EP2317779A2 - Hearing aid and method for feedback suppression with directional microphone - Google Patents

Abstract

The method involves attenuating sound signals fed back from a listener (37) of a hearing aid (30) to a directional microphone (33) by adaptation of the directional microphone in a preset frequency band. The frequency band is determined by an open-loop-gain measurement. The directional microphone is adapted by changing adaptation parameters to attenuate feedback signal components of white noise received from the directional microphone. The adaptation of the directional microphone is continued when attenuation exceeds a threshold value. Independent claims are also included for the following: (1) a method for operating a hearing aid (2) a hearing aid comprising an adaptation unit.

Description

Hearing aid and method for feedback suppression with a directional microphone

The invention relates to a method and a hearing device for the suppression or compensation of acoustic feedbacks with the aid of the directivity of an adaptive directional microphone.

A common problem with hearing aids is the feedback between the output of the hearing aid and the input, which is annoying as feedback whistles. FIG. 1 shows the principle of an acoustic feedback using the example of a hearing aid 1. The hearing aid 1 comprises a microphone 2, which receives an acoustic useful signal 10, converts it into an electrical microphone signal 11 and outputs it to a signal processing unit 3. In the signal processing unit 3, the microphone signal 11 is, among other things, processed and amplified and output as a receiver signal 12 to a receiver 4. In the receiver 4, the electrical receiver signal 12 is again converted into an acoustic output signal 13 and delivered to the eardrum 7 of a hearing aid wearer.

The problem now is that a part of the acoustic output signal 13 passes through an acoustic feedback path 14 to the input of the hearing device 1, where it is superimposed on the useful signal 10 and recorded as a sum signal from the microphone 2. With a suitable phase position and amplitude of the fed-back output signal, disturbing feedback whistling occurs. In particular, by an open hearing aid supply, the attenuation of the acoustic feedback is low, whereby the problem is exacerbated.

To solve the problem adaptive systems for feedback suppression have been available for some time. In this case, the acoustic feedback path 14 is digitally reproduced. The replication takes place, for example, by means of an adaptive compensation filter 5 which is driven by the listener Signal 12 is fed. After filtering in the compensation filter 5, a filtered compensation signal 15 is subtracted from the microphone signal 11. Ideally, the effect of the acoustic feedback path 14 is thereby canceled and there is a feedback-compensated input signal 16 of the signal processing unit 3.

For effective feedback suppression, adjustment of the filter coefficients of the adaptive compensation filter 5 is required. For this purpose, the input signal 16 of the signal processing unit 3 is evaluated by means of an analysis unit 6 and examined for possible feedback. The adaptation can cause artifacts, since 5 not optimal adaptive compensation filters 5 additional signal components are generated. In addition, in a not optimally adapted compensation filter 5, a feedback whistling may occur. In the EP 1 033 063 B1 such a hearing aid is disclosed, wherein two parallel adaptive compensation filters are used to improve the feedback suppression.

Directional microphone systems are one of the methods of noise suppression that has been established for years and demonstrably improve speech intelligibility in listening situations in which the useful signal and the interference signals come from different directions. In modern hearing aids, the directivity is generated by differential processing of two or more adjacent microphones with omnidirectional characteristics.

FIG. 2 shows a simplified block diagram of a directional microphone system 1st order with two microphones 21, 22 at a distance of about 10 to 15 mm. This results for sound signals coming from the front V an external delay of T2 between the first and the second microphone 21, 22, which corresponds for example to the distance of the microphones 21, 22 to each other. The signal R2 of the second microphone 22 is delayed by the time T1 in a delay unit 23, in the inverter 24 is inverted and added to the signal R1 of the first microphone 21 in the first adder 25. The sum results in the directional microphone signal RA, which can be supplied to a listener, for example via signal processing. The direction-dependent sensitivity arises essentially from a subtraction of the second microphone signal R2 delayed by the time T2 from the first signal R1. Sound signals from the front V are thus, after appropriate equalization, not attenuated, while, for example, sound signals are extinguished from behind S.

