EP1771038A2 - Method for operating a hearing-aid system for binaural treatment of a user - Google Patents

Abstract

The system has first and second hearing aids (1,1') for the left and right ears of the user, each with a microphone (2,2'), a signal processor (3,3'; 4,4') and an output transducer and an arrangement for transferring an audio signal between hearing aid. At least for a defined frequency range the acoustic output signal output by the earpiece (5,5') of the second hearing aid originates exclusively from the first audio signal and the acoustic output signal output by the earpiece of the first hearing aid originates exclusively from the second audio signal. An independent claim is also included for (A) an arrangement for implementing the inventive method (B) and a method of.

Description

The invention relates to a method for operating a hearing aid system with a first hearing aid device which can be worn on or in the left ear of a user and a second hearing aid device which can be worn on or in the right ear of the user, the hearing aid devices each having at least one microphone for receiving an acoustic input signal and converting it into a An audio signal, a signal processing device for processing an audio signal and an output transducer for converting a processed audio signal in a perceptible by the user as an acoustic signal and means for transmitting an audio signal from a respective hearing aid to the respective other hearing aid, at least for a certain frequency range of the microphone of the first hearing aid device, a first audio signal is generated and this first audio signal or a resulting audio signal is transmitted to the second hearing aid and after a sig Nalverarbeitung is output from the handset of the second hearing aid and at the same time from the microphone of the second hearing aid, a second audio signal is generated and this second audio signal or a resulting audio signal is transmitted to the first hearing aid and output after a signal processing by the listener of the first hearing aid.

In a hearing aid, an input signal is recorded by means of an input transducer and converted into an electrical input signal. Usually serves as an input transducer at least one microphone which receives an acoustic input signal. Modern hearing aids often comprise a microphone system with a plurality of microphones in order to achieve a direction dependent on the direction of arrival of acoustic signals reception, a directional characteristic. However, the input transducers may also include a telecoil or an antenna for Recording of electromagnetic input signals. The input signals converted by the input converter into electrical input signals (audio signals) are fed to a signal processing unit for further processing and amplification. The further processing and amplification takes place to compensate for the individual hearing loss of a hearing aid wearer, as a rule, as a function of the signal frequency. The signal processing unit generates an electrical output signal, which is fed via an output transducer to the hearing of the hearing aid wearer, so that the latter perceives the output signal as an acoustic signal. As output transducers usually listeners are used, which generate an acoustic output signal. However, output transducers for generating mechanical vibrations are also known, which directly excite certain parts of the ear, such as the ossicles, to vibrate. Furthermore, output transducers are known which directly stimulate neurons of the ear.

Due to the miniaturization aimed at in hearing aid devices, the microphone and the earpiece of a hearing aid device usually have only a small distance from one another. This promotes unwanted sound transmission directly from the listener to the microphone, often resulting in annoying feedback whistling (feedback). To solve this problem, there are a variety of different approaches, such as the use of notch filters, adaptive filters, directional microphones or extensive sealing of the ear canal. However, none of these measures has so far reliably and completely eliminated the occurrence of feedback whistling.

From the US 5,757,932 is a hearing aid system with a left ear and a right ear of a user portable hearing aid known. Between the hearing aids, a transmission of audio signals takes place. In both hearing aids, signals are thus processed which represent sound signals recorded at the two ears. Thereby Both ears of the user can be supplied with a binaural output signal.

From the EP 941014 A2 a hearing aid system is known in which a control signal is transmitted from one hearing aid to a second.

From the DE 10048354 A1 a hearing aid system with two hearing aids is known in which sound field characteristics are generated in each hearing aid and transmitted to the respective other hearing aid.

From the WO 00/00001 A2 a hearing aid system with two hearing aids is known, in which the signal processing in the two hearing aids is synchronized via a wireless connection between the hearing aids.

From the DE 10304648 B3 For example, a method for communication between hearing aids is known in which data packets of higher priority are transmitted first.

From the EP 0 941 014 A2 is a hearing aid device system with two head-worn hearing aids for binaural care of a user known. The hearing aids include means for wireless transmission of control signals and audio signals between the hearing aids. This makes it possible to process the audio signals obtained by means of the microphones in both hearing aids at least partially only in one of the two hearing aids. Signal processing resources therefore need not be equally provided in both hearing aids.

A disadvantage of known hearing aid devices is that the feedback problem has so far been solved only insufficient.

The object of the present invention is therefore to largely avoid feedback in a hearing aid device system for the binaural supply of a user.

