EP3355592A1 - Method for operating a binaural hearing aid system - Google Patents

Abstract

The invention specifies a method for operating a binaural hearing device system (2) with a first hearing device (4a) and a second hearing device (4b), wherein a first audio signal (18a) of the first hearing device (4a) is converted into a first radio-frequency component (HF1). and a first low frequency portion (NF1) is divided, wherein a second audio signal (18b) of the second hearing aid (4b) is divided into a second high frequency component (HF2) and a second low frequency component (NF2), wherein for the division the first audio signal (18a) in the first high-frequency component (HF1) and the first low-frequency component (NF1) a first provisional division frequency (tf1) is predetermined, wherein for the division of the second audio signal (18b) in the second high-frequency component (HF2) and the second low-frequency component (NF2), a second preliminary division frequency (tf2) is given, wherein a division frequency (tf) based on the first provisional division frequency (tf1) and the second and the first audio signal (18a) is divided at the division frequency (tf) into the first high-frequency component (HF1) and the first low-frequency component (NF1), and the second audio signal (18b ) is divided at the division frequency (tf) into the second high-frequency component (HF2) and the first low-frequency component (NF2).

Description

The invention relates to a method for operating a binaural hearing device system with a first hearing device and a second hearing device, wherein a first audio signal of the first hearing device is divided into a first high-frequency component and a first low-frequency component, and wherein a second audio signal of the second hearing aid in a second high-frequency component and a second low-frequency component is divided.

In a hearing aid, a sound signal of the environment is typically converted by means of an input transducer into an electrical signal, and processed in a signal processing unit according to the audiological requirements of the user and in particular amplified frequency-dependent. The processed signal is now converted by an output transducer into an output sound signal, which is fed to the user's ear. For improved spatial hearing and improved spatial resolution of the sound signals binaural hearing aid systems are often used with two hearing aids, of which the user carries one on each of the left and right ear. The hearing aids transmit mutually their input signals generated by the respective input transducers and / or further audio signals derived therefrom by signal processing and possibly additional control signals and generate from the local signals and the received signals the respective output signals for the local output transducers.

During operation of a hearing aid, coupling of the output sound signal into the input transducer may result in an acoustic feedback loop since the output sound signal again amplifies the signal processing experiences, which can lead to significant whistling or generally noise. The acoustic feedback is therefore usually suppressed by means of an internal electrical feedback loop in which a compensation signal is generated based on the amplified audio signal, for example in an adaptive filter, which is supplied to the input signal to compensate the acoustic feedback. In order to prevent that thereby strongly tonal signal components of the input signal are canceled, and there is the formation of artifacts in the output signal, while the amplified audio signal is often frequency-distorted before it is fed to the adaptive filter to decorrelate it from the input signal, a formation counteracts artifacts.

The EP 2 988 529 A1 for example, discloses a method for suppressing acoustic feedback in a hearing aid, adaptively determining a pitch frequency as a function of the acoustic feedback, and applying a frequency change only to the signal portions above the pitch frequency. On the one hand, the division frequency is chosen to be as high as possible in order to minimize the frequency range in which the hearing aid frequency-modulated signal is superimposed on the hearing aid with the non-frequency-changed direct sound, but on the other hand, at least the frequency range potentially critical for acoustic feedback to be changed.

In a binaural hearing aid system, an acoustic feedback loop may form for each of the two hearing aids. For the suppression of the feedback locally in each hearing aid, however, arise from the transmission of the individual signals between the two hearing aids and their mutual use for the generation of the output signals additional requirements.

Frequency distortions in binaural hearing aids are known to those skilled in the form of frequency transpositions from the US 2013/0 051 566 A1 known in the context of improving the spatial perception of an environment. However, the known findings on a suppression of acoustic feedbacks in binaural hearing aids due to the different objectives only very limited applicability.

The invention is therefore based on the object of specifying a method for operating a binaural hearing device system, which is to allow the suppression of acoustic feedback in the most natural spatial hearing.

