阅读说明：本技术 用于运行听力设备的方法和听力设备 (Method for operating a hearing device and hearing device ) 是由 S.贝斯特 于 2021-05-17 设计创作，主要内容包括：本发明涉及一种用于运行听力设备(2)、尤其是助听器的方法(24),所述听力设备具有定向麦克风(6)、干扰噪声抑制单元(50)和用于将输出声(16)输出的听筒(14)。借助所述定向麦克风(8)检测来自优先方向(30)的声音(28)并且将所述声音向干扰噪声抑制单元(50)传导。借助所述干扰噪声抑制单元(50)产生抵消声信号(54)并且将所述抵消声信号向听筒(14)传导。借助所述听筒(14)输出所述抵消声信号(54)作为输出声(16)。这样产生所述抵消声信号(54),使得在所述输出声(16)与所述声音(28)叠加时至少部分地进行相消的声学干涉。本发明还涉及一种听力设备(2)以及一种听力设备(2)的应用。(The invention relates to a method (24) for operating a hearing device (2), in particular a hearing aid, having a directional microphone (6), an interference noise suppression unit (50) and an earpiece (14) for outputting output sound (16). A sound (28) from a preferred direction (30) is detected by means of the directional microphone (8) and conducted to an interference noise suppression unit (50). Generating a canceling sound signal (54) by means of the interference noise suppression unit (50) and conducting the canceling sound signal to the earpiece (14). Outputting the sound-cancelling signal (54) as output sound (16) by means of the earpiece (14). The muffling signal (54) is generated such that destructive acoustic interference occurs at least partially when the output sound (16) and the sound (28) are superimposed. The invention also relates to a hearing device (2) and to a use of a hearing device (2).)

1. Method (24) for operating a hearing device (2), in particular a hearing aid, having a directional microphone (6), an interference noise suppression unit (50) and an earpiece (14) for outputting output sound (16), wherein,

-detecting sound (28) from a preferential direction (30) by means of the directional microphone (8) and conducting the sound towards an interference noise suppression unit (50),

-generating a cancelling acoustic signal (54) by means of the interference noise suppression unit (50) and conducting the cancelling acoustic signal towards the earpiece (14), and

-outputting the muffled signal (54) as output sound (16) by means of the earpiece (14), wherein,

the muffling signal (54) is generated such that destructive acoustic interference occurs at least partially when the output sound (16) and the sound (28) are superimposed.

2. The method (24) of claim 1, wherein the cancellation sound signal (54) is generated such that frequency selectivity achieves destructive acoustic interference.

3. Method (24) according to claim 1 or 2, characterized in that the preferential direction (30) is changed in dependence on the sound (28).

4. Method (24) according to one of claims 1 to 3, characterized in that the other acoustic signals (45) are output simultaneously with the aid of the earpiece (14).

5. A hearing device (2), in particular a hearing aid, having a directional microphone (6), an interference noise suppression unit (50) and an earpiece (14) for outputting output sound (16), and operating according to the method (24) of one of claims 1 to 4.

6. Use of a hearing device (2) for generating output sound (16) for at least partially destructive acoustic interference with sound (28) from a preferential direction (30) upon superposition, wherein the output sound (16) is based on a cancelling sound signal (54) based on sound (28) detected from the preferential direction (30) by means of a directional microphone (6).

Technical Field

The invention relates to a method for operating a hearing device and a hearing device. The hearing devices each have a directional microphone, an interference noise suppression unit and an earpiece for outputting an output sound. The hearing device is preferably a hearing aid.

Background

Hearing aids are commonly used by persons suffering from hearing loss. Ambient sound is usually detected here by means of an electromechanical sound transducer. The detected electrical signals are processed by means of an amplifier circuit and introduced into the human ear canal by means of a further electromechanical transducer in the form of an earpiece. Furthermore, the detected acoustic signals are usually processed, for which purpose a signal processor of an amplifier circuit is usually used. The amplification is carried out in a manner adapted to the possible hearing loss of the hearing device wearer.