This object is achieved by the method for operating a hearing aid device system according to claims 1, 4 and 5.

The basic idea of the invention is to separate the signal paths of the hearing aid devices which lead from a microphone via a signal processing unit to a receiver in a hearing aid device system with two hearing aid devices for the binaural supply of a hearing impaired person. An audio signal emanating from the microphone of the hearing aid worn on the left ear is transmitted to the hearing aid worn on the right ear and output by the listener of the hearing aid worn on the right ear. Likewise, an audio signal emitted by the microphone of the hearing aid worn on the right ear is transmitted to the left hearing aid and output by the listener of the left hearing aid. The distance between a microphone and a listener, with a feedback path between them, has been significantly increased. In terms of both the acoustic feedback path and the transmission of structure-borne sound between the listener in question and the microphone in question, essentially the head of the user determines the feedback path. Was in conventional hearing aids, the distance between a handset and a microphone, between which a feedback path is formed, in the range of millimeters to a few centimeters, so this distance increases in a hearing aid device system according to the invention to several decimeters.

The invention is advantageous above all in the case of a severe hearing loss, since it increasingly causes feedback due to the required high amplification. Furthermore, it is to be expected that in the case of the hearing aid system according to the invention, the severely hearing impaired, habituation takes place after a short time, so that the direction of an incoming sound signal is correctly interpreted again. The human brain seems to be adaptive in this regard. Namely, it is known that when seeing, the eyes caught Images are projected mirror-inverted onto the respective retina. Therefore, we would actually have to see all things "upside down". If one equips test persons with special glasses, which produce a mirror-inverted representation, then these subjects actually see first of all "upside down". Surprisingly, this impression disappears after a few days, so that everything is seen "normal" again. After prolonged wearing then occur when discontinuing the corresponding glasses again the same problems as at the beginning when wearing the glasses.

A similar effect to the one described in the field of vision also occurs during hearing, so that after a habituation phase the swapping of the signals is no longer perceived as disturbing. In particular, in the supply of severely hearing impaired, where feedback is a major problem and hardly hear anything without hearing aids, the habituation effect is not nullified again by the fact that temporarily no hearing aids are worn.

The locations in the signal paths of the hearing aid devices, at which the separation of the signal paths for signal transmission between the hearing aid devices takes place, can in principle be chosen almost arbitrarily. Thus, a "microfonn" separation can take place in which the audio signals emitted by the microphones are not or hardly further processed before they are transmitted crosswise between the hearing aids. Likewise, "separation close to the listener" can take place, in which the further processing of the audio signals generated by the microphones has already taken place, at least substantially. This is well possible especially in digital hearing aid systems in which only numbers rows are transmitted between the hearing aids anyway and therefore the energy required for the signal transmission is almost independent of the degree of amplification of the audio signals. However, it should then be noted that in this at the end of the signal path signal transmission taking place in the worn on the left ear hearing aid signal processing may need to be adapted to the hearing loss of the right ear and vice versa. Of course, the separation of the signal paths can in principle also take place at any point between the two extremes mentioned. An asymmetrical separation of the signal paths is possible, so that in a hearing aid, a signal at one point of the signal path is sent and sent to the other hearing aid when the signal processing is already substantially completed and the same hearing aid, the almost unprocessed audio signal of the other hearing aid for further processing receives. As a result, the signal processing is mainly concentrated on one of the two hearing aids of the hearing aid system.

The signal transmission between the hearing aids worn on the right and on the left ear preferably takes place wirelessly. This increases the wearing comfort of the hearing aid system according to the invention. However, a less convenient but less expensive wired audio signal transmission may be provided. Furthermore, the signal transmission is preferably carried out directly between the two worn on or in the ear hearing aids. However, signal transmission may also be via another device, e.g. an external processor unit carried on the body.

Preferably, the microphone signals emanating from the microphones are transmitted completely crosswise to the respective other hearing aid. However, it is also possible within the scope of the invention to transmit only certain frequency ranges of the audio signals between the hearing aid devices. Frequency ranges for which no problem with feedback is to be expected need not be transmitted. As a result, the amount of data to be transmitted between the hearing aids can be reduced.

In hearing aids, there is often a parallel processing of the audio signals generated by the microphones in several parallel frequency bands (channels). Can be advantageous In such hearing aids certain channels are transmitted crosswise between the hearing aids.