Adaptive directional microphones are microphones that are able to adapt to different environmental conditions during operation. In this case, it is usually the goal to receive as well as possible useful sound emitted by a useful sound source, while the background noise emanating from one or more noise sources should be damped as well as possible in the output signal emitted by the adaptive directional microphone. From the WO 00/19770 A1 a hearing aid with an adaptive directional microphone is known in which the directional gain / attenuation can be varied according to the result of a signal analysis.

It is an object of the invention to provide a simple method and a simple hearing aid for feedback suppression with low artifacts.

According to the invention, the stated object is achieved with the method and the hearing device of the independent claims.

The invention claims a method for feedback suppression in a hearing aid with an adaptive directional microphone. A sound signal fed back from a receiver of the hearing aid to the directional microphone is attenuated by appropriate adaptation of the directional microphone. That is, the directional characteristic of the directional microphone points in the direction of the feedback path a "dent" on. The invention has the advantage that artifact-free in a simple way, an acoustic feedback is attenuated.

In one embodiment of the invention can be damped only in predetermined frequency bands. This can be done in the other frequency bands undisturbed directional microphone operation.

In another embodiment, the attenuation may occur only in the frequency bands in which feedback occurs. The advantage of this is that other frequency bands are not affected.

Furthermore, the frequency bands can be determined by an open-loop gain (OLG) measurement.

In a further development of the method, white noise can be emitted by the listener. The fed-back signal components of the white noise received by the directional microphone are attenuated by the directional microphone adapting its directional characteristic by changing adaptation parameters. The adaptation is stopped when the damping exceeds a predefinable threshold. Subsequently, the adaptation parameters determined in this way are stored. That is, they are "frozen" for further use. The threshold can be maximum attenuation. This offers the advantage that the optimum settings of the adaptive directional microphone can be determined in a hearing aid fitting session.

In another embodiment, the level of the feedback frequency bands may be adjusted to the level of adjacent frequency bands after the feedback cancellation. This preserves the sound even if there is an independent directional microphone operation in the frequency bands without feedback.

Furthermore, the directional microphone can be operated with the stored adaptation parameters. As a result, a low-feedback operation is ensured.

The invention also provides a hearing aid with an adaptive directional microphone for feedback suppression. The hearing device comprises an adaptation unit which adjusts the directional microphone such that a sound signal fed back from a listener of the hearing device to the directional microphone is attenuated.

In a development of the hearing aid, it can only attenuate in predeterminable frequency bands.

In another embodiment, the hearing aid can only attenuate in the frequency bands in which feedback occurs.

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eine Rauschsignaleinheit, die über den Hörer weißes Rau- schen abgibt,

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eine Steuereinheit zum Ermitteln von Adaptionsparametern der Adaptionseinheit, welche die Adaption des Richtmikro- fons durch Verändern der Adaptionsparametern derart steu- ert, dass die vom Richtmikrofon empfangenen, rückgekoppel- ten Signalanteile des weißen Rauschens gedämpft werden, und welche die Adaption anhält, wenn die Dämpfung einen Schwellwert bzw. eine maximale Dämfpung überschreitet, und

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eine Speichereinheit zum Abspeichern der so ermittelten Adaptionsparameter.

Furthermore, the hearing aid may comprise the following units:

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a noise signal unit which emits white noise via the listener,

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a control unit for determining adaptation parameters of the adaptation unit, which controls the adaptation of the directional microphone by changing the adaptation parameters in such a way that the feedback signals of the white noise received by the directional microphone are attenuated and which stops the adaptation if the attenuation exceeds a threshold or maximum attenuation, and

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a memory unit for storing the thus determined adaptation parameters.

The hearing aid may also include a level adjustment unit that adjusts the level of the frequency bands having feedback after the feedback cancellation to the level of adjacent frequency bands without feedback.

In a development, the hearing device may comprise at least two omnidirectional microphones emitting microphones, which are electrically interconnected to form a directional characteristic in the adaptation unit.

Other features and advantages of the invention will become apparent from the following explanations of several embodiments with reference to schematic drawings.

