EP3913618A1 - Hearing aid and method for operating a hearing aid - Google Patents

Abstract

The invention relates to a method (24) for operating a hearing aid (2), in particular a hearing aid, which has a directional microphone (6), a noise suppression unit (50) and a receiver (14) for outputting an output sound (16). Sound (28) from a preferred direction (30) is recorded by means of the directional microphone (8) and passed to the background noise suppression unit (50). A counter-sound signal (54) is generated by means of the background noise suppression unit (50) and sent to the listener (14). The counter-sound signal (54) is output as output sound (16) by means of the receiver (14). The counter-sound signal (54) is generated in such a way that when the output sound (16) is superimposed on the sound (28), at least partially destructive acoustic interference occurs. The invention also relates to a hearing aid (2) and the use of a hearing aid (2).

Description

The method relates to a method for operating a hearing aid and a hearing aid. The hearing aid has a directional microphone, a noise suppression unit and a receiver for outputting an output sound. The hearing aid is preferably a hearing aid.

People who suffer from hearing impairment usually use a hearing aid. Ambient sound is usually recorded by means of an electromechanical sound transducer. The recorded electrical signals are processed by means of an amplifier circuit and introduced into the ear canal of the person by means of a further electromechanical transducer in the form of a receiver. In most cases, the recorded sound signals are also processed, for which a signal processor of the amplifier circuit is usually used. In this case, the gain is matched to any hearing loss of the hearing aid wearer.

If the ambient sound also includes sound from an interference source, that is to say an unwanted source, this is also recorded and, due to the amplification, is introduced into the person's auditory canal to a greater extent. This makes it difficult for the person to identify the desired components in the sound emitted into the auditory canal. A directional microphone is usually used to avoid this. This is set to a desired sound source so that only the sound emitted by this is recorded by means of the electromechanical sound transducer. Thus, only this component of the ambient sound is emitted into the auditory canal in an amplified manner by means of the amplifier circuit. In this case, however, it is also possible that the sound emitted by the source of interference also penetrates directly into the ear canal of the person so that it is perceived by the person, albeit not amplified. So a distinction is possible for the person, the gain factor of the amplifier circuit is therefore also increased, which can lead to a loss of comfort and fatigue of the person.

Headphones with active noise suppression are also known. The headphones usually have a microphone, by means of which the ambient sound is recorded and passed to a background noise suppression unit, by means of which a counter-sound signal is generated. This is conducted to a listener of the headphones so that an output sound is emitted into the ear canal. This is superimposed on the ambient sound penetrating the ear canal, so that a destructive acoustic interference occurs. As a result, the ambient sound cannot be perceived by the person or is only perceptible to a reduced extent. Furthermore, additional sound, usually in the form of music, is emitted into the ear canal with the listener. Due to the noise suppression, it is possible to output the additional sound at a reduced volume, although this can still be perceived better by the person. Since the sound to be perceived by the person, namely the additional sound, is output by means of the headphones themselves, it is necessary to completely eliminate the ambient sound by means of the destructive acoustic interference in the auditory canal. As a result, the person can essentially not perceive processes in their environment, at least on the basis of the respective ambient sound.

The invention is based on the object of specifying a particularly suitable method for operating a hearing aid and a particularly suitable method for operating a hearing aid system as well as a particularly suitable hearing aid, with in particular comfort and / or speech intelligibility being increased.

With regard to the method, this object is achieved according to the invention by the features of claim 1 and, with regard to the hearing aid, by the features of claim 5. Advantageous further developments and refinements are the subject of the respective subclaims.

