EP2169984A2 - Hearing aid with a directional microphone system and method for operating such a hearing aid device - Google Patents

Abstract

The device (1) has directional microphones (M1-M3) picking up an acoustic input signal and creating electrical microphone signals (S1-S3). A signal processing unit (2) processes and amplifies the electrical microphone signal, and creates an electrical output signal. An earpiece (3) converts the electrical output signal into an acoustic output signal. The directional microphones provide directional effect based on the amplification of the electrical microphone signal, where the directional effect comprises a first-order directional effect set below a threshold value of the amplification. An independent claim is also included for a method for operating a hearing aid device.

Description

The invention relates to a hearing aid and a method for operating a hearing aid with a directional microphone system for receiving an acoustic input signal and generating at least one electrical microphone signal, a signal processing unit for processing and amplifying the electrical microphone signal and generating an electrical output signal and a receiver for converting the electrical output signal in an acoustic output signal, wherein in the directional microphone system different directional effects are adjustable and wherein the gain is adjustable in dependence on the result of an analysis of the microphone signal.

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 and converts it into an electrical input signal. Modern hearing aids often comprise a directional 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, telephone coils or antennas for receiving electromagnetic input signals and conversion to electrical input signals are also common as input transducers. The input signals converted by the input transducer into electrical input 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 user usually in response to the signal frequency of the input signal. The signal processing unit supplies at its output an electrical output signal, which via at least one output transducer the hearing of the hearing aid wearer is supplied so that it 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. A hearing aid further includes a voltage source (battery or rechargeable battery) for powering the electronic components. Furthermore, controls (on / off switch, program switch, volume control, etc.) may be present.

In modern hearing aids devices for the classification of hearing situations are used. Depending on the hearing situation, the transmission parameters of the hearing aid are automatically varied. The classification may include u.a. Influence on the amplification of the electrical input signal, the operation of noise canceling algorithms or on the directional microphone system. Thus, for example, depending on the detected hearing situation selected (discretely switched or continuously faded) between an omnidirectional directional characteristic (directional characteristic of zero order) and a clear directivity of the microphone system (directivity of the first or higher order). To generate the directional characteristic gradient microphones are used or interconnected several omnidirectional microphones with each other.

From the DE 103 31 956 B3 a hearing aid is known with a directional microphone system comprising a plurality of electrically interconnected omnidirectional microphones and in which different directivity can be adjusted. In the known hearing aid device, the sound quality is to be improved, in particular in a quiet, listening environment. For this purpose, it is proposed to increase the signal delay in at least one microphone signal such that an increase in the transfer function in the frequency response of the microphone system takes place, which also improves the signal-to-noise ratio by reducing the proportion of microphone noise in the microphone output signal.

The hearing aid professional is known that a hearing aid tends to tend to feedback at a very high gain, if in the directional microphone system used a high degree of directivity is set. Therefore, at very high gains (e.g., greater than 100 dB), the directional microphone system is used only in omnidirectional operation, i. without directivity. In hearing aids for hearing-impaired hearing aid wearers who require a relatively high amplification, in particular with quiet acoustic input signals, adjustment of the directivity has hitherto been carried out as a function of the signal level of the acoustic input signal. Thus, the maximum directivity of the directional microphone system used was allowed only above a certain signal level of the acoustic input signal, or, if a high degree of directivity was required even at a lower signal level of the acoustic input signal, the gain correspondingly decreased.

So far, in hearing aid devices, both the adjustment of the gain and the adjustment of the directivity in each case depending on the result of an analysis of one or more microphone signals or from the or the microphone signals resulting signals. The maximum possible directivity was determined by the signal level of the acoustic input signal.

The object of the present invention is always to provide the hearing aid wearer with the greatest possible degree of reinforcement and directivity.

This object is achieved by a hearing aid with the features of claim 1. Furthermore, the object is achieved by a method for operating a hearing aid with the method steps according to claim 5.

The invention has the advantage that the greatest possible degree of directivity, in particular with a high gain of the acoustic input signal by the hearing aid, is no longer directly coupled to the signal level of the input signal. Rather, the greatest possible degree of directivity in the hearing aid according to the invention now depends directly on the set gain. The difference to the previous procedure is particularly clear when the hearing aid adjusts only a relatively low gain despite a relatively quiet acoustic input signal, which would actually require a high gain. This is e.g. then the case when the classifier recognizes that in the acoustic input signal no or only a small useful signal component is present and thus is at least predominantly an interference signal in the input signal. In this case, it makes no sense if the hearing aid selects a high gain. However, it is advantageous for the user if the hearing aid device retains the highest possible directivity in the directional microphone system used, especially in a hearing situation with a high interference signal component. Advantageously, the greatest possible degree of directivity for a particular hearing situation no longer depends on the level of the acoustic input signal, but directly on the set gain. This fully exploits the technical possibilities of the hearing aid in question.