In a preferred development of the invention, only an over-cross transmission of audio signals between a hearing aid worn on or in the left ear and on or in the right ear of a user takes place when the occurrence of feedback has to be expected with high probability. This is especially the case when an acoustic input signal experiences a high gain. Furthermore, feedback often occurs when a high sound pressure level is generated by the listener of the hearing aid in question. Preferably, in a hearing aid device system according to the invention, the set gain or the generated sound pressure level is monitored, so that when certain threshold values are exceeded, an over-cross transmission according to the invention can take place automatically. The threshold values are advantageously adjustable by programming the hearing aid devices. In the case of further development, monitoring and cross-over transmission are preferably carried out in each case for specific frequency ranges or channels.

In a variant of the invention, the crosswise transmission of audio signals is limited to one or more specific listening programs. The cross-over transmission thus takes place only in the hearing programs for which this transmission is also explicitly, e.g. by programming the hearing aids, was provided. For example, when listening to music or watching television by consumer electronics devices usually no disadvantage associated with it, if the signal supplied to the right and the left ear are reversed. The invention can thereby be applied particularly advantageously in the listening situations "television" and "music", in which feedback occurs particularly frequently because of the large dynamic range of the acoustic input signals.

In another variant of the invention, the hearing aids each comprise a plurality of microphones for the formation of directional microphones with directional characteristics of different order. In particular, in such hearing aids simultaneously audio signals can be processed, which emerge from the directional microphones of different order. According to the invention, it is possible in such hearing aids to transmit the audio signals of microphones or microphone systems of a certain order crosswise between the hearing aid devices. For example, so only outgoing from omnidirectional microphones audio signals are transmitted crosswise between the hearing aids and outgoing from directional microphones of first or higher order audio signals in which feedback-induced whistling occurs less frequently, not transmitted.

In connection with the invention, a complete separation of the signal path between the microphone and the receiver preferably takes place at least for a certain frequency range. This means that no audio signal obtained from the microphone signal of the same hearing aid device is supplied to the listener of this hearing aid device for this frequency range. However, it is also possible within the scope of the invention not to completely separate the signal path. Although in this embodiment, an audio signal from the signal path of the first hearing aid is also tapped and transmitted to the second hearing aid of the hearing aid system, in parallel there is also a signal processing of the present at the tap audio signal in the first hearing aid and a signal output of the processed signal through the Handset of the first hearing aid. The signal processing is carried out in the context of the invention, however, such that feedback by this signal in the first hearing aid are likely to be excluded. The signal in question is therefore usually delivered by the second hearing aid device with a higher sound pressure level than from the first, when in both ears present in about the same hearing loss. Feedback can be excluded with high probability, if the so-called loop gain for a particular Hearing aid continuous signal even in the worst case, for example, even in a poorly fitting Otoplasik, always less than one. A threshold, which is an upper limit for the gain, is set accordingly.

• Figur 1 zeigt das Grundprinzip eines Hörhilfegerätesystems gemäß der Erfindung und
• Figur 2 zeigt ein Hörhilfegerätesystem mit einem Richtmikrofonsystem und paralleler Signalverarbeitung in mehreren Frequenzbändern.

The invention will be explained below with reference to exemplary embodiments:

• Figure 1 shows the basic principle of a hearing aid device system according to the invention and
• FIG. 2 shows a hearing aid system with a directional microphone system and parallel signal processing in several frequency bands.

The exemplary embodiment according to FIG. 1 shows a hearing device system 1, 1 'according to the invention with a left and a right hearing device 1 or 1'. Each of the hearing aids 1 or 1 'comprises a microphone 2 or 2', a first signal processing unit 3 or 3 ', a second signal processing unit 4 or 4' and a receiver 5 or 5 '. The first signal processing units 3 and 3 'are each connected to a transmitting coil 6 or 6' and the second signal processing units 4 and 4 'are each connected to a receiving coil 7 or 7'. There is a wireless signal transmission from the transmitting coil 6 of the left hearing aid 1 to the receiving coil 7 'of the right hearing aid 1' and from the transmitting coil 6 'of the right hearing aid 1' to the receiving coil 7 of the left hearing aid 1. By means of this arrangement, one of the Microphone 2 of the left ear portable hearing aid 1 recorded sound signal after the signal processing and amplification by the hearing aid system 1, 1 'supplied to the right ear of a user and simultaneously one of the microphone 2' of the hearing aid device 1 'worn on the right ear after the signal processing and amplification supplied by the hearing aid device system 1, 1 'to the left ear of the user. Feedbacks are due to the large distance of the microphone 2 or 2 'for receiving the acoustic Input signal from the handset 5 'and 5, which outputs the amplified microphone signal, largely avoided.