If the ambient sound additionally has sound of a source of interference, i.e. an undesired source, this sound is likewise detected and, as a result of the amplification, is introduced into the human ear canal in an amplified manner. Thereby making it difficult for a person to identify the desired component in the sound emitted into the ear canal. Directional microphones are often used to avoid this. The directional microphone is tuned to the desired sound source such that only sound emanating from the desired sound source is detected by means of an electromechanical sound transducer. Only this component of the ambient sound is thus amplified by the amplifier circuit and output into the auditory canal. However, it is also possible here for the sound emitted from the source of interference to additionally enter directly into the human ear canal, so that it is still perceived by the human even if it is not amplified. Thus, in order to be distinguishable by a person, the amplification factor of the amplifier circuit is likewise increased, which may lead to a loss of comfort and a feeling of fatigue for the person.

Furthermore, headsets with active interference noise suppression devices are known. The headphones usually have a microphone, with the aid of which ambient sound is detected and conducted to an interference noise suppression unit, with the aid of which a cancellation sound signal (gegenschall signal) is generated. The muffling signal is conducted to the earpiece of the earpiece, thereby outputting an output sound (Ausgabeschall) into the ear canal. The output sound is superimposed with ambient sound entering the ear canal, thereby achieving destructive acoustic interference. Thus, the ambient sound is not perceived (or heard) or is perceived only weakly by the human. In addition, additional sound, usually in the form of music, is output by the earpiece into the ear canal. Due to the interference noise suppression, additional sound can be output at a reduced loudness (or volume), which additional sound can nevertheless be perceived better by a person. Since the sound to be perceived by the person, i.e. the additional sound, is output by means of the earpiece itself, it is necessary to completely cancel the ambient sound in the ear canal by means of destructive acoustic interference. Thus, the person does not substantially perceive things in his surroundings at least from the corresponding ambient sound.

Disclosure of Invention

The object of the present invention is to provide a particularly suitable method for operating a hearing device and a particularly suitable method for operating a hearing device system and a particularly suitable hearing device, in which, in particular, the comfort and/or the language intelligibility are increased.

According to the invention, the object is achieved in a method aspect by a method for operating a hearing device, in particular a hearing aid, having a directional microphone, an interference noise suppression unit and an earpiece for outputting sound, in which method sound from a preferred direction is detected by means of the directional microphone and conducted to the interference noise suppression unit; generating a canceling acoustic signal by means of the interference noise suppression unit and conducting the canceling acoustic signal towards an earpiece; and outputting the cancelling sound signal as output sound by means of the earpiece, wherein the cancelling sound signal is generated such that at least partially destructive acoustic interference occurs when the output sound is superimposed with the sound.

The object is achieved in a hearing device, in particular a hearing aid, having a directional microphone, an interference noise suppression unit and an earpiece for outputting sound, and operating by the method according to the invention.

The method is for operating a hearing device. The hearing instrument is for example or comprises an earphone. However, the hearing device is particularly preferably a hearing aid. Hearing aids are used to assist people suffering from hearing loss. In other words, a hearing aid 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 ear canal" hearing aid (RIC; hearing aid of the front shell typeIn-ear hearing aids, e.g. "in-the-ear" hearing aids, "in-the-canal" hearing aids (ITC) or "complete in-the-canal" hearing aids (CIC), spectacle hearing aids, pocket hearing aidsBone conduction hearing aids or implants. The hearing aid is particularly preferably a Behind-the-Ear hearing aid ("Behind-the-Ear" hearing aid) worn Behind the pinna.

The hearing instrument is arranged and designed to be worn on the human body. In other words, the hearing instrument preferably comprises a holding means by means of which a fixation on the human body can be achieved. If the hearing device is a hearing aid, the hearing device is provided and designed for placement, for example, behind the ear or in the ear canal. The hearing device is in particular wireless and is provided and designed for at least partial introduction into the ear canal. The hearing instrument particularly preferably comprises an energy accumulator by means of which the energy supply is provided.

The hearing instrument has a directional microphone. The directional microphone is used to detect sound from a preferential direction. In operation, sound (acoustic) is converted into an electrical signal, also referred to as an acoustic signal, by means of the directional microphone. In this case, only sound from the preferred direction is detected, or at least amplified, by means of the directional microphone. If, however, other sounds, for example sounds from the opposite direction, arrive at the directional microphone, they are not detected or are detected only to a reduced extent, so that they represent no or only a relatively small component of the acoustic signal. In order to produce the directional effect of the directional microphone, i.e. preferably to detect sound from a preferred direction, the directional microphone expediently has a plurality of individual microphones, which are each designed as an omnidirectional microphone, for example. The directional effect is achieved by means of a corresponding evaluation of the electrical signals generated by the microphone.