The above object is achieved by a method for operating a binaural hearing aid system with a first hearing aid and a second hearing aid, wherein a first audio signal of the first hearing aid is divided into a first high-frequency component and a first low-frequency component, wherein a second audio signal of the second hearing aid is divided into a second high-frequency component and a second low-frequency component, wherein for the division of the first audio signal in the first high-frequency component and the first low-frequency component, a first provisional division frequency is predetermined, wherein for the division of the second audio signal a second provisional dividing frequency is set in the second high frequency portion and the second low frequency portion, wherein a dividing frequency is determined from the first preliminary dividing frequency and the second provisional dividing frequency, and wherein for suppressing the first audio signal at the division frequency is divided into the first high-frequency component and the first low-frequency component, and the second audio signal is divided at the division frequency into the second high-frequency component and the first low-frequency component. Advantageous and partly inventive in themselves embodiments are the subject of the dependent claims and the following description.

Preferably, the first audio signal is generated locally in the first hearing device and the second audio signal locally in the second hearing device. In particular, the first or the second audio signal can be given in each case by an intermediate signal in the signal processing process of the respective hearing device.

In a hearing aid for the suppression of acoustic feedback usually an intermediate signal is diverted from the main signal path and a dedicated feedback suppression device, such as an adaptive filter supplied, where based on the intermediate signal, a compensation signal is generated, which is fed back into the main signal path, so that in the main signal path Signal components, which are based on the acoustic feedback, should be extinguished as possible. The main signal path in this case comprises in particular an input signal which is generated by an input transducer of the hearing aid from a sound signal of the environment, the input signal comprehensive signal components which are supplied to the user-specific signal processing of the hearing aid, wherein the user-specific signal processing in particular frequency-dependent amplification and noise suppression includes a corresponding user-specific processed signal and an output signal derived therefrom, which is converted by an output transducer of the hearing aid into an output sound signal for the user.

The suppression of the feedback can lead to losses of sound quality, since on the one hand for particularly tonal and / or stationary useful signals, a distinction between a feedback-related whistles and a useful signal component in a frequency range relevant for feedback is difficult, which also signal components of the useful signal potentially from the extinction by the compensation signal may be affected. On the other hand, also stationary signal components of background noise can be audibly modulated, which can affect the hearing sense of a listening situation, even if the useful signal is not affected.

For the reasons mentioned, it is often attempted to limit the suppression of the feedback only to those frequency ranges in which a feedback is actually present or threatens to occur. These are, depending on the mechanical and electro-acoustic conditions of the hearing aid, usually medium to high frequencies from about 2 kHz, occasionally from 1 kHz. For this purpose, the compensation signal can be generated in such a way that it contains signal components only in the relevant frequency ranges. This can now be done in that the feedback suppression device divides the corresponding intermediate signal diverted from the main signal path into a high-frequency component and a low-frequency component at a division frequency, and only the high-frequency component is used to generate the compensation signal.

For the suppression of acoustic feedbacks in a binaural hearing aid system, a priori usually every local acoustic feedback path - ie in each case from the output transducer back to the input transducer of the same hearing aid - considered separately due to the strong attenuation of a crosswise feedback. Now, an acoustic feedback path changes locally, e.g. due to a change in the seat of the hearing aid in question as a result of jaw movements when the user speaks or the like, it is preferable to adjust the suppression of the feedback to the changed circumstances, which actually also means a change in the frequency range of the suppression with respect to the local auditory sense Division frequency includes.

However, a purely local determination of the respective division frequency, ie in particular only on the basis of the locally present acoustic feedback path from the respective output transducer back to the input transducer of the same hearing aid, lead to further problems in the hearing when updating the division frequencies. To suspend the user's hearing no unnatural-looking, sudden changes, updates of division frequencies usually with a certain continuous "cross-fading", so for example by shifting the division frequency to the new value out in a suitable time window to be selected. If, however, the target values for the respectively updated graduation frequency are different for the two hearing aids, this can surprisingly lead to sound sources being perceived as rotating around the user by the user, which results in a clear discrepancy due to the constant visual perception of his surroundings. This perceived mislocalization is mainly due to the variable group delay, ie the signal transit time over the Frequency caused, whereby the interaural time differences can be falsified.

In order to counteract such incorrectly perceived rotation of the sound sources, it is now proposed within the scope of the invention to first locally predetermine a value for a provisional division frequency in a first step, and in a second step the real division frequency at which both the first and also the second audio signal are to be divided into their respective high frequency and low frequency components, based on the two provisional division frequencies of the individual hearing aids to determine. In this way, both the requirements for local suppression of the feedback resulting from the two acoustic feedback paths, as well as the desire for the most realistic spatial hearing perception can be taken into account in an advantageous manner.