Of course, in contrast to the embodiment shown with separate transmitting coils 6 and 6 'and receiving coils 7 and 7' in each hearing aid a single coil or antenna may be present, which is suitable both for transmitting and for receiving signals.

The hearing aid device system according to FIG. 2 has two hearing aid devices 10 and 10 'of identical design. On the one hand, the audio signal emanating from the omnidirectional microphone 11 is fed directly to a filter bank 14 and, on the other hand, it is electrically connected to the omnidirectional microphone 12 to form a first-order directional microphone system. For this purpose, the audio signal originating from the omnidirectional microphone 12 is first delayed in a delay unit 13 and subtracted from the audio signal of the microphone 11. Also, the audio signal M2 of the first-order directional microphone thus formed is first supplied to the filter bank 15, in which the audio signals are split into a plurality of frequency bands. The parallel signal processing takes place in the signal processing blocks 16 and 17 of the signal processing unit 19. Preferably, the same cutoff frequencies are selected for the different frequency bands in both hearing aid devices.

According to the invention, for at least one frequency band, in the exemplary embodiment the band FBn, the signal path between the signal processing blocks 16 and 17 is interrupted. The listener 18 thus no signal component of the frequency band FBn of the audio signals M1 and M2 is supplied. Instead, this signal component is transmitted via the transmitting coil 21 and the receiving coil 22 'to the hearing aid device 10' and emitted by the hearing aid device 10 'via the earpiece 18'. Before the signal is output, there is preferably still a signal processing in the signal processing block 17 ', eg a gain. Parallel For this purpose, the audio signal in the frequency band FBn 'from the hearing aid 10' via the transmitting coil 21 'and the receiving coil 22 is transmitted to the hearing aid 10 and supplied to the listener 18 after signal processing in the signal processing block 17. The crosswise signal transmission described in this way can be carried out for one or more frequency bands that are particularly critical with regard to the feedback tendency. Preferably, the respective frequency bands are selectable, for example by programming the hearing aids.

In the mentioned variant of the invention, the signal paths of the hearing aid devices 10 and 10 'for the frequency bands FBn or FBn' are interrupted by the opened switches 23 and 23 'between the signal processing blocks 16 and 17 or 16' and 17 '. The output signal output by the receiver 18 thus contains no signal component originating from the microphone signals M1 and M2 in the frequency band FBn and the output signal output by the receiver 18 'contains no signal component in the frequency band FBn' originating from the microphone signals M1 'and M2'.

In another variant of the invention, the switches are missing 23 or 23 ', or they remain closed, at least in certain applications, even if an over-cross transmission of audio signals for the critical frequency bands FBn or FBn'. However, then for the signals in the respective frequency bands, the gain is adjusted so that feedback is excluded. Thus, while the ear is supplied with an output signal which comprises the entire transmittable bandwidth of an input signal detected by the microphones, however, in view of the gain required to compensate for the individual hearing loss of the hearing aid wearer for these frequency bands only in an attenuated form. The other ear, on the other hand, receives the transmitted signal in the volume required for that other ear.

In a further variant of the invention, it is provided that the two microphone signals M1 and M2 originating from directional microphone systems of different order are treated differently with regard to the signal transmission according to the invention. In particular, the microphone signals M1 and M1 'emanating from the two omnidirectional microphones 11 and 11' are advantageously transmitted crosswise to the respective other hearing aid device and the microphone signals M2 or M2 'which are less critical with respect to the feedback tendency are not transmitted to the respective other hearing aid device. This procedure has the advantage that the amount of data to be transmitted is reduced.

The signal processing in both hearing aid devices 10 and 10 'preferably takes place as a function of the hearing situation in which the hearing aid devices are located instantaneously. In this case, an automatic adjustment can take place, which is based, for example, on an analysis of the audio signals in the signal processing blocks 16 or 16 '. Furthermore, in the case of the hearing aid devices 10 and 10 'according to the exemplary embodiment, it is possible to manually switch between different hearing programs by means of the program selection buttons 20 or 20'. In a further development of the invention it is provided that the selection of the audio signals, e.g. M1, M1 'or M2, M2' or the selection of the one or more transmitted frequency bands as a function of the current hearing situation or the current hearing program. For example, Thus, in the listening situation "listening to music", an at least extensive crosswise transmission of the audio signals can take place, since in this hearing situation it is as a rule insignificant from which direction a sound signal seems to be incident into the hearing aid system. In contrast to this, in a hearing situation "road traffic" can at least largely be dispensed with the crosswise transmission, whereby, however, an increased tendency to feedback of the relevant hearing aid device system is connected.