Furthermore, the hearing device has an especially actively designed interference noise suppression unit (ANC; "active noise cancellation"). The interference noise suppression unit is suitable, in particular arranged and designed, for generating an acoustic cancellation signal, in particular a cancellation acoustic signal with respect to the acoustic signal. The hearing instrument further comprises an earpiece, preferably designed as a loudspeaker. In other words, the earpiece is an electromechanical transducer. The earpiece serves to output the output sound, i.e. to output sound waves, which thus occurs acoustically. The earpiece is here expediently arranged such that the output sound energy is able to be output into the ear canal of the wearer of the hearing device, i.e. the user, when the hearing device is worn in a prescribed state.

The method provides for detecting sound from a preferred direction by means of a directional microphone. Thereby converting the acoustic sound waves of the sound into electrical sound signals. The preferred direction is here, for example, the only direction, and only the sound arriving at the directional microphone around a cone around the preferred direction is detected, so that the acoustic signal has only this component (or part) of the ambient sound. In other words, only the ambient sound part arriving at the directional microphone from a (certain) spatial region, which is a cone whose axis passes through the directional microphone and is parallel to the preferential direction, is detected by means of the directional microphone and converted into an acoustic signal. The spatial angle is in particular less than 90 °, 45 °, 30 °, 20 ° or 10 °. The spatial region from which the sound originates is alternatively in the form of an anti-cardiac line (anticarioid). The acoustic signal generated by means of the directional microphone is conducted towards the interference noise suppression unit. For this purpose, the directional microphone and the interference noise suppression unit are connected to one another, in particular in terms of signal engineering, for example by means of cables or conductor tracks.

The canceling acoustic signal is generated by means of the interference noise suppression unit, and is therefore likewise an electrical signal. The canceling acoustic signal is conducted towards the earpiece, for example, directly or via other components. The earpiece is thereby at least partially loaded by the counteracting acoustic signal or at least one signal based on said counteracting acoustic signal. Whereby the canceling acoustic signal is output as an output acoustic signal by means of the earpiece. In other words, the canceling sound signal is converted into sound, i.e., output sound. The output sound is for destructive acoustic interference with the sound. In other words, the output sound at least partially destructively acoustically interferes when superimposed with the sound. The output sound is suitable, in particular designed and arranged for this purpose. The destructive acoustic interference is suitably performed at the ear or in the ear canal/auditory canal of the user. The hearing instrument is suitably designed accordingly for this purpose. In other words, both the sound and the output sound arrive in the ear canal of the person in a state in which the hearing device is as prescribed, i.e. when the hearing device is worn by the person, and the output sound and the sound are superimposed. Here, a destructive acoustic interference is carried out, so that the sound is not perceived, or at least only to a greater extent, by the person wearing the hearing device, i.e. the user. In this case, the sound-counteracting signal is generated in such a way that the resulting output sound is formed. For this purpose, the noise cancellation sound signal is expediently phase-shifted by 180 ° relative to the sound signal.

Other sounds, i.e. sounds which do not arrive at the directional microphone from a preferred direction, and for example sounds which arrive at the directional microphone from a direction opposite to the preferred direction, are not attenuated or are attenuated only to a relatively small extent when superimposed on the output sound. The other sounds are preferably substantially unchanged here.

Thus, the sound arriving at the directional microphone and thus at the hearing device from the preferential direction is not perceived or perceived to a relatively small extent by the method. While the other components of the ambient sound, i.e. the sound that does not arrive at the directional microphone from a preferred direction, are preferably not attenuated, so that the sound can be perceived by a human without attenuation. It is thus possible to specifically hide (or screen) one or more specific sources of interference, in particular emitted sound, while the rest of the environment can be perceived by the user. Relatively low noise can also be perceived, which increases comfort and speech intelligibility and thus also safety. There is no need to amplify these noises. Furthermore, it is ensured that, with the hearing device, the ear canal is only partially closed and thus ambient sound enters the ear canal, no sound or at least a reduced loudness sound is perceived. It is therefore not necessary to seal the ear canal, which improves the wearing comfort of the hearing device. Sounds from a plurality of preferential directions are detected, for example by means of directional microphones, and conducted towards an interference noise suppression unit. Thereby enabling the concealment of multiple interference sources.