Figur 1:

ein Blockschaltbild eines Hörgeräts mit Rückkopp- lungsunterdrückung gemäß Stand der Technik,

Figur 2:

ein Blockschaltbild einer Mikrofonanordnung mit Richtcharakteristik gemäß Stand der Technik,

Figur 3:

ein Ablaufdiagramm eines Verfahrens zur Rückkopp- lungsunterdrückung mit einem adaptiven Richtmikro- fon,

Figur 4:

ein Blockschaltbild eines Hörgeräts mit einer Rückkopplungsunterdrückung mittels Richtmikrofon und

Figur 5:

Messkurven von frequenzabhängigen Rückkopplungen bei einem Hörgerät.

Show it:

FIG. 1:

1 is a block diagram of a hearing aid with feedback suppression according to the prior art;

FIG. 2:

a block diagram of a microphone array with directional characteristic according to the prior art,

FIG. 3:

2 is a flow chart of a method for feedback suppression with an adaptive directional microphone.

FIG. 4:

a block diagram of a hearing aid with a feedback suppression by means of directional microphone and

FIG. 5:

Traces of frequency-dependent feedback in a hearing aid.

FIG. 3 shows a flow diagram of a method for feedback suppression in hearing aids using an adaptive directional microphone. In the first step 100, white noise WR is emitted by a receiver of a hearing device carried by a hearing device wearer in a sound-proof measuring cabin that is as sound-proof as possible. As a result of an acoustic feedback path between the handset of the hearing aid and at least one microphone of the directional microphone signal components of the white noise are picked up by the microphone. In step 101, the adaptation parameters AP of the adaptive directional microphone are changed so that the feedback signal components are attenuated.

In step 102, the adaptation is stopped when the signal components of the feedback white noise are attenuated by a predefinable threshold value. The threshold can be maximum attenuation. In step 103, the thus determined adaptation parameters AP are stored. Preferably, the attenuation takes place only in the frequency bands FB, in which feedback occurs. These are determined with an OLG measurement in step 104. In step 105, the hearing device is now operated with the thus determined adaptation parameters AP and the thus determined frequency bands FB.

FIG. 4 shows a block diagram of a hearing aid 30 with directional microphone 33 for the suppression of acoustic feedback. Two omnidirectional microphones 31 record sound signals, convert them into electrical signals and supply them to an adaptation unit 32. The microphone signals of the two microphones 31 are electrically interconnected in the adaptation unit 32. By changing adaptation parameters in the adaptation unit 32, the directional characteristic of the directional microphone 33 formed by the microphones 31 can be changed.

A directional microphone signal leaves the adaptation unit 32 and is supplied to a level adjusting unit 34. With the help of the level adjustment unit 34, the signal levels of different frequency bands can be adapted to each other if necessary. The thus adapted signal is fed to a signal processing unit 36 and leaves this amplified and processed. The signal processed by the signal processing unit 36 is supplied to a receiver 37 and emitted as a sound signal from this. A portion of the sound signal is fed back via an acoustic feedback path 38 to the microphones 31 and may lead to feedback whistles. Therefore, with a control unit 39, the adaptation parameters of the adaptation unit 32 are changed such that the feedback signal components are attenuated. That is, the indentation (notch) of the directional characteristic of the directional microphone 33 points in the direction of the feedback path.

Preferably, the adaptation parameters are determined in a hearing aid fitting session. For this purpose, white noise is emitted by the receiver 37 with the aid of a noise signal unit 41 in the hearing device 30. This is partially acoustically fed back and recorded by the microphones 31. The adaptation parameters of the Adaption unit 32 are now changed until the feedback noise signal is attenuated by a predefinable threshold. The adaptation parameters determined in this way are stored in a memory unit 40 and used in the hearing aid operation.

Advantageously, only those frequency bands are attenuated, in which feedback occurs. The critical frequency bands are determined, for example, by an OLG measurement.

In order to avoid sound differences for signals from the rear in directional microphone operation in non-attenuated frequency bands, the level adjustment unit 34 adjusts the levels of the attenuated frequency bands to the levels of adjacent frequency bands.

FIG. 5 shows a diagram of a signal level R in dB as a function of the frequency f in kHz for sound signal fed back into an omnidirectional microphone and for sound signal fed back into a directional microphone with 70 ° notch.

It can clearly be seen from the two level curves OM and RM of the omnidirectional microphone or of the directional microphone that feedback occurs at a frequency f of about 3 kHz, the feedback in the directional microphone being about 25 dB lower than in the omnidirectional due to the selected 70 ° directivity Microphone is.