The method is used to operate a hearing aid. For example, the hearing aid is a headphone or comprises a headphone. The hearing aid is particularly preferred but a hearing aid. The hearing aid device is used to support a person suffering from a hearing impairment. In other words, the hearing aid device is a medical device, by means of which, for example, a partial hearing loss is compensated. The hearing aid is, for example, a "receiver-in-the-canal" hearing aid (RIC; Ex-Hörer- hearing aid), an in-the-ear hearing aid, such as an "in-the-ear" hearing aid, an "in-the -canal "hearing aid (ITC) or a" complete-in-canal "hearing aid (CIC), hearing glasses, a pocket hearing aid, a bone conduction hearing aid or an implant. The hearing aid device is particularly preferably a behind-the-ear hearing aid device that is worn behind an auricle.

The hearing aid is intended and set up to be worn on the human body. In other words, the hearing aid preferably comprises a holding device, by means of which attachment to the human body is possible. If the hearing aid is a hearing aid, the hearing aid is provided and set up, for example, to be arranged behind the ear or within an auditory canal. In particular, the hearing aid is wireless and is provided and set up to be at least partially inserted into an auditory canal. The hearing aid particularly preferably comprises an energy store, by means of which an energy supply is provided.

The hearing aid has a directional microphone. The directional microphone is used to record sound from a preferred direction. During operation, the (acoustic) sound is converted into an electrical signal by means of the directional microphone, which is referred to below as a sound signal. In this case, the directional microphone only or at least amplifies the sound from the preferred direction. If, on the other hand, additional sound strikes the directional microphone, for example from the opposite direction, this additional sound is not detected or only to a reduced extent, so that it represents no or only a comparatively small component of the sound signal. To create the directional effect of the directional microphone, that is to say the preferred detection of the sound from the preferred direction, it expediently has several individual microphones, each of which is designed, for example, as an omnidirectional microphone. The directional effect is realized here by means of a corresponding evaluation of the electrical signals generated by means of the microphones.

Furthermore, the hearing aid has a noise suppression unit which is designed in particular to be active (ANC; “active noise canceling”). The noise suppression unit is suitable, in particular provided and set up, to generate a counter-sound signal, in particular for the sound signal. The hearing aid also comprises a receiver which is preferably designed in the manner of a loudspeaker. In other words, the handset is an electromechanical transducer. The receiver is used to output an output sound, i.e. the output of sound waves, which is acoustically. The receiver is suitably arranged in such a way that the output sound is emitted into an auditory canal of a wearer of the hearing aid, that is to say of the user, when the hearing aid is worn in the intended state.

The method provides that sound from the preferred direction is recorded by means of the directional microphone. The acoustic sound waves of the sound are thus converted into the electrical sound signal. The preferred direction is, for example, a single direction, and only the sound that hits the directional microphone around a cone around the preferred direction is recorded so that the sound signal only has these components of the ambient sound. In other words, only that part of the ambient sound is recorded by means of the directional microphone and converted into the sound signal that hits the directional microphone from a room area, the room area being a cone, the axis of which goes through the directional microphone and is parallel to the preferred direction. In particular, the solid angle is smaller than 90 °, 45 °, 30 °, 20 ° or 10 °. Alternatively, the area of the room from which the sound originates has an anti-cardioid shape. The sound signal generated by the directional microphone is sent to the noise suppression unit. In particular, for this purpose the directional microphone and the background noise suppression unit are connected to one another for signaling purposes, for example by means of a cable or a conductor track.

By means of the noise suppression unit, an anti-noise signal is generated, which is thus also an electrical signal. The counter-sound signal is passed to the listener, for example directly or via other components. The listener is thus at least partially acted upon by means of the counter-sound signal or at least a signal that is based on the counter-sound signal. By means of the handset the counter-sound signal is thus output as output sound. In other words, the counter-sound signal is converted into sound, namely the output sound. The output sound was used for destructive acoustic interference with the sound. In other words, when the output sound is superimposed on the sound, at least partially destructive acoustic interference occurs. The output sound is suitable for this, in particular provided and set up. The destructive acoustic interference expediently takes place on the ear or in the ear canal / auditory canal of the user. The hearing aid is expediently designed accordingly for this purpose. In other words, both the sound and the output sound reach the hearing aid in the intended state of the hearing aid, that is, when it is worn by the person, in the ear canal, and the output sound and the sound are superimposed. The destructive acoustic interference occurs here, so that the person wearing the hearing aid, that is to say the user, cannot perceive the sound or at least only perceive it to a greatly reduced extent. The counter-sound signal is created in such a way that the resulting output sound is generated. For this purpose, the counter-sound signal is expediently 180 ° out of phase with the sound signal.