For example, destructive acoustic interference is carried out over a relatively wide frequency band, suitably over all frequencies that can be perceived by humans, i.e. in particular frequencies of 20Hz to 20000 kHz. However, it is particularly preferred that the frequencies selectively undergo destructive acoustic interference. For this purpose, the sound-damping signal is suitably generated accordingly. The output sound and thus the canceling sound signal here have, in particular, an upper (frequency) limit, so that only sounds with frequencies below the upper frequency limit interfere destructively. The frequency band here has no lower limit, for example. It is however particularly preferred that a lower frequency limit is also present, so that the counteracting acoustic signal has a lower (frequency) limit and an upper (frequency) limit. It is thereby possible to specifically hide certain interference sources, while other sound sources which are also located in the preferred direction can still be perceived by the user. Thereby further improving comfort.

The preferential direction is for example fixedly set. Possible microphones of the directional microphone are for this purpose, for example, fixedly electrically connected to one another. It is however particularly preferred to be able to change the direction of preference. This is achieved, for example, by manual adjustment. It is particularly preferred here to change the preferential direction in dependence on the sound itself. In particular, the adaptation to the priority direction takes place here. The preferred direction is expediently set such that a specific component of the ambient sound is detected as sound. The sound has, for example, a certain characteristic, for example a certain frequency or other characteristic. For example, the sound is identified manually or automatically in the ambient sound. For this purpose, for example, a continuous sound produced by a source of disturbance, for example a refrigerator or a pneumatic hammer, is first detected in the ambient sound. The direction from which the sound arrives at the directional microphone is then identified and taken as the preferred direction. The adaptation priority direction is adjusted in particular if the position of the interference source relative to the directional microphone changes. The preferred direction is thereby adjusted to the current interference source and the interference source is thereby at least partially concealed.

Hearing devices are for example only used to hide sounds from humans. In other words only the cancelling acoustic signal is output by means of the hearing instrument. It is however particularly preferred to output the other acoustic signals simultaneously with respect to the anti-noise signal by means of the earpiece. The output sound thus has multiple components. Such as a music track or a soundtrack of a movie. As an alternative to this, the further acoustic signal is likewise generated by means of the hearing device itself. For this purpose, in particular other sounds are detected by the hearing device and conducted as audio signals to the corresponding circuit. The further acoustic signal is derived therefrom by means of the circuit. In particular, amplification is carried out by means of the circuit, the amplification being carried out, for example, directionally selectively. In other words, the further sound is preferably detected from a further preferred direction, which in particular has an angle of more than 30 ° or 45 ° with respect to the preferred direction.

The hearing instrument suitably comprises a signal processor, which suitably at least partly assumes the function of the circuitry. The signal processor is for example a Digital Signal Processor (DSP) or is realized by means of analog components. The adaptation of the audio signal, which is generated in particular by a directional microphone, for example a part of the directional microphone or another microphone, is carried out in particular by means of a signal processor. If the signal processor is designed as a digital signal processor, an a/D converter (analog-to-digital converter) is expediently arranged here between the signal processor and the directional microphone or the further microphone. In particular, the signal processor is adjusted according to the parameter set. The parameter set defines the amplification in the different frequency ranges. In different parameter sets, for example, the amplification factors for the individual frequency bands differ. The hearing instrument particularly preferably additionally comprises an amplifier, or the amplifier is at least partially formed by means of a signal processor. The amplifier is connected, for example, in signal technology before or after the signal processing.

The sound source generating the further sound is thereby made amplificably perceptible to the user on the basis of the further sound signal, so that at least a part of the hearing loss can be compensated. The intelligibility of the other sound is however at least improved for the user.