Expediently, a first frequency-distorted audio signal is used in each case for the first high-frequency component and the first low-frequency component, thereby generating a first frequency-distorted audio signal and one for the second high-frequency component and the second low-frequency component respectively for the second audio signal applied different second frequency distortion and generates a second frequency-distorted audio signal. By applying the first frequency distortion, the first high-frequency component and the first low-frequency component of the first audio signal are thus distorted, the distortion occurring for the first high-frequency component and the first low-frequency component to varying degrees. The same applies to the second frequency distortion with regard to the second high-frequency component and the second low-frequency component. In particular, in this case the first frequency distortion and the second frequency distortion each have an identical effect on the first audio signal and the second audio signal, ie the same frequency distortion is applied to the first high-frequency component as to the second high-frequency component, and to the first low-frequency component Share the same frequency distortion is applied as the second low-frequency component. In particular, by the first frequency distortion and the second frequency distortion only frequency-distorts the respective high-frequency component, while the respective low-frequency component of the relevant audio signal remains unchanged.

The application of frequency distortion to signal components, from which a compensation signal for suppressing acoustic feedback is to be generated, decorrelates the respective signal components from the corresponding signal components of the main signal path. Thus, it can be achieved that the compensation signal generated on the basis of the frequency-distorted signal components largely extinguishes only the acoustic feedback, but due to the decorrelation no further tonal signal components. For the application of frequency distortions in the suppression of acoustic feedback in a binaural hearing aid system, the proposed determination of the pitch frequency is therefore particularly advantageous.

Preferably, the first provisional dividing frequency is transmitted from the first hearing device to the second hearing device, wherein after receiving the first provisional dividing frequency, the second provisional dividing frequency is transmitted from the second hearing device to the first hearing device, and wherein in the first hearing device and in the second hearing device, the dividing frequency respectively after same predetermined rule based on the first provisional pitch frequency and the second provisional pitch frequency is determined. This means that both provisional dividing frequencies are present locally after the transmission processes mentioned in both hearing aids, and the final dividing frequency is determined on the basis of a rule identical for both hearing aids, which for example is stored in advance in a memory of each of the two hearing aids Both audio signals are to be divided respectively. In particular, further communication can take place for this purpose, for example communication requests for establishing a transmission channel for the provisional division frequency, confirmation of the reception of a provisional division frequency independently of the transmission of the value of the local provisional division frequency and / or synchronization requests for time synchronization, etc. The first is preferred provisional division frequency only after a detected change in local requirements, in particular of the first acoustic feedback path, transmitted to the second hearing aid, thus initiating the synchronization process. As a result, the effort and scope of required communication between the two hearing aids for the best possible determination of the division frequency can be significantly limited.

Conveniently, the division frequency is determined in each case on the basis of the minimum of the first provisional division frequency and the second provisional division frequency. In particular, the dividing frequency is hereby determined directly as the minimum of the first provisional dividing frequency and the second provisional dividing frequency, or as a minimum within a plurality of predetermined possible values for the dividing frequency, which in particular may form a discrete grid of possible values, e.g. Based on the lower of the two provisional division frequencies, the next-lower predetermined possible value is determined as the division frequency ("floor function"). By taking into account the minimum of the two provisional division frequencies, it can be achieved that the thus determined division frequency sufficiently takes into account the acoustic conditions in both hearing aids, and is not considered too high for a hearing aid. The selection on the basis of a plurality of predetermined possible values for the division frequency, in particular discrete values, makes it possible to take into account further boundary conditions.

In an advantageous embodiment of the invention, a first input signal is generated from a sound signal of the environment in the first hearing device by a first input transducer, wherein in the first hearing aid based on the first input signal by a first signal processing, the first audio signal is generated. In particular, a second input signal is generated from the sound signal in the second hearing device by a second input transducer, wherein the second audio signal is generated in the second hearing aid on the basis of the second input signal by a second signal processing. In a hearing aid, an input signal is generated from a sound signal of the environment on the basis of the input transducer, the signal components of which are usually subjected to user-specific signal processing The amplification factors in the individual frequency bands are usually determined as a function of a user's hearing loss to be corrected, for example on the basis of an audiogram. The frequency distortion of the audio signal resulting from the signal processing, and thus the proposed determination of the pitch frequency in a binaural hearing aid system, are particularly favorable, since this advantageously makes it possible to correct acoustic feedbacks.