Additional sound, that is, sound that does not strike the directional microphone from the preferred direction and that strikes the directional microphone, for example, from the direction opposite to the preferred direction, is not attenuated or only at a comparatively low level when it is superimposed with the output sound. In this case, there is preferably essentially no change in the further sound.

Due to the method, the person does not perceive the sound hitting the directional microphone and thus the hearing aid from the preferred direction, or only perceives it to a comparatively small extent. In contrast, further components of the ambient sound, that is to say the sound that does not strike the directional microphone from the preferred direction, are preferably not attenuated, so that the person can perceive it undiminished. As a result, it is possible that one or more specific sources of interference, which in particular emit or emit sound, are specifically masked out, whereas the rest of the environment can still be perceived by the user. It is thus also possible to perceive comparatively quiet noises, which increases comfort and speech intelligibility and therefore also security. Here is one It is not necessary to amplify these noises. Furthermore, with only a partial closure of the auditory canal by means of the hearing aid and the consequent penetration of the ambient sound into the auditory canal, it is ensured that the sound is not perceived or is at least perceived at a reduced volume. As a result, sealing of the auditory canal is not absolutely necessary, which increases the comfort of wearing the hearing aid. For example, the directional microphone records sound from several preferred directions and sends it to the noise suppression unit. It is thus possible to mask out several sources of interference.

For example, the destructive acoustic interference takes place over a comparatively broad frequency band, expediently over all frequencies that can be perceived by a human being, that is to say in particular from 20 Hz to 20,000 kHz. Particularly preferably, however, the destructive acoustic interference takes place in a frequency-selective manner. The counter-sound signal is expediently created accordingly for this purpose. In particular, the output sound and thus also the counter-sound signal have an upper (frequency) limit, so that only destructive interference occurs with the sound whose frequency is lower than the upper frequency limit. For example, there is no lower limit to the frequency band. Particularly preferably, however, a lower frequency limit is also present, so that the counter-sound signal has a lower and an upper (frequency) limit. It is thus possible to suppress certain sources of interference in a targeted manner, whereas sources of additional sound that are also in the preferred direction can still be perceived by the user. Thus, comfort is further increased.

For example, the preferred direction is set to be rigid. For this purpose, the possible microphones of the directional microphone are, for example, permanently electrically connected to one another. However, it is particularly preferably possible to change the preferred direction. This is done, for example, by means of manual setting. The preferred direction is particularly preferably changed as a function of the sound itself. In particular, an adaptive adjustment of the preferred direction takes place here. The preferred direction is suitably set in such a way that a certain component of the ambient sound is identified as sound. This sound has, for example, certain properties, such as a certain one Frequency or other properties. For example, the sound is identified manually or automatically in the ambient sound. For example, a constant hum or the like is first identified in the ambient sound, which is caused by the source of interference, for example a refrigerator or a jackhammer. The direction from which this sound hits the directional microphone is then identified, and this direction is used as the preferred direction. If the position of the source of interference changes with respect to the directional microphone, in particular the preferred direction is adapted. The preferred direction is thus set to the current source of interference, and this is thus at least partially masked out.