The hearing instrument is for example or comprises an earphone. The hearing device is designed here, for example, as a so-called headset. However, the hearing device is particularly preferably a hearing aid. Hearing aids are used to assist people suffering from hearing loss. In other words, a hearing aid 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 ear canal" hearing aid (RIC; hearing aid of the front shell typeIn-ear hearing aids, such as "in-the-ear" hearing aids, "in-the-canal" hearing aids (ITCs) or "complete in-the-canal" hearing aids (CICs), spectacle hearing aids, pocket hearing aids, bone conduction hearing aids or implants. The hearing aid is particularly preferably a Behind-the-Ear hearing aid ("Behind-the-Ear" hearing aid) worn Behind the pinna.

Furthermore, the hearing device has a directional microphone, an interference noise suppression unit and an earpiece. Depending on the design of the hearing device, the earpiece can be arranged outside or at least partially inside the ear canal of the user and be arranged there when the hearing device is worn as intended.

The hearing instrument operates according to a method in which sound from a preferential direction is detected by means of a directional microphone and conducted towards an interference noise suppression unit. Generating a cancellation sound signal by means of the interference noise suppression unit and conducting the cancellation sound signal to the earpiece. Outputting a cancellation sound signal as output sound by means of the earpiece, wherein the cancellation sound signal is generated such that at least partially destructive acoustic interference occurs when the output sound is superimposed with the sound. The hearing instrument preferably has a control unit by means of which the method is at least partially performed. In other words, the control unit is suitable, in particular designed and arranged, for carrying out the method.

A hearing device with directional microphones is used to produce output sound for at least partially destructive acoustic interference with sound from preferential directions when superimposed. The output sound is based on a canceling sound signal based on sound detected from a preferential direction by means of a directional microphone.

The extended designs and advantages described in connection with the method can also be transferred substantially to hearing devices/applications and to each other and vice versa.

Drawings

Embodiments of the invention are explained in more detail below with reference to the drawings. In the drawings:

fig. 1 schematically shows a hearing device;

fig. 2 shows a method for operating a hearing instrument; and is

Fig. 3 schematically shows a hearing instrument in a simplified partial view.

Corresponding parts are provided with the same reference numerals throughout the figures.

Detailed Description

Fig. 1 shows a hearing device 2 in the form of a hearing aid, which is arranged and designed to be worn behind the ear of a user (user, hearing device wearer, wearer). In other words, Behind-the-Ear hearing aids ("Behind-the-Ear" hearing aids) are concerned. The hearing instrument 2 comprises a housing 4, which is made of plastic. A directional microphone 6 with two electromechanical sound transducers in the form of respective omnidirectional microphones 8 is arranged in the housing 4. By varying the offset in time between the acoustic signals detected by means of the omnidirectional microphone 8, the directional characteristic of the directional microphone 6 can be varied. The two microphones 8 are signal-technically coupled to a signal processing unit 10, which includes an amplification circuit, which is not shown in detail, and a signal processor 12. The signal processing unit 10 is also formed by circuit elements, for example electrical and/or electronic components. The signal processor 12 is a Digital Signal Processor (DSP) and is connected to the microphone 8 in terms of signals by means of an a/D converter, which is not shown in detail.

The receiver 14 is signal-technically coupled to the signal processing unit 10. In operation, an (electrical) signal provided by means of the signal processing unit 10 is converted by means of the earpiece 14 into output sound 16, i.e. sound waves. The sound waves are directed into a sound tube 18, one of the ends of which is fixed to the housing 4. The other end of the sound tube 18 is surrounded by a dome (Dom)20, which is arranged in a defined state in an ear canal, not shown in detail here, of the user. The dome 20 has a plurality of openings therein, so that the wearing comfort is increased. The signal processing unit 10, the directional microphone 6 and the receiver 14 are supplied with power by means of a battery 22.

Fig. 2 shows a method 24 for operating the hearing instrument 2, the signal path of which is shown in fig. 3. In a first operating step 26, ambient sound 27 is detected by means of the microphone 8. The ambient sound 27 here has a sound 28 which arrives at the directional microphone 6 from a preferred direction 30. Furthermore, the ambient sound 27 has other sounds 32 which arrive at the directional microphone 6 from other preferential directions 34. The sound 28 is emitted from an interference source and has a specific frequency spectrum, i.e. essentially only a single frequency of 50 Hz. While other sounds 32 are emitted by other sound sources, i.e. other persons.