Preferably, first output signal is generated on the basis of the first audio signal, which is converted by a first output transducer of the first hearing aid into a first output sound signal, wherein on the basis of the first frequency-distorted audio signal an acoustic feedback is suppressed via a first acoustic feedback path from the first output transducer to the first input transducer. In particular, the first output signal is generated based on the first frequency-distorted audio signal. In particular, based on the second audio signal, preferably based on the second frequency-distorted audio signal, a second output signal is generated, which is converted by a second output transducer of the second hearing aid in a second output sound signal, based on the second frequency-distorted audio signal acoustic feedback via a second acoustic feedback path from the second Output transducer is suppressed to the second input transducer. It is a common practice in hearing aids to use the audio signal resulting from this user-specific signal processing to suppress an acoustic feedback. Thus, the application of a frequency distortion to this audio signal in the context of the suppression of the acoustic feedback is expedient, and therefore in binaural hearing aid systems, the proposed method for determining the pitch frequency particularly advantageous.

Conveniently, the pitch frequency is updated in response to an external triggering event. As a triggering event here are preferably a change in the sound signal of the environment, a change in the first and / or in the second feedback path, a user input, resulting from a user input change in the first output signal and a modified classification of the hearing situation by the hearing aid or the binaural hearing aid system comprises. This ensures that the pitch frequency is always adjusted when the external conditions change, so the sound signal of the environment and / or in particular the first acoustic feedback path, so that the pitch frequency is always adapted to the currently existing conditions. However, if the external conditions, in particular the first acoustic feedback path, remain stable, then no adaptation is necessary, so that an update is omitted. As a result, battery power can be saved, since unnecessary updating operations, which would also be associated with transmission power for the transmission operations fail.

In a further advantageous embodiment of the invention, the pitch frequency is updated in response to an internal triggering event. In particular, the internal triggering event can be formed by a periodic encoder value, so that, for example, at regular intervals, the division frequency is temporarily set to a predetermined, preferably low value, particularly preferably the lowest possible value by a valid estimation for the respective feedback path even at low To get frequencies. Subsequently, the pitch frequency is updated again using the method described above.

The invention further mentions a binaural hearing aid system having a first hearing aid and a second hearing aid, wherein the binaural hearing aid system is configured to perform the method described above. The advantages stated for the method and for its further developments can be transferred analogously to the binaural hearing device system.

FIG.

1 in einem Blockschaltbild ein binaurales Hörgerätesystem mit zwei Hörgeräten und einem Protokoll zur Synchronisierung einer Teilungsfrequenz.

An embodiment of the invention will be explained in more detail with reference to a drawing. This shows schematically:

FIG.

1 is a block diagram of a binaural hearing aid system with two hearing aids and a protocol for synchronizing a division frequency.

In FIG. 1 a binaural hearing aid system 2 is shown in a block diagram. The binaural hearing aid system 2 comprises a first hearing aid 4a and a second hearing aid 4b. From a sound signal 6 of the environment, a first input signal 10a is generated in the first hearing device 4a by means of a first input transducer 8a, and a second input signal 10b is generated in the second hearing device 4b by means of a second input transducer 8b. The first input transducer 8a and the second input transducer 8b are given in the present case by a respective microphone. In both hearing aids 4a, 4b, the respective input signal 10a, 10b is then mixed with a first or second compensation signal 12a, 12b, respectively, and the resulting first or second compensated signal 14a, 14b is fed to first and second signal processing 16a, 16b, respectively. which in each case generates an intermediate signal, which is to be referred to here as first or second audio signal 18a, 18b. Based on the first and the second audio signal 18a, 18b, a first output signal 20a and a second output signal 20b is generated, which is converted by a first output transducer 22a and a second output transducer 22b respectively into a first and second output sound signal 24a, 24b. The first and second output transducers 22a, 22b are each provided by a loudspeaker. By coupling the first output sound signal 24a into the first input transducer 8a, a first acoustic feedback path 26a is formed, via which an acoustic feedback takes place. The same applies to the second acoustic feedback path 26b of the second output sound signal 24b to the second input transducer 8b.