For example, the hearing aid only serves to block out the sound for the person. In other words, only the counter-sound signal is output by means of the hearing device. Particularly preferably, however, a further sound signal is output by means of the receiver at the same time as the counter-sound signal. Thus, the output sound has several components. The further sound signal is, for example, a piece of music or a soundtrack from a film. As an alternative to this, the further sound signal is also generated by means of the hearing aid itself. For this purpose, in particular another sound is recorded by means of the hearing aid and passed as an audio signal to a corresponding circuit. The additional sound signal is derived from this by means of this. In particular, amplification takes place by means of the circuit, the amplification taking place in a direction-selective manner, for example. In other words, the further sound is preferably detected from a further preferred direction, which in particular has an angle to the preferred direction that is greater than 30 ° or 45 °.

The hearing aid expediently comprises a signal processor, which suitably at least partially takes over the function of the circuit. The signal processor is, for example, a digital signal processor (DSP) or implemented using analog components. The signal processor is used in particular to adapt the audio signal, which is generated in particular with the directional microphone, for example part of it, or a further microphone. In this case, an A / D converter is expediently arranged between these, provided the signal processor is designed as a digital signal processor. The signal processor is set in particular as a function of a set of parameters. Using the A gain in different frequency ranges is specified in the parameter set. For example, the gain factor assigned to the individual frequency bands differs in the case of different parameter sets. The hearing aid particularly preferably additionally comprises an amplifier, or the amplifier is at least partially formed by means of the signal processor. For example, in terms of signal technology, the amplifier is connected upstream or downstream of the signal processor.

Due to the additional sound signal, the user can perceive a sound source producing the additional sound to a greater extent, so that an at least partial hearing loss can be compensated for. At least, however, an intelligibility of the further sound is improved for the user.

For example, the hearing aid is a headphone or comprises a headphone. Here, the hearing aid is designed, for example, as a so-called headset. However, the hearing aid is particularly preferably a hearing aid. The hearing aid device is used to support a person suffering from a hearing impairment. In other words, the hearing aid device is a medical device, by means of which, for example, a partial hearing loss is compensated. The hearing aid is, for example, a "receiver-in-the-canal" hearing aid (RIC; Ex-listener hearing aid), an in-the-ear hearing aid, such as an "in-the-ear" hearing aid, an "in-the -canal "hearing aid (ITC) or a" complete-in-canal "hearing aid (CIC), hearing glasses, a pocket hearing aid, a bone conduction hearing aid or an implant. The hearing aid device is particularly preferably a behind-the-ear hearing aid device that is worn behind an auricle.

The hearing aid also has a directional microphone, a noise suppression unit and a receiver. Depending on the design of the hearing aid, the receiver can be arranged outside or at least partially within an auditory canal of a user and is arranged there when the hearing aid is worn as intended.

The hearing aid is operated according to a method in which the directional microphone detects sound from a preferred direction and sends it to the noise suppression unit is directed. An anti-noise signal is generated by means of the background noise suppression unit and sent to the listener. The counter-sound signal is output as output sound by means of the earpiece, the counter-sound signal being generated in such a way that when the output sound is superimposed on the sound, at least partially destructive acoustic interference occurs. The hearing aid preferably has a control unit by means of which the method is at least partially carried out. In other words, the control unit is suitable, in particular provided and set up, to carry out the method.

A hearing aid with a directional microphone is used to generate an output sound for at least partially destructive acoustic interference with a sound from a preferred direction when superimposed. The output sound is based on a counter-sound signal that is based on the sound recorded from the preferred direction by means of the directional microphone.

The developments and advantages described in connection with the method can also be applied to the hearing aid application and to each other and vice versa.

Fig. 1

schematisch ein Hörgerät,

Fig. 2

ein Verfahren zum Betrieb des Hörgeräts, und

Fig. 3

schematisch vereinfacht ausschnittsweise das Hörgerät.

An exemplary embodiment of the invention is explained in more detail below with reference to a drawing. Show in it:

Fig. 1

schematically a hearing aid,

Fig. 2

a method for operating the hearing aid, and

Fig. 3

schematically simplified sections of the hearing aid.

Corresponding parts are provided with the same reference symbols in all figures.

