustic audio signal and the electronic audio signal are processed together and a correlated output signal with a directional effect for directional hearing is generated from both audio signals and delivered to a listener, wherein
• based on the acoustic audio signals, the location of the audio source is localized and the directional effect is generated.

• einen akustischen Empfänger, insbesondere ein Mikrofon zum Empfang eines akustischen Audiosignals,
• einen elektronischen Empfänger für ein elektronisches, gestreamtes Audiosignal,
• eine Signalverarbeitungseinheit mit zumindest einem Prozessor zur Verarbeitung des akustischen sowie des elektronischen Audiosignals, wobei die Signalverarbeitungseinheit dafür ausgebildet ist zumindest in einem akustischen Betriebsmodus
  • o auf Basis der beiden Audiosignale ein Ausgangssignal mit einem Richtungseffekt zu erzeugen,
  • o wobei auf Basis der akustischen Audiosignale der Ort der Audioquelle lokalisiert und der Richtungseffekt erzeugt wird,

The binaural hearing aid system according to the invention is designed in particular to carry out this method and comprises two hearing aids, with a respective hearing aid having

• an acoustic receiver, in particular a microphone for receiving an acoustic audio signal,
• an electronic receiver for an electronic, streamed audio signal,
• a signal processing unit with at least one processor for processing the acoustic and the electronic audio signal, the signal processing unit being designed for this at least in an acoustic operating mode
  • o to generate an output signal with a directional effect based on the two audio signals,
  • o where the location of the audio source is localized and the directional effect is generated based on the acoustic audio signals,

To output the output signal with the directional effect, a receiver is typically provided, which usually receives the signal from the signal processing unit converts the received electronic output signal into an acoustic output signal.

Such a hearing aid system improves the hearing sensation in specific listening situations in which an acoustic audio source is present and at the same time the acoustic audio signal from this acoustic audio source is converted into an electronic audio signal and made available via a transmitter as a streamed electronic audio signal. Such listening situations occur regularly when audio signals typically have to be made available to a larger audience in order to enable both hearing aid wearers and non-hearing aid wearers to have the best possible hearing perception.

Such situations occur, for example, in a lecture hall, concert hall, museum, etc., where appropriate technical equipment is available for emitting a streamed audio signal.

An essential aspect of the invention is that at least in one operating mode, which is referred to herein as an acoustic operating mode, a correlated output signal is generated from the two received audio signals. In the present case, correlated output signal is generally understood to mean that both information from the acoustic audio signal and information from the electronic audio signal are processed and used to generate the output signal with the directional effect.

Furthermore, it is essential that in the selected acoustic operating mode the information about the location of the acoustic audio source is extracted from the acoustic audio signal and this directional information is used to generate the directional effect in the output signal for directional hearing.

This embodiment is based on the consideration that in the listening situations described above there is often the problem that the acoustic audio source as well the electronic audio source falls apart, i.e. is placed in different locations. In such a case, if the location of the electronic audio source were used for the directional effect, a false hearing perception would be created for the hearing aid user. At the same time, the acoustic audio signal is often overlaid with a large number of disturbing noises, so that signal processing based solely on the acoustic audio signal would lead to an output signal of inferior quality.

The special design described here with the correlated output signal ensures, on the one hand, good sound quality based on the electronic audio signal and, at the same time, the location of the audio source is reliably determined via the acoustic audio signal and used for directional listening.

To analyze the received audio signals, a respective hearing aid of the hearing aid system has a suitable electronic circuit unit, with the help of which the location of the respective audio source is determined from the received audio signals in a generally known manner.

For a mutual assignment of the acoustic and electronic audio signals, a correlation is preferably carried out mathematically: the electronic audio signal is correlated, for example, with all identified acoustic signal sources in the environment of the hearing aid wearer.

To generate the directional effect, a suitable electronic circuit is also designed in the signal processing unit, with the help of which the output signals are processed with the desired directional effect on the one hand for the left ear and on the other hand for the right ear. The signal processing unit is generally also a complex circuit for signal processing.

The advantages and preferred embodiments listed below with regard to the method can also be applied analogously to the hearing aid system and vice versa.

In a preferred embodiment, the acoustic audio signal is only used to determine the location of the audio source and to generate the directional effect. This means that the acoustic audio signal is only used to identify the location of the acoustic audio source.

In contrast, the acoustic audio signal is preferably not amplified and processed, in particular to compensate for individual hearing damage. For this purpose, (only) the electronic audio signal is processed accordingly, i.e. processed with the help of the signal processing unit on the basis of the user-specific, individual settings and in particular to compensate for individual hearing damage. For this purpose, in particular, a frequency-selective amplification is carried out corresponding to a previously individually determined hearing impairment of the hearing aid wearer. To generate the directional effect, the electronic audio signal prepared in this way is processed, taking into account the location of the audio source previously determined based on the acoustic audio signal, using the known measures for the two hearing aids, as mentioned at the beginning, in order to generate the desired directional effect. The parts of the signal processing that serve to compensate for the individual hearing loss are carried out in particular solely on the basis of the electronic audio signal.