Furthermore, in a development of the invention, at least for a certain frequency range, the required Amplification of an existing audio signal or the sound pressure level of the output signal from the handset automatically estimated. If one of these values exceeds a predetermined threshold value, an over-cross transmission according to the invention automatically takes place; otherwise this will be omitted. This ensures that cross-transmission of audio only occurs when it appears necessary to avoid feedback.

Claims (14)

Method for operating a hearing aid system with a first hearing aid device (1; 10) which can be worn on or in the left ear of a user and a second hearing aid device (1 ';10') which can be worn on or in the right ear of the user, wherein the hearing aid devices (1, 1 ' 10, 10 ') each have at least one microphone (2, 2', 11, 11 ', 12, 12') for receiving an acoustic input signal and conversion into an audio signal, a signal processing device (3, 4, 3 ', 4'; 16, 17, 16 ', 17') for processing an audio signal and an output transducer (5, 5 '; 18, 18') for converting a processed audio signal into a signal perceivable by the user as an acoustic signal, and means (6, 7; 6 ', 7', 21, 22, 21 ', 22') for transmitting an audio signal from one hearing aid device (1, 1 ', 10, 10') to the other hearing aid device (1, 1 ', 10, 10', respectively). ), wherein at least for a certain frequency range of the microphone (2; 11, 12) of the first hearing aid device (1; 10) a first audio signal is generated and this first audio signal or a resulting audio signal to the second hearing aid device (1 '; 10 ') is transmitted and, after a signal processing by the handset (5', 18 ') of the second hearing aid (1', 10 ') as an acoustic output signal and simultaneously from the microphone (2', 11 ', 12') of the A second audio signal is generated on the second hearing aid device (1 ', 10') and this second audio signal or an audio signal resulting therefrom is transmitted to the first hearing aid device (1, 10) and after signal processing by the listener (5, 18) of the first hearing aid device (FIG. 1, 10) is output as an acoustic output signal, characterized in that at least for the particular frequency range the acoustic output signal emitted by the listener (5 ', 18') of the second hearing aid device (1 ', 10') emerges exclusively from the first audio signal, and the acoustic output signal emitted by the handset (5 ', 18') of the first hearing aid device (1, 10) emerges exclusively from the second audio signal. Method for operating a hearing aid system according to claim 1, wherein the signal path between the microphone (2; 11, 12) and the earpiece (5; 18) of the first hearing aid (1; 10) is interrupted with respect to the first audio signal. Method for operating a hearing aid system according to claim 1 or 2, wherein the signal path between the microphone (2 ', 11', 12 ') and the earpiece (5', 18 ') of the second hearing aid (1', 10 ') with respect to the second Audio signal is interrupted. Method for operating a hearing aid system with a first hearing aid device (1; 10) which can be worn on or in the left ear of a user and a second hearing aid device (1 ';10') which can be worn on or in the right ear of the user, wherein the hearing aid devices (1, 1 ' 10, 10 ') each have at least one microphone (2, 2', 11, 11 ', 12, 12') for receiving an acoustic input signal and conversion into an audio signal, a signal processing device (3, 4, 3 ', 4'; 16, 17, 16 ', 17') for processing an audio signal and an output transducer (5, 5 '; 18, 18') for converting a processed audio signal into a signal perceivable by the user as an acoustic signal, and means (6, 7; 6 ', 7', 21, 22, 21 ', 22') for transmitting an audio signal from one hearing aid device (1, 1 ', 10, 10') to the other hearing aid device (1, 1 ', 10, 10', respectively). ), wherein at least for a certain frequency range of the microphone (2; 11, 12) of the first hearing aid device (1; 10) a first audio signal is generated and this first audio signal or a resulting audio signal to the second hearing aid device (1 '; 10 ') is transmitted and, after a signal processing by the handset (5', 18 ') of the second hearing aid (1', 10 ') as an acoustic output signal and simultaneously from the microphone (2', 11 ', 12') of the A second audio signal is generated on the second hearing aid device (1 ', 10') and this second audio signal or an audio signal resulting therefrom is transmitted to the first hearing aid device (1, 10) and after signal processing by the earpiece (5, 18) of the first hearing aid device (1; 10) is output as an acoustic output signal, characterized in that at least for the particular frequency range emitted by the handset (5 ';18') of the second hearing aid (1 ';10') acoustic output signal from the first and the second In the second hearing aid (5 ', 18'), a gain is set with respect to the second audio signal that does not exceed a noncritical threshold with respect to the occurrence of feedback, and a higher