LIST OF REFERENCE NUMBERS

1

hearing Aid

2

microphone

3

Signal processing unit

4

receiver

5

compensating filter

6

analysis unit

7

eardrum

10

payload

11

microphone signal

12

earpiece signal

13

output

14

Feedback path

15

compensation signal

16

input

21

First microphone

22

Second microphone

23

delay unit

24

inverter

25

adder

30

hearing Aid

31

microphone

32

adaptation unit

33

directional microphone

34

Pegelanpasseinheit

35

Feedback compensation unit

36

Signal processing unit

37

receiver

38

Acoustic feedback path

39

control unit

40

storage unit

41

Noise signal unit

100

Release of white noise WR

101

Change the adaptation parameters AP

102

Stopping the adaptation

103

Storing the adaptation parameters AP

104

OLG measurement

105

Operation of the hearing aid 30

AP

Adaptation parameter of the directional microphone 33

f

Frequency in kHz

FB

Frequency bands with feedback

OM

Signal level of an omnidirectional microphone

R

Feedback signal level in dB

R1

Microphone signal of the first microphone 21

R2

Microphone signal of the second microphone 22

RA

Directional microphone signal

RM

Signal level of a directional microphone with 70 ° notch

S

Sound signals from behind

T1

Delay Time

V

Sound signals from the front

WR

White noise

Claims (13)

A method of feedback suppression in a hearing aid (30) having an adaptive directional microphone (33) characterized by : - An attenuation of one of a listener (37) of the hearing aid (30) to the directional microphone (33) fed back sound signal by adapting the directional microphone (33). Method according to claim 1,
characterized,
that the damping only in predetermined frequency bands (FB) is carried out. Method according to claim 2,
characterized,
that the attenuation takes place only in the frequency bands (FB), in which feedback occurs. Method according to claim 3,
characterized,
that the frequency bands (FB) are determined by an open-loop gain measurement. Method according to one of the preceding claims, characterized by : a noise (100) of white noise (WR) by the listener (37), - An adaptation of the directional microphone (33) by changing (101) of adaptation parameters (AP) to attenuate the received from the directional microphone (33), fed back signal components of the white noise (WR), - stopping (102) the adaptation when the attenuation exceeds a threshold, and - Storing (103) of the adaptation parameters (AP). Method according to one of claims 2 to 5,
characterized,
that the level of the frequency bands (FB) with feedback after the feedback suppression is adjusted to the level of adjacent frequency bands. A method of operating a hearing aid (30) according to claim 5 or 6,
characterized,
that the directional microphone (33) with the stored adaptation parameters (AP) is operated (105). Hearing aid (30) with an adaptive directional microphone (33) for feedback suppression,
characterized by : - An adaptation unit (32) which adjusts the directional microphone (33) such that one of a listener (37) of the hearing aid (30) to the directional microphone (33) fed back sound signal is attenuated. Hearing aid (30) according to claim 8,
characterized,
that it only attenuates in predefinable frequency bands (FB). Hearing aid (30) according to claim 9,
characterized,
that it only attenuates in the frequency bands (FB) in which feedback occurs. Hearing aid (30) according to one of claims 8 to 10, characterized by : a noise signal unit (41) which emits white noise (WR) via the receiver (37), - A control unit (39) for determining adaptation parameters (AP) of the adaptation unit (32), which controls the adaptation of the directional microphone (33) by changing the adaptation parameters (AP) such that the received by the directional microphone (33), fed back signal components of the white Noise (WR) are attenuated, and which the adaptation stops when the damping exceeds a threshold, and - A memory unit (40) for storing the thus determined adaptation parameters (AP). Hearing aid (30) according to one of claims 9 to 11, characterized by : - A level adjusting unit (34), which adjusts the level of the frequency bands (FB) with feedback after a feedback suppression to the level of adjacent frequency bands without feedback. Hearing aid (30) according to one of claims 8 to 12, characterized by : - At least two omnidirectional microphones emitting microphones (31), which are electrically interconnected to form a directional characteristic in the adaptation unit (32).

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