EP1307072B1 - Method for operating a hearing aid and hearing aid - Google Patents

Abstract

The method involves processing, amplifying and outputting an electrical signal from a hearing aid transducer. A switching unit is triggered for switching and slidably transitioning the hearing aid between two operating condition, and generating two signals. The two signals are operated with a weighting function which first increases and second decreases with the switching event. An Independent claim is also included for a hearing aid.

Description

The invention relates to a method for operating a hearing aid with an input transducer for receiving an input signal and conversion into an electrical signal, a signal processing unit for processing and amplification of the electrical signal and an output transducer, wherein a switching operation for transferring the hearing aid from a first operating state to a second Operating state is triggered and wherein there is a sliding transition from the first operating state to the second operating state Furthermore, the invention relates to a hearing aid for performing the method.

For optimized operation in different listening situations, a plurality of hearing programs can be set in a known hearing device. You can switch between the individual programs either manually or automatically. Such a hearing aid is for example in the US 4,425,481 disclosed.

Furthermore, hearing aids are known from the prior art in which algorithms for signal processing in the hearing device can be switched on and off for further adaptation to different auditory situations. These algorithms relate to e.g. the compression, the reduction of interfering signals or the speech signal increase.

Both the switching between different hearing programs and the activation of algorithms in the hearing aid can be done manually or automatically. As a rule, disturbing acoustic effects and associated irritations in the perception of sound signals in natural listening situations arise. Most of these express themselves in the form of annoying crackling noises, unnatural level jumps or unnatural, sudden sound changes.

From the DE 195 42 961 C1 a circuit for operating a hearing aid equipped with at least one variable operating parameter and a hearing aid as such are known, wherein the operating parameter settings of a starting situation and a target situation are defined in a memory arrangement and by means of a control unit over a certain time interval, a transition of the operating parameter of the setting in the Starting situation in the setting of the target situation is feasible.

From the DE 195 34 981 A1 a method for fine adjustment of hearing aids is known, in which an evaluation of the degree of optimization of the hearing aid set parameters, for example by means of psychoacoustic parameters, and in a subsequent optimization step, an adjustment of parameters requiring improvement takes place first in an assessment step. In this case, the degree of optimization to be evaluated or parameters which are relevant for this within the evaluation step and / or the degree of the adjustment of the parameter requiring improvement is determined by fuzzy logic-based algorithms or rule sets.

From the DE 198 59 171 C2 An implantable hearing aid with tinnitus masker or noise is known, in which a digital signal processor is provided, which is designed both for the preparation of the audio signal as well as for the generation of tinnitus masking or Noiserfunktion necessary signals and for the combination of the latter signals with the audio signal.

From the US 6,101,258 is a hearing aid with an omnidirectional and a directional microphone known. It can be switched manually or automatically between a directional and a non-directional microphone characteristic. Soft fading between the different microphone characteristics is also possible.

From the WO 01/01731 A1 as well as from the WO 01/72085 A2 Hearing devices with a plurality of omnidirectional microphones are known, which are electrically interconnected to produce a directivity. By different interconnection of the microphones different directional characteristics can be generated. You can blend in slightly between the different directional characteristics.

The object of the present invention is to avoid disturbing acoustic effects in a hearing device caused by switching on, off or switching operations.

This object is achieved by a method having the features according to claim 1

Furthermore, the object is achieved by a hearing aid with the features according to claim 17.

The hearing aid that is used to carry out the method according to the invention is, for example, a hearing aid worn behind the ear, a hearing aid that can be worn in the ear, an implantable hearing aid or a pocket hearing device. Furthermore, the hearing device used may also be part of a plurality of devices for the care of a hearing impaired comprehensive hearing aid system, eg part of a hearing aid system with two worn on the head hearing aids for binaural care or part of a hearing aid system, consisting of a head-worn device and a wearable processor unit. The hearing aid comprises an input transducer for receiving an input signal. Typically, the input transducer is a microphone that picks up an acoustic signal and converts it into an electrical signal. As input transformer but also units come into consideration, the one Have coil or an antenna and receive an electromagnetic signal and convert it into an electrical signal. The hearing device further comprises a signal processing unit for processing and frequency-dependent amplification of the electrical signal. For signal processing in the hearing aid is preferably a digital signal processor (DSP), whose operation can be influenced by means of transferable to the hearing aid programs or parameters. As a result, the mode of operation of the signal processing unit can be adapted to the individual hearing loss of a hearing aid wearer and to the current hearing situation in which the hearing aid is currently being operated. The thus changed electrical signal is finally fed to an output transducer. This is usually designed as a handset, which converts the electrical output signal into an acoustic signal. However, other embodiments are also possible here, for example an implantable output transducer which is directly connected to an auditory ossicle and excites it to vibrate.