In a preferred development, the electronic audio signal is further processed, for example, by one or more of the following measures:
An individual head-related transfer function of the hearing aid wearer is taken into account and included.

The (acoustic) properties of the hearing aid wearer's environment are simulated. For example, room acoustics are included in the processed electronic audio signal. For this purpose, in particular, a so-called impulse response of the room in which the acoustic audio source and/or the hearing aid wearer is located is determined and simulated. The acoustic audio signal is evaluated to determine the room acoustics, especially the impulse response. In this case, further information in addition to the location of the acoustic audio source is determined from the acoustic audio signal.

In general, the individual signal processing based on the individual hearing damage of the hearing aid wearer, i.e. the processing of the audio signal to compensate for the individual hearing damage, is generally carried out solely on the basis of the electronic audio signal.

In an expedient further development, the location of the respective audio source is determined both on the basis of the acoustic audio signal and on the basis of the electronic audio signal, i.e. on the one hand the location of the acoustic audio source and on the other hand the location of the electronic audio source.

In a preferred further development, it is finally checked whether the locations of the audio sources match or differ. By determining the location of the audio source twice, the listening situation can be analyzed and determined more precisely in order to create the most realistic possible hearing perception based on this information.

In the event that it is recognized during this test that the two locations are different, the acoustic audio signal is used to determine the location of the acoustic audio source and to generate the directional effect. Specifically, only the acoustic audio signal is used. In contrast, location information contained in the electronic audio signal is not taken into account. In this case, the acoustic operating mode is set.

In a preferred embodiment, it is further provided that in the case in which it is recognized during the test that the two locations match, the electronic audio signal is used to determine the location of the audio source and to generate the directional effect. Location information contained in the electronic audio signal is therefore used to generate the directional effect.

According to a first variant, the electronic audio signals are only used in addition, so that both the electronic audio signals and the acoustic audio signals are used to determine the location, whereby the most accurate possible spatial resolution is achieved.

According to a second variant, only the electronic audio signal is used to determine the location and to generate the directional effect. In this case, in which the location is determined exclusively on the basis of the electronic audio signal, a different operating mode is therefore set, which is hereinafter referred to as the electronic operating mode. In this operating mode, the acoustic audio signal is preferably completely ignored for the signal processing and is therefore not used for the signal processing and the generation of the output signal.

The electronic audio signal is generally a radio signal and preferably a Bluetooth signal. This is provided to the hearing aid system in particular via a so-called sidelink connection. The electronic audio signal is generated by a transmitter, also known as a streaming device, which is the electronic audio source.

An exemplary embodiment of the invention is shown in more detail below using the single figure. This shows a hearing aid situation with a speaker as the acoustic audio source and a hearing aid wearer with a binaural hearing aid system.

In the listening situation shown in the figure, a speaker, who represents an acoustic audio source 2, is located, for example, in a room, for example in a lecture hall or outside at a defined location.

Furthermore, a hearing aid wearer 4 is shown, who wears a binaural hearing aid system 6 with two hearing aids 8. The hearing aids 8 are designed, for example, as BTE hearing aids, ITE hearing aids, etc.

An acoustic audio signal AS is emitted by the acoustic audio source 2 and is received by both hearing aids 8.

Furthermore, a streaming device 10 is provided, which emits an electronic audio signal ES based on the acoustic audio signal AS emitted by the acoustic audio source 2. The streaming device 10 is therefore a transmitter for the electronic audio signal ES and thus simultaneously forms an electronic audio source 12. In the listening situation shown, the electronic audio source 12 is located away from the acoustic audio source 2.

The two hearing aids 8 are designed to receive the electronic audio signal ES.

The binaural hearing aid system 6 is designed to output an output signal S with a directional effect for directional hearing.

A respective hearing aid 8 has an acoustic receiver 14 for receiving the acoustic audio signal AS and an electronic receiver 16 for receiving the electronic audio signal ES. The acoustic receiver 14 is in particular a microphone. Furthermore, a respective hearing aid 8 comprises a signal processing unit 18. A respective receiver 14, 16 transmits an optionally processed audio signal to the signal processing unit 18. In the case of a microphone, the acoustic audio signal AS is converted into an electronic signal.

The signal processing unit 18 has a first circuit unit 20 for analyzing the received acoustic audio signal AS and a second circuit unit 22 for analyzing the received electronic audio signal ES. These two circuit units 20, 22 are designed to evaluate the respective audio signals AS, ES with regard to the location of the respective audio source 2, 12.

The signal processing unit 18 is further generally designed to generate a correlated electronic output signal S with a directional effect.