gain with respect to the first audio signal than with the second audio signal becomes. Method for operating a hearing aid device system, in particular a hearing aid device system according to claim 4, with a first hearing aid device (1; 10) which can be worn on or in the left ear of a user and a second hearing aid device (1 ';10') which can be worn on or in the right ear of the user wherein the hearing aid devices (1, 1 ', 10, 10') each have at least one microphone (2, 2 ', 11, 11', 12, 12 ') for receiving an acoustic input signal and conversion into an audio signal, a signal processing device (3, 4, 3 ', 4', 16, 17, 16 ', 17') for processing an audio signal and an output transducer (5, 5 ', 18, 18') for converting a processed audio signal into an audio signal perceivable by the user Signal and means (6, 7, 6 ', 7', 21, 22, 21 ', 22') for transmitting an audio signal from one hearing aid device (1, 1 ', 10, 10') to the other hearing aid device (1 , 1 ', 10, 10'), wherein at least for a certain frequency range of the Microphone (2; 11, 12) of the first hearing aid device (1; 10), a first audio signal is generated and this first audio signal or an audio signal resulting therefrom is transmitted to the second hearing aid device (1 ', 10') and after signal processing by the listener (5 ', 18') of the second hearing aid device (1 '; 10 ') is output as an acoustic output signal and at the same time a second audio signal is generated by the microphone (2', 11 ', 12') of the second hearing aid device (1 ', 10') and this second audio signal or an audio signal resulting therefrom the first hearing aid (1; 10) is transmitted and after a signal processing by the handset (5; 18) of the first hearing aid (1; 10) is output as an acoustic output signal, characterized in that at least for the particular frequency range from the listener ( 5, 18) of the first hearing aid device (1, 10) resulting from the first and the second audio signal, wherein in the first hearing aid (5, 18) with respect to the first audio signal, a gain is set, with respect to the occurrence of feedback does not exceed the uncritical threshold, and a higher gain is set with respect to the second audio signal than with the first audio signal. A method of operating a hearing aid device according to one of claims 1 to 5, wherein the audio signals between the hearing aids (1, 1 ', 10, 10') are transmitted by wire. Method for operating a hearing aid system according to one of claims 1 to 5, wherein the audio signals between the hearing aids (1, 1 ', 10, 10') are transmitted wirelessly. Method for operating a hearing aid system according to one of claims 1 to 7, wherein the audio signal originating from the microphone (1; 11, 12) of one of the two hearing aids (1; 10) or the audio signal resulting therefrom is completely applied to the respective other hearing aid device (1 '; 10 ') is transmitted. Method for operating a hearing aid system according to one of claims 1 to 7, wherein in the microphone (1, 11, 12) of one of the two hearing aids (1; 10) outgoing audio signal or the resulting audio signal only a certain frequency range (FBn; FBn ' ) between the hearing aids (1, 1 ', 10, 10') is transmitted. Method for operating a hearing aid system according to one of claims 1 to 9, wherein at least for one frequency range (FBn) a compensation of a hearing loss of the user required amplification of the acoustic input signal by the relevant hearing aid (1; 10) is determined and depending on the determined gain the Signal transmission between the hearing aids is done. Method for operating a hearing aid system according to one of Claims 1 to 10, wherein the sound pressure level of an acoustic output signal generated by the relevant hearing aid device (1; 10) is determined for at least one frequency range (FBn) and the signal transmission between the hearing aid devices takes place as a function of the determined sound pressure level. Method for operating a hearing aid system according to claim 10 or 11, wherein threshold values for the amplification or the sound pressure level are set by programming the relevant hearing aid device (1; 10). A method of operating a hearing aid system according to any one of claims 1 to 12, wherein each hearing aid (10, 10 ') a plurality of microphones (11, 12, 11', 12 ') which are each interconnected to form a directional microphone, wherein of the directional microphones respectively directional microphone signals are generated with different directional characteristics and wherein only a directional microphone signal of a specific directional characteristic of a hearing aid (10) on the other hearing aid (10 ') is transmitted. Method for operating a hearing aid system according to one of claims 1 to 13, wherein the signal transmission between the hearing aid devices (1, 1 ', 10, 10') in response to an instantaneous hearing situation in which the hearing aid device is located, or in response to a set hearing program ,

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