Advantageously, a function is stored in the hearing aid, which determines the dependence of the directivity of the gain. In the simplest case of a hearing aid device with a directional microphone system comprising two omnidirectional microphones which can be interconnected electrically, this is a threshold value of the amplification above which an omnidirectional (and therefore no) directivity is always set.

In a directional microphone system comprising more than two microphones, higher order directivity effects can be realized, e.g. in a directional microphone system with three omnidirectional microphones directional effects of first and second order. In this case, two gain thresholds can be set, with the hearing aid concerned automatically a second order directivity at a gain below the lower threshold, a first order directivity at a gain between the two thresholds, and a directivity at a gain above the upper threshold zeroth order chooses. This procedure can in principle be extended to directional microphone systems with an arbitrary number of microphones and thus arbitrary order of directivity.

Furthermore, in addition to the switching between different orders of directivity as a function of discrete threshold values of the amplification, it is also possible that a continuous and continuous functional relationship between the amplification and the directivity is stored in the hearing aid. Depending on the currently set at the hearing aid concerned gain then the level of directivity for the respective directional microphone system is selected and set.

Advantageously, the selected according to the invention, the relationship between the directivity and the gain only the greatest possible degree of directivity at the respective gain. This relationship can be determined, for example, by laboratory experiments, so that a stable operation of the respective hearing aid device is always ensured in the directivity associated with the respective amplification. Of course, however, a smaller than the largest possible directivity can always be set in the respective gain. Detects the hearing aid by an analysis of one or more microphone signals or from these signals, for example, that in the current hearing situation, a directivity is not required is, then automatically no or a lower than the maximum directivity at the instantaneous gain can be set.

The invention has hitherto been explained for the complete frequency spectrum which can be transmitted with the relevant hearing aid device. In hearing aids, however, the signal processing usually takes place in parallel within individual frequency bands, the so-called channels. Both the setting of the gain and the directivity between the individual channels can vary. Of course, the considerations explained so far with reference to a frequency band can also be applied to a number of parallel frequency bands.

• Figur 1 ein stark vereinfachtes Blockschaltbild eines Hörhilfegerätes gemäß der Erfindung,
• Figur 2 ein erstes Beispiel für den Zusammenhang zwischen der Verstärkungseinstellung und der Richtwirkung und
• Figur 3 ein zweites Beispiel für den Zusammenhang zwischen der Verstärkungseinstellung und der Richtwirkung.

The invention will be explained in more detail with reference to an embodiment. Showing:

• FIG. 1 a highly simplified block diagram of a hearing aid according to the invention,
• FIG. 2 a first example of the relationship between the gain setting and the directivity and
• FIG. 3 a second example of the relationship between the gain setting and the directivity.

FIG. 1 shows a highly simplified block diagram of a hearing aid 1 with three microphones M1, M2 and M3, which receive an acoustic input signal and generate three electrical microphone signals S1, S2 and S3. The three microphones M1, M2 and M3, together with a microphone interconnection unit 4, form a directional microphone system whose directivity can be changed by different interconnections of the microphones M1, M2 and M3 and different delays of the microphone signals S1, S2 and S3 in the microphone interconnection unit 4. The microphone interconnection unit 4 delivers at its output a directional microphone signal R, which is for further processing and frequency-dependent amplification of a signal processing unit 2 is supplied. The processed and amplified directional microphone signal is finally converted by an earphone 3 into an acoustic output signal and supplied to the hearing of a user of the hearing aid device 1.

The hearing aid 1 is manually (by manual program switching) and automatically adaptable to different listening situations. The adaptation takes place in particular by setting parameters which determine the signal processing in the signal processing unit 2. For this purpose, for the automatic determination of the parameter settings suitable for the respective hearing situation, an analysis of the microphone signals S1, S2 and S3 takes place in an analysis and control unit 6. By means of this analysis, the hearing situation in which the relevant hearing aid device 1 is currently located is automatically recognized and suitable Parameter settings determined and set in the signal processing unit 2. In particular, the amount of amplification of an acoustic input signal is determined by the hearing aid 1, wherein in addition to the signal analysis also other factors can influence the gain, such as a manual volume adjustment, which the user makes, for example by means of a remote control on the hearing aid 1.