In Fig. 1 a hearing aid 2 is shown in the form of a hearing aid which is provided and set up to be worn behind an ear of a user (user, hearing aid wearer, wearer). In other words, it is a behind-the-ear hearing aid device ("behind-the-ear" hearing aid device). The hearing aid 2 comprises a housing 4 which is made of a plastic. Inside the case 4 is a directional microphone 6 with two electromechanical sound transducers in the form of an omnidirectional microphone 8 each. By changing a time offset between the acoustic signals detected by means of the omnidirectional microphones 8, it is possible to change a directional characteristic of the directional microphone 6. The two microphones 8 are signal-technically coupled to a signal processing unit 10, which comprises an amplifier circuit (not shown in detail) and a signal processor 12. The signal processing unit 10 is also formed by means of circuit elements, such as, for example, electrical and / or electronic components. The signal processor 12 is a digital signal processor (DSP) and is signal-connected to the microphones 8 via an A / D converter (not shown in detail).

A receiver 14 is signal-coupled to the signal processing unit 10. During operation, the receiver 14 converts an (electrical) signal provided by the signal processing unit 10 into an output sound 16, that is to say into sound waves. These are introduced into a sound tube 18, one end of which is attached to the housing 4. The other end of the sound tube 18 is enclosed by means of a dome 20 which, in the intended state, is arranged in an auditory canal of the user, not shown here. Here, the dome 20 has several openings so that it is more comfortable to wear. The signal processing unit 10, the directional microphone 6 and the receiver 14 are supplied with current by means of a battery 22.

In Figure 2 a method 24 for operating the hearing aid 2 is shown, the signal path of which is shown in FIG Figure 3 is shown. In a first work step 26, an ambient sound 27 is recorded by means of the microphones 8. The ambient sound 27 here has sound 28 which strikes the directional microphone 6 from a preferred direction 30. Furthermore, the ambient sound 27 has further sound 32 which strikes the directional microphone 6 from a further preferred direction 34. In this case, the sound 28 is emitted by an interference source and has a specific frequency spectrum, namely essentially only a single frequency which is 50 Hz. The further sound 32, on the other hand, is emitted by a further sound source, namely a further person.

The sound 28 and the further sound 32 are recorded by means of the microphones 8 of the directional microphone 6 and passed to the signal processing unit 10. The signal processing unit 10 forms part of the directional microphone 6, and by means of a corresponding time offset, the component corresponding to the sound 28, namely a sound signal 36 and a component corresponding to the further sound 32, is in the detected signals that are detected by the microphones 8 Component, namely an audio signal 38, identified.

In a subsequent second work step 40, the preferred direction 30, that is to say the direction from which the sound 28 is recorded by means of the directional microphone 6 for generating the sound signal 36, is changed as a function of the sound 28. Here, the preferred direction 30 is changed in the direction from which the sound 28 mainly hits the directional microphone 6. For this purpose, the maximum in the directional distribution for the 50 Hz signal is determined and the preferred direction 30 is placed in this direction. Furthermore, the further preferred direction 34 is set in such a way that it points to the further sound source. This is done, for example, manually or by means of a suitable algorithm.

In a subsequent third work step 42, the further sound signal 38 is passed to the signal processor 12. In a fourth work step 44, the audio signal 38 is processed by the signal processor 12. In this case, certain frequencies are amplified and others are attenuated. Compression is also set. The audio signal 38 processed in this way is fed as a further sound signal 45 to an amplifier 46 of the signal processing unit 10.

At the same time as the third work step 42, a fifth work step 48 is carried out. In these, the sound signal 36 is fed to a background noise suppression unit 50 of the signal processing unit 10. In a sixth work step 52, an anti-noise signal 54 is created by means of the background noise suppression unit 50, which signal is also passed to the amplifier 46.