The sound 28 and other sounds 32 are detected by means of the microphone 8 of the directional microphone 6 and conducted towards the signal processing unit 10. The signal processing unit 10 forms part of the directional microphone 6 and discriminates, by means of a respective time offset, the component corresponding to the sound 28, i.e. the acoustic signal 36, and the component corresponding to the further sound 32, i.e. the audio signal 38, from the signal detected by the microphone 8.

In a second subsequent operating step 40, the preferred direction 30 is changed as a function of the sound 28, i.e. the direction from which the sound 28 is detected by means of the directional microphone 6 to generate the sound signal 36. The preferred direction 30 is changed to the direction from which the sound 28 mainly reaches the directional microphone 6. For this purpose, the maximum in the directional distribution in the case of a 50Hz signal is determined and the priority direction 30 is set in this direction. Furthermore, the other preferential direction 34 is set such that it points to the other sound source. This is effected, for example, manually or by means of a suitable algorithm.

In a following third operating step 42, the further acoustic signal 38 is conducted to the signal processor 12. The processing of the audio signal 38 takes place in a fourth operation step 44 by means of the signal processor 12. In this case, certain frequencies are amplified and other frequencies are attenuated. In addition, compression is provided. The audio signal 38 processed in this way is conducted as a further acoustic signal 45 into an amplifier 46 of the signal processing unit 10.

A fifth work step 48 is carried out simultaneously with the third work step 42. In the fifth operating step, the acoustic signal 36 is conducted into the interference noise suppression unit 50 of the signal processing unit 10. In a sixth operating step 52, a cancellation sound signal 54 is generated by means of the interference noise suppression unit 50, which is likewise conducted to the amplifier 46.

In a seventh operating step 56, the further acoustic signal 45 and the canceling acoustic signal 54 are conducted in an amplified manner and combined by means of the amplifier 46 to the receiver 14. The amplified further acoustic signal 45 and the canceling acoustic signal 54 are output as output sound 16 via the sound tube 18 in an eighth operating step 58 with the aid of the earpiece into the ear canal 60 of the user.

Since the dome 20 is designed to be permeable, the ambient sound 27, i.e. the sound 28 and the other sounds 32, also reaches the ear canal 60 here substantially unimpeded. The sound 28 and other sounds 32 are superimposed with the output sound 16 in the ear canal 60. Since the audio signal 38 is amplified by means of the signal processor 12, constructive (or constructive) acoustic interference is realized at least partially in the ear canal 60, so that the other sound 32 is perceptible to the user. Destructive acoustic interference of this component of the output sound 16 with the sound 28 is achieved due to the output of the canceling acoustic signal 54. The sound 28 is thus substantially eliminated by the output sound 16. In other words, destructive acoustic interference is achieved. Whereby the sound 28 is not perceived or can only be perceived to a relatively large extent weakly by the user. It is therefore not necessary to select a relatively large degree of amplification of the audio signal 38 in the fourth operating step 44, wherein the user is nevertheless able to reliably perceive the further sound 32 directly or from the components contained by means of the output sound 16. The muffled sound signal 54, or the component of the output sound 16 based on the muffled sound signal, has only a frequency of 50Hz, so that the frequencies selectively achieve destructive acoustic interference. Thereby enabling the user to perceive sound sources other than the interfering source from the preferential direction 30.

The present invention is not limited to the above-described embodiments. But other variants of the invention can also be derived therefrom by the person skilled in the art, without departing from the scope of the invention. Furthermore, all individual features described in particular in connection with the exemplary embodiments can also be combined with one another in other ways, as long as they do not depart from the technical solution of the invention.

List of reference numerals

2 hearing device

4 casing

6 directional microphone

8 microphone

10 Signal processing unit

12 Signal processor

14 earphone

16 output sound

18 sound tube

20 round top

22 cell

24 method

26 first working step

27 ambient sound

28 Sound

30 direction of precedence

32 other sounds

34 other preferential direction

36 acoustic signals

38 audio signal

40 second working step

42 third working step

44 fourth working step

45 other acoustic signals

46 amplifier

48 fifth working step

50 interference noise suppression unit

52 sixth working step

54 canceling acoustic signals

56 seventh working step

58 eighth working step

60 ear canal