In order to suppress the acoustic feedback via the first or second acoustic feedback path 26a, 26b, the first and second compensation signal 12a, 12b are now respectively generated in a first or second adaptive filter 28a, 28b. To the respective input variables of the first and the second adaptive filter 28a, 28b sufficiently from the first and second input signal 10a, 10b to decorrelate, the first audio signal 18a and the second audio signal 18b of a first frequency distortion 30a and a second frequency distortion 30b are subjected.

The first frequency distortion 30a, which is given here by a frequency shift by a constant amount, is hereby applied to the first audio signal 18a only above a pitch frequency tf, which the first audio signal 18a in a first high-frequency component HF1 and a first low-frequency component NF1 divides. The resulting first frequency-distorted audio signal 32a, which comprises the frequency-shifted first high-frequency component HF1 of the first audio signal 18a, is then fed on the one hand to the first adaptive filter 28a for generating the first compensation signal 12a, and on the other hand as the first output signal 20a to the first output transducer 22a. The same applies to the second frequency distortion 30b with respect to the pitch frequency tf and the resulting second high-frequency or second low-frequency portion HF2, NF2.

In many cases, the respective compensation signal 12a, 12b is generated only in those frequency bands in which a suppression of the acoustic feedback is required at all. For improved, artifact-free suppression, the decorrelation is performed using the frequency distortion 30a, 30b over the entire frequency range in which the feedback is to be suppressed. That is, by determining the division frequency tf, not only the application range of the respective frequency distortion 30a, 30b is determined, but also the frequency range of the two compensation signals 12a, 12b and thus the field of application of the suppression of the acoustic feedback.

If, in one of the two acoustic feedback paths 26a, 26b, there is a physical change and thus a change in the transfer function, this change has an immediate effect on the corresponding correction of the feedback by the respective adaptive filter 28a, 28b. For this purpose, dividing frequencies would now be required in the two hearing aids 4a, 4b, in which case the each optimum division frequency - ie with the greatest possible suppression of the acoustic feedback with the least possible influence on the sound impression in the respective output sound signal 24a, 24b -in each case depends on the local circumstances, and thus actually two different division frequencies would be selected, then each locally in the hearing aid 4a, 4b to fade would be. This cross-fading with different division frequencies, however, can lead to an unfavorable hearing sensation in the user of the binaural hearing aid system 2 such that surrounding sound sources apparently change their position.

In order to counteract this auditory impression, a first provisional division frequency tf1 is first transmitted from the first hearing device 4a to the second hearing device 4b during a physical change of the first acoustic feedback path 26a. The second hearing aid 4b receives the first preliminary division frequency tf1 and in turn determines, based on the second acoustic feedback path 26b, which could possibly also have changed slightly, a second preliminary division frequency tf2, which is transmitted to the first hearing aid 4a. If no change in the second acoustic feedback path 26b has taken place since the last update of the division frequency tf, then the current division frequency tf can also be transmitted as the value of the second provisional division frequency tf2.

Both hearing aids 4a, 4b now each have the first and the second provisional division frequency tf1, tf2. In order to achieve a uniform hearing sensation and nevertheless to ensure sufficient suppression of the feedback at both hearing aids 4a, 4b, the minimum of the first provisional division frequency tf1 and the second provisional division frequency tf2 is now defined as the division frequency tf. The first audio signal 18a is then divided into a first high-frequency component HF1 and a first low-frequency component NF1 at the division frequency tf, the first high-frequency component HF1 being frequency-shifted and the first frequency-distorted audio signal 32a being the first adaptive filter 28a for the first adaptive filter 28a Generation of the first compensation signal 12a is supplied. The same applies to the second audio signal 18b and the second frequency-distorted audio signal 32b with respect to the same pitch frequency tf.

Although the invention has been illustrated and described in detail by the preferred embodiment, the invention is not limited by this embodiment. Other variations can be deduced therefrom by those skilled in the art without departing from the scope of the invention.