This output signal S is passed on to a receiver 24 of the hearing aid 8, which typically converts the electronic output signal S into an acoustic output signal.

To generate the directional effect, the signal processing unit 18 uses the location information contained in the acoustic audio signal AS in a first, acoustic operating mode, either alone or in addition. That is, the signal processing unit 18 generates the directional effect based on the location information about the acoustic audio source 2 contained in the acoustic audio signal AS.

The acoustic audio signal AS is preferably used exclusively to determine the location information. Further signal processing of the acoustic audio signal AS preferably does not take place, at least not in a listening situation in which the electronic, streamed audio signal ES is also available in parallel in addition to the acoustic audio signal AS.

The electronic audio signal ES is processed in a manner known per se by the signal processing unit 18 in accordance with the user-specific, individual settings. For this purpose, in particular, an individual, frequency-dependent amplification of the received electronic audio signal ES is carried out.

To generate the directional effect, the two output signals for the left hearing aid 8 and the right hearing aid 8 are then processed in a suitable, known manner based on the location information obtained from the acoustic audio signal AS, so that the directional effect is included.

The hearing aid wearer 4 therefore receives acoustic signals via the two hearing aids 8, which have the desired directional effect or generate them as an auditory perception for the hearing aid wearer 4.

In one embodiment variant, for example, it is provided that the signal processing unit 18 determines both the location of the acoustic audio source 2 and the location of the electronic audio source 12 and checks whether the two locations match. Depending on the test, different operating modes can be set. In particular, if the two locations fall apart, a so-called acoustic operating mode is set, in which the location information is obtained solely from the acoustic audio signals.

If the two audio sources 2, 12 match in location, a modified acoustic operating mode can be set, in which both the acoustic audio signal AS and the electronic audio signal ES are used to determine the location of the (acoustic) audio source.

In a further operating mode, which is referred to as an electronic operating mode, the location information - especially but not necessarily in the case that the two audio sources 2, 12 match - is taken solely from the electronic audio signal ES. In this operating mode, the acoustic audio signal AS is not used for signal processing.

Reference symbol list

2

acoustic audio source

4

Hearing aid wearers

6

binaural hearing aid system

8th

hearing aid

10

Streaming device

12

electronic audio source

14

acoustic receiver

16

electronic receiver

18

Signal processing unit

20

first circuit unit

22

second circuit unit

24

listener

AS

acoustic audio signal

IT

electronic audio signal

S

Output signal

Claims (10)

Method for operating a binaural hearing aid system (6), in which - an acoustic audio signal (AS) is received, which comes from an acoustic audio source (2). - an electronic audio signal (ES) streamed from an electronic audio source (12) is received, which is based on the acoustic audio signal (AS) of the acoustic audio source (2), characterized in that at least in an acoustic operating mode - the acoustic audio signal (AS) and the electronic audio signal (ES) are processed together and an output signal (S) with a directional effect is generated from both audio signals (AS, ES), and that - the location of the acoustic audio source (2) is localized based on the acoustic audio signal (AS) and the directional effect is generated. Method according to the preceding claim, characterized in that the acoustic audio signal (AS) is only used to determine the location of the acoustic audio source (2) and to generate the directional effect. Method according to one of the preceding claims, characterized in that signal processing to compensate for an individual hearing impairment of the hearing aid wearer is carried out solely on the basis of the electronic audio signal. Method according to one of the preceding claims, characterized in that a location of the respective audio source (2, 12) is determined both on the basis of the acoustic audio signal (AS) and on the basis of the electronic audio signal (ES). Method according to the preceding claim, characterized in that it is checked whether the locations of the audio sources (2, 12) match or differ. Method according to the preceding claim, characterized in that if the two locations fall apart, the acoustic audio signal (AS) is used to generate the directional effect. Method according to claim 5, characterized in that if the two locations match, the electronic audio signal (ES) is used at least additionally or solely to generate the directional effect. Method according to one of the preceding claims, characterized in that the electronic audio signal (ES) is a radio signal, in particular a Bluetooth signal. Binaural hearing aid system (6) with two hearing aids (8), in particular for carrying out the method according to one of the preceding claims, in which a respective hearing aid (8) has - an acoustic receiver (14) for an acoustic audio signal (AS), - an electronic receiver (16) for an electronic, streamed audio signal (ES), - a signal processing unit (18) for processing the acoustic audio signal (AS) and the electronic audio signal (ES), the signal processing unit (18) being designed for this purpose, o to generate an output signal (S) with a directional effect based on the two audio signals (AS, ES), o wherein in at least one acoustic operating mode the location of the acoustic audio source (2) is localized based on the acoustic audio signal (AS) and the directional effect is generated. Hearing aid system (6) according to the preceding claim, wherein the signal processing unit (18) is additionally designed to identify the location of the electronic audio source (12) based on the electronic audio signal (ES).

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