By means of the amplifier 46, in a seventh work step 56, the further sound signal 45 and the counter-sound signal 54 are amplified and sent to the receiver 14 in combination. By means of this, in an eighth work step 58, the amplified further sound signal 45 and the counter-sound signal 54 emitted as the output sound 16 through the sound tube 18 into an auditory canal 60 of the user.

Since the dome 20 is designed to be permeable, the surrounding sound 27, that is, both the sound 28 and the further sound 32, also enter the auditory canal 60 essentially unhindered. The sound 28 and the further sound 32 are also superimposed in the auditory canal 60 the output sound 16. Due to the amplification of the audio signal 38 by means of the signal processor 12, there is at least some structural acoustic interference in the ear canal 60, so that the additional sound 32 can be perceived by the user. Due to the output of the counter-sound signal 54, there is a destructive acoustic interference of this component of the output sound 16 with the sound 28. As a result, the sound 28 is essentially extinguished by means of the output sound 16. In other words, destructive acoustic interference occurs. Thus, the sound 28 cannot be perceived by the user or is only perceptible to a comparatively reduced extent. It is therefore not necessary to select the amplification of the audio signal 38 to be comparatively high in the fourth work step 44, although the user can still reliably perceive the further sound 32 either directly or using the components contained by means of the output sound 16. The counter-sound signal 54 or the component of the output sound 16 based thereon only has a frequency of 50 Hz, so that the destructive acoustic interference occurs in a frequency-selective manner. It is thus possible for the user to perceive other sound sources besides the interference source from the preferred direction 30.

The invention is not restricted to the exemplary embodiment described above. Rather, other variants of the invention can also be derived therefrom by the person skilled in the art without departing from the subject matter of the invention. In particular, all of the individual features described in connection with the exemplary embodiment can also be combined with one another in other ways without departing from the subject matter of the invention.

List of reference symbols

2

Hearing aid

4th

casing

6th

Directional microphone

8th

microphone

10

Signal processing unit

12th

Signal processor

14th

Listener

16

Output sound

18th

Sound tube

20th

Dom

22nd

battery

24

procedure

26th

first step

27

Ambient noise

28

sound

30th

Preferred direction

32

further sound

34

further preferred direction

36

Sound signal

38

Audio signal

40

second step

42

third step

44

fourth step

45

another sound signal

46

amplifier

48

fifth step

50

Noise suppression unit

52

sixth step

54

Anti-noise signal

56

seventh step

58

eighth step

60

Ear canal

Claims (6)

Method (24) for operating a hearing aid (2), in particular a hearing aid, which has a directional microphone (6), a noise suppression unit (50) and an earpiece (14) for outputting an output sound (16), wherein - By means of the directional microphone (8), sound (28) from a preferred direction (30) is recorded and passed to the background noise suppression unit (50), - A counter-sound signal (54) is created by means of the background noise suppression unit (50) and passed to the listener (14), and - The counter-sound signal (54) is output as output sound (16) by means of the receiver (14), wherein the counter-sound signal (54) is generated in such a way that when the output sound (16) is superimposed on the sound (28), at least partially destructive acoustic interference occurs. Method (24) according to claim 1,
characterized,
that the counter-sound signal (54) is created in such a way that the destructive acoustic interference occurs in a frequency-selective manner. Method (24) according to claim 1 or 2,
characterized,
that the preferred direction (30) is changed as a function of the sound (28). Method (24) according to one of claims 1 to 3,
characterized,
that by means of the receiver (14) a further sound signal (45) is output at the same time. Hearing aid (2), in particular hearing aid, which has a directional microphone (6), a background noise suppression unit (50) and an earpiece (14) for outputting an output sound (16), and which according to a method (24) according to one of Claims 1 to 4 is operated. Use of a hearing aid (2) to generate an output sound (16) for at least partially destructive acoustic interference with a sound (28) from a preferred direction (30) when superimposed, the output sound (16) being based on a counter-sound signal (54) based on based on the sound (28) recorded from the preferred direction (30) by means of a directional microphone (6).

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