LIST OF REFERENCE NUMBERS

2

binaural hearing aid system

4a, 4b

first / second hearing aid

6

Sound signal of the environment

8a, 8b

first / second input converter

10a, 10b

first / second input signal

12a, 12b

first / second compensation signal

14a, 14b

first / second compensated signal

16a, 16b

first / second signal processing

18a, 18b

first / second audio signal

20a, 20b

first / second output signal

22a, 22b

first / second output transducer

24a, 24b

first / second output sound signal

26a, 26b

first / second acoustic feedback path

28a, 28b

first / second adaptive filter

30a, 30b

first / second frequency distortion

32a, 32b

first / second frequency-distorted audio signal

HF1, HF2

first / second high frequency component

NF1, NF2

first / second low-frequency component

tf

graduation frequency

tf1, tf2

first / second provisional pitch frequency

Claims (10)

Method for operating a binaural hearing device system (2) with a first hearing device (4a) and a second hearing device (4b),
wherein a first audio signal (18a) of the first hearing aid (4a) is divided into a first radio-frequency component (HF1) and a first low-frequency component (NF1),
wherein a second audio signal (18b) of the second hearing aid (4b) is divided into a second radio frequency component (HF2) and a second low-frequency component (NF2),
wherein for the division of the first audio signal (18a) into the first high-frequency component (HF1) and the first low-frequency component (NF1) a first provisional division frequency (tf1) is specified,
wherein for the division of the second audio signal (18b) into the second high-frequency component (HF2) and the second low-frequency component (NF2) a second provisional division frequency (tf2) is specified,
wherein a division frequency (tf) is determined based on the first preliminary division frequency (tf1) and the second provisional division frequency (tf2), and
wherein for suppressing an acoustic feedback, the first audio signal (18a) at the division frequency (tf) is divided into the first high frequency component (HF1) and the first low frequency component (NF1), and the second audio signal (18b) at the division frequency (tf) is divided into the second high-frequency component (HF2) and the first low-frequency component (NF2). Method according to claim 1,
wherein a first frequency distortion (30a) different in each case for the first high-frequency component (HF1) and the first low-frequency component (NF1) is applied to the first audio signal (18a), and thereby a first frequency-distorted audio signal (32a) is generated, and
wherein the second audio signal (18b) is one each for the second high-frequency component (HF2) and the second low-frequency component (NF2) second frequency distortion (30b) is applied, and from which a second frequency-distorted audio signal (32b) is generated. A method according to claim 1 or claim 2,
wherein the first preliminary division frequency (tf1) is transmitted from the first hearing device (4a) to the second hearing device (4b),
wherein after receiving the first preliminary division frequency (tf1), the second provisional division frequency (tf2) is transmitted from the second hearing aid (4b) to the first hearing aid (4a), and
wherein in the first hearing aid (4a) and in the second hearing aid (4b) the division frequency (tf) is determined according to the same predetermined rule on the basis of the first preliminary division frequency (tf1) and the second provisional division frequency (tf2). Method according to claim 3,
wherein the division frequency (tf) is determined based on the minimum of the first provisional division frequency (tf1) and the second provisional division frequency (tf2), respectively. Method according to one of the preceding claims,
wherein from a sound signal (6) of the environment in the first hearing aid (4a) by a first input transducer (8a), a first input signal (10a) is generated, and
wherein the first audio signal (18a) is generated in the first hearing device (4a) on the basis of the first input signal (8a) by a first signal processor (16a). Method according to claim 5,
wherein on the basis of the first audio signal (18a) a first output signal (20a) is generated, which is converted by a first output transducer (22a) of the first hearing aid (4a) into a first output sound signal (24a), and
wherein on the basis of the first frequency-distorted audio signal (32a) an acoustic Feedback via a first acoustic feedback path (26a) from the first output transducer (22a) to the first input transducer (8a) is suppressed. Method according to claim 6,
wherein upon an external triggering event, the division frequency (tf) is updated. Method according to claim 7,
wherein as external triggering event a change in the sound signal (6) of the environment, a change in the first feedback path and / or in the second feedback path (26a, 26b), a user input, a user input resulting change in the first output signal (24a) and a modified Classification of a hearing situation by the hearing aid (4a, 4b) or the binaural hearing aid system (2) are included. Method according to one of claims 6 to 8,
wherein upon an internal triggering event, the division frequency (tf) is updated. Binaural hearing aid system (2) with a first hearing aid (4a) and a second hearing aid (4b), wherein the binaural hearing aid system (2) is adapted to carry out the method according to one of the preceding claims.

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