As already stated above, the signal processing in the hearing aid can be controlled by parameters. A whole set of parameters used to adjust the signal processing to a particular listening situation is called a hearing program. When changing the hearing program therefore usually a variety of parameters is changed. In addition to the parameters for controlling the signal processing but also certain algorithms can influence the signal processing in the hearing aid. For example, an automatic gain control (AGC - Automatic Gain Control) can be effected by an algorithm. Another algorithm can be used to detect and reduce noise. Also, a special increase of speech signals by a convenient algorithm is possible.

In addition to the parameters for controlling the signal processing in the hearing aid and the algorithms themselves signal processing and thereby affect the signal processing in the hearing aid, hearing aids provide additional functions that can be activated, deactivated or adjusted. Such a function that can be exercised with the hearing device may relate, for example, to the microphone system. Thus, in a hearing aid, an omnidirectional or a directional reception can be set and, in the case of a directional reception, the degree of directivity of the microphone system can be determined. Further functions relate, for example, to a switchable signal for tinnitus therapy or the receipt of an input signal by means of a telecoil.

Modern hearing aids thus offer a variety of settings, by means of which they can be adapted to different listening situations or individual wishes and needs of a hearing aid wearer. If the hearing situation changes during the operation of the hearing device or if the hearing aid wearer wishes a change in a function of the hearing aid, then a switching process is necessary. A switching operation is understood to be the switching on or off of an algorithm, the activation or deactivation of a function or the abrupt change of at least one parameter of the signal processing. An example, continuous change in the gain by means of a volume control is thus no switching operation in the context of the invention.

So far, hearing aids are transferred by the switching abruptly from a first operating state to a second operating state. Compared to the first operating state, an algorithm is switched on or off in the second operating state, or the algorithm is modified in its mode of operation. Likewise, by switching over a function of the hearing aid can be activated, deactivated or changed. The sudden change in the operating state is accompanied by disturbing acoustic effects and the associated irritation in the perception of sound signals. By the sliding transition from the first operating state to the second operating state according to the invention avoids such effects. The trigger for the change of the operating state is still an activation or deactivation of an algorithm or a function or a change of an algorithm or a function. According to the invention, however, the changes made do not instantaneously affect in their entirety the signal output via the output transducer. The resulting with conventional hearing aids click or pop noises, unnatural level jumps and unnatural sound changes are thus prevented. The change of the operating state is effected by a sliding transition from the first operating state to the second operating state.

The method according to the invention can be applied to switching on or off an algorithm as well as to changing an activated algorithm. In the latter case, the algorithm performs a first function in the first operating state and a second function in the second operating state. For example, in an automatic gain control algorithm, this may mean changing the compression characteristic. Likewise, however, algorithms which relate to the frequency response, the reduction of interference signals or the raising of speech signals can be switched on, switched off or changed in their function.

As with the algorithms that perform signal processing, the invention can also be applied to functions of the hearing aid that hide no algorithm. For example, the generation of a signal for tinnitus therapy may be provided. Is this feature enabled, Thus, in addition to the signal transmitted by the hearing aid, a signal is emitted for masking the tinnitus in the auditory canal.

The invention provides that in a switching operation of the hearing aid from a first operating state to a second operating state temporarily both operating states are present in parallel in the hearing aid. If, for example, an algorithm is switched on when the operating state is changed, this means that during the switching process the signal processing takes place both with the algorithm switched on and in parallel also with the algorithm switched off. The results of the parallel signal processing are finally weighted and merged. Advantageously, this does not involve parallel signal processing over the entire signal path of the hearing device, but only in the part of the signal path of the hearing aid in which the two operating states differ. A preceding and subsequent signal processing can therefore be carried out equally for both operating states. The sliding transition from the first operating state to the second operating state is now achieved according to an embodiment of the invention in that both operating states are linked to each other via a weighting function, wherein during the switching operation the weighting of a first signal resulting from the first operating state at 1 beginning gradually, steadily or at most in small jumps decreases and the weighting of a second signal resulting from the second operating state, starting at 0 gradually increases, steadily or at most in small jumps. The sum of the weights is preferably at least approximately always equal to 1. If, for example, an algorithm for noise suppression is switched on, this means that signal processing in a signal path of the hearing aid initially continues without this algorithm. Parallel to this the signal processing takes place in a second signal path of the hearing aid with the algorithm for noise reduction. Immediately following the algorithm for noise suppression and at the corresponding point in the parallel signal path of the hearing aid, the two signal paths are linked together via a weighting function. The weighting of the algorithm for noise suppression is increased from 0 to 1 and the weighting of the corresponding parallel processing is lowered starting from 1 without the corresponding algorithm. The sum of the weights is preferably always equal to 1. Thus, the hearing aid is automatically, "soft" and transferred almost imperceptibly from a first operating state to the second operating state. Click or pop noises, unnatural level jumps and unnatural sound changes are thereby avoided.

An embodiment of the invention is characterized in that at least one parameter for controlling the signal processing in the hearing device has a specific value in the first operating state and, in a second operating state, has a value which has changed abruptly with respect to the first value. As a rule, however, a large number of parameters are changed abruptly at the same time during a switching process in the hearing device, for example during the change of the hearing program. According to the invention, the switching operation does not unfold its full effect immediately, but there is a smooth transition from the first operating state to the second operating state. For this purpose, at least in the subregion of the signal processing unit of the hearing aid on which the parameter is applied, a parallel signal processing, on the one hand with the parameter in its initial value and on the other with the parameter in its final value. The outputs of the parallel signal processing blocks are then added with automatically changing weighting until, at the end of the transition, in fact only the signal branch with the parameter in its final value is active. The invention is in this case limited by manual adjustment operations on the hearing aid, which take place continuously or continuously with a digital hearing device. Such settings relate to, for example, the volume control or settings related to the sound. These can be adjusted by means of controls, but this is not to be understood as a "switching" within the meaning of the invention.
The switching process is preferably controlled by a dedicated switching algorithm. This determines the weighting of the two signals and optionally the point in the signal path of the hearing aid, at which the two parallel paths are brought together, so that the parallel signal processing remains possible only to a part of the signal path.

In the invention, it does not matter whether the switching operation is performed manually, for example by actuating a control element, or automatically, e.g. is triggered by an automatic situation detection and switching of the hearing program.

An embodiment of the invention provides that the duration of the switching operation is adjustable. Depending on how annoying a user feels the switching operations, then the switching process "harder" or "softer" can be set. In general, the duration of the switching process will be selected in the range of a few seconds.

Further details of the invention will be described below with reference to embodiments.

• Figur 1 ein Blockschaltbild eines Hörgerätes, bei dem ein Algorithmus zur Signalverarbeitung sowie verschiedene Funktionen einstellbar sind,
• Figur 2 eine erste Schaltungseinheit zum gleitenden Ein- und Ausschalten eines Algorithmus,
• Figur 3 eine Schaltungseinheit zum gleitenden Umschalten zwischen zwei Hörprogrammen,
• Figur 4 einen zwischen omnidirektionalem und direktionalem Empfang umschaltbaren Signaleingang eines Hörgerätes nach dem Stand der Technik,
• Figur 5 eine Schaltungsanordnung, die einen gleitenden Übergang zwischen omnidirektionalem und direktionalem Empfang bewirkt,
• Figur 6 die Änderung der Richtcharakteristik beim weichen Überblenden zwischen omnidirektionalem und direktionalem Betrieb anhand von Richtdiagrammen und

Show it:

• 1 shows a block diagram of a hearing aid in which an algorithm for signal processing and various functions are adjustable,
• FIG. 2 shows a first circuit unit for the sliding on and off of an algorithm,
• FIG. 3 shows a circuit unit for the sliding switching between two hearing programs,
• 4 shows a switchable between omnidirectional and directional reception signal input of a hearing aid according to the prior art,
• FIG. 5 shows a circuit arrangement which effects a smooth transition between omnidirectional and directional reception.
• Figure 6 shows the change of the directional characteristic in the soft cross-fading between omnidirectional and directional operation using directional diagrams and

FIG. 1 shows a block diagram of a hearing aid 1 in which both an omnidirectional microphone 2 and a directional microphone formed from the microphones 3 and 4 are provided for receiving an acoustic input signal. To form a directional microphone system, the two microphones 3 and 4 are electrically interconnected via a delay element 5 and a differential element 6. For further processing, the microphone signals are fed to a signal processing unit 7. This preferably comprises a digital signal processor, in which the signal processing takes place in parallel in a plurality of frequency channels. The signal processing unit 7 is adjustable to compensate for the individual hearing loss of a hearing aid wearer by a variety of parameters. Furthermore, several different parameter sets for adapting the signal processing in the hearing device 1 to different listening situations, so-called listening programs, can be provided and activated therein. In addition, the signal processing unit 7 allows the activation and adjustment of various algorithms for signal processing or such functions of the hearing aid 1. Such algorithms may relate, for example, to the frequency response, the reduction of interference signals, the enhancement of speech signals, the directional microphone characteristic, the compression, etc. In the hearing aid 1 adjustable functions are, for example, the choice of the signal input via a telephone coil 8, via the microphone 2 or via the microphone system 3, 4. Another example of an adjustable function is the generation of a signal for tinnitus therapy.

The activation or adjustment of the algorithms or functions can be carried out manually or automatically in the hearing device 1. For example, the hearing aid 1 can automatically detect certain hearing situations, e.g. the hearing situation "environment with noise", and then activate a corresponding hearing program. Simultaneously with the relevant hearing program, an algorithm for noise suppression is then activated. In the exemplary embodiment, this is illustrated by the circuit unit 9 for reducing interference signals within the signal processing unit 7. An input signal s (t) enters the circuit unit 9 and an output signal y (t) is supplied at the output. Both s (t) and y (t) may be vectors, ie a plurality of signals. Overall, therefore, a signal is picked up at at least one point in the signal path of the hearing aid 1, supplied to the circuit unit for reducing interference signals 9 and returned to the signal path after a signal processing. For example, can be done in the circuit unit 9 filtering.

If an input signal has passed through the signal processing unit 7 of the hearing aid 1, it is finally converted into an acoustic signal via a receiver 10 and fed to the auditory canal of the hearing device wearer.

With reference to the circuit unit 9 for reducing interference signals according to Figure 1, an exemplary embodiment is hereinafter the invention described in more detail. For this purpose, the circuit unit 9 is schematically illustrated in block diagram in FIG. The circuit unit 9 is supplied to a signal input an input signal s (t). An analysis unit 11A analyzes the input signal s (t) and detects whether an interference signal is contained therein. As the output of the analysis unit 11A, a binary signal a (t) is supplied. In this case, the value 0 means that no interference signal has been detected, and with a detected interference signal, the value 1 is generated. The signal a (t) does not directly switch on or off an algorithm for noise suppression in the arithmetic unit 12, but is initially applied to an input of a low-pass filter 11B. If the value of the signal a (t) jumps from 0 to 1, the value of the signal k (t) at the output of the low pass 11B continuously increases from 0 to 1 as a function of the time constant of the low pass 11B. The analysis unit 11A thus forms together with the Low pass 11B provides a classifier 11 that does not "hard" between 0 or 1 - that is, "no noise present" or "noise present" - but provides a "smooth" sliding transition.

The signal k (t) is located directly at an input 13A and the value 1-k (t) formed in a computing unit 14 at an input of a multiplier 13B. As is further apparent from the block diagram, the multiplier 13B is supplied directly with the input signal s (t) while first passing through the arithmetic unit 12 before being supplied to the multiplier 13A. Finally, the two parallel signal paths are combined by a summer 15 again. Thus, in the case of a jump from a (t) from 0 to 1, the arithmetic operations carried out by the arithmetic unit 12 initially do not have a full effect on the output signal y (t), but only to the extent that the signal k (t) increases. To the same extent, the effect of the signal s (t), which was originally switched directly through to the output y (t), is reduced. After a certain, preferably adjustable period of time then the value of the signal k (t) has increased to 1, which the arithmetic unit 12 unfolds its full effect at the signal output y (t) and the direct signal path is bypassed while bypassing the arithmetic unit 12.

If, after a while, the interfering signals in the input signal s (t) are no longer detected by the analysis unit 11A, the signal a (t) switches from 1 to 0 and the reverse process is set in motion.

The "soft" switching on and off of an algorithm has been described in the exemplary embodiment with reference to a circuit unit for reducing interference signals. Analogously, however, this approach can be applied to any algorithm that performs signal processing in the hearing aid. Furthermore, in addition to the switching on and off of algorithms can also be switched between different algorithms. In addition, it is also possible that by switching the calculation rule that is executed by an algorithm to change. In this case, according to the invention, during the switching operation, both the original algorithm and the modified algorithm are executed. In contrast to the exemplary embodiment shown according to FIG. 2, in both signal paths between the signal input s (t) and the adder 15 there are arithmetic units for the parallel execution of these algorithms, the results of which are then added according to the invention with alternating weighting.

The invention offers the advantage that interference noise or unnatural sound changes caused by switching on, off or switching operations in the hearing device according to the invention can be avoided. This effect is particularly advantageous in switching operations in the hearing aid, which are triggered automatically. In many cases, under certain external conditions, many switching operations take place within a short time, for example within a few seconds. In the exemplary embodiment, this may be the case if only a weak interference signal is present. Then the output signal of the analysis unit 11A, a (t), very often changes between 1 and 0, ie: "interference signal present" or "no interference signal present". In conjunction with the low-pass filter 11B, the multipliers 13A and 13B and the arithmetic unit 14, this then leads to a state in which both