A further automatic adaptation of the hearing aid device 1 to the current hearing situation concerns the directional microphone system. Here, too, the control takes place on the basis of a signal analysis of the microphone signals S1, S2 and S3, which takes place in a directional microphone control unit 5 for this purpose. In particular, the interference signal component and the directions of incidence of acoustic signals in the directional microphone system determine the directivity, which is then adjusted by means of the microphone circuit unit 4.

As a further parameter flows in the determination and adjustment of the directivity in the hearing aid 1 according to the invention also the currently set in the hearing aid 1 in the signal processing unit 2 gain with.

Clarifies the relationship between maximum directivity and gain FIG. 2 , With the directional microphone system with the three electrically interconnected omnidirectional microphones M1, M2 and M3 of the hearing aid 1 directivities zero, first and second order can be realized. For this purpose is in the diagram according to FIG. 1 a directivity index RI is plotted against the gain V. "O" stands for a directional characteristic of zeroth order (ie no directivity), "1" for a directional characteristic of the first order and "2" for a directional characteristic of the second order. Accordingly, up to a threshold value V1 of the amplification, there is no upper limit of the directivity. It can be set with the directional microphone maximum possible directivity of the second order. Between the first threshold value V1 and the second threshold value V2, only a directional characteristic of the first order is maximally possible, and above the threshold value V2 a directional effect must be completely dispensed with.

As already mentioned, the diagrams only give the maximum possible directional effect as a function of the amplification, in which a stable operation of the relevant hearing aid device is ensured. Of course, always a lower directivity can be set.

Another example of a variety of possible functions shows FIG. 3 , Also, a directivity index RI is plotted against the gain V. A difference from the example according to FIG. 2 results in the range between the threshold values V1 and V2, wherein here a linear decrease of the directivity of a directional characteristic of the second order to a directional characteristic of zero order is given. Such a connection can be achieved, for example, by a targeted control of the time constants in the microphone interconnection unit 4 FIG. 1 be achieved.

Advantageous is the relationship between the gain and the maximum directivity, as with the help of FIGS. 2 and 3 has been described, deposited in the hearing aid 1, for example in a memory of the directional microphone control unit 4th

Claims (8)

Hearing aid (1) having a directional microphone system (M1, M2, M3, 4) for receiving an acoustic input signal and generating at least one electrical microphone signal (S1, S2, S3, R), a signal processing unit (2) for processing and amplifying the electrical microphone signal ( S1, S2, S3, R) and generating an electrical output signal and a receiver (3) for converting the electrical output signal into an acoustic output signal, wherein in the directional microphone system (M1, M2, M3, 4) different directivities are adjustable and wherein the gain depending on the result of an analysis of the microphone signal (S1, S2, S3, R) is adjustable,
characterized in that the adjustment of the directivity takes place as a function of the set gain. Hearing aid (1) according to claim 1, wherein in the hearing aid (1) a function of the directivity as a function of the gain can be stored and the directivity is adjustable according to this function. Hearing aid device (1) according to claim 1, wherein in the hearing aid (1) a function of maximum directivity as a function of gain can be stored and the degree of directivity is adjustable so that it does not exceed the maximum directivity at the respective gain. Hearing aid device (1) according to one of the preceding claims, wherein at least directivities zeroth and first order are adjustable, wherein at least one threshold value (V1, V2) of the gain is adjustable and wherein at a gain below the threshold value (V2) a first-order directivity and at a gain above the threshold value (V2), a directivity of zeroth order is adjustable. Method for operating a hearing aid device (1) having a directional microphone system (M1, M2, M3, 4) for receiving an acoustic input signal and generating at least one electrical microphone signal (S1, S2, S3, R), a signal processing unit for processing and amplifying the electrical microphone signal (S1, S2, S3, R) and generating an electrical output signal and a receiver (3) for converting the electrical output signal into an acoustic output signal, wherein in the directional microphone system (M1, M2, M3, 4) different directivities are adjustable and wherein the Gain is adjusted as a function of the result of an analysis of the microphone signal (S1, S2, S3, R),
characterized in that the directivity is adjusted automatically in dependence of the set gain. Method for operating a hearing aid device (1) according to claim 5, wherein in the hearing aid device (1) a function of the directivity as a function of the gain is stored and the degree of directivity is adjusted automatically according to this function. Method for operating a hearing aid (1) according to claim 5, wherein in the hearing aid (1) a function of the maximum directivity as a function of gain is stored and the degree of directivity is automatically adjusted so that it does not exceed the maximum directivity at the respective gain , Method for operating a hearing aid device (1) according to one of the preceding claims, wherein at least one zero and first order directivities are adjustable, wherein at least one threshold value (V1, V2) of the gain is set and wherein at a gain below the threshold value (V2) a Directivity of the first order and at a gain above the threshold (V2) is automatically set a directivity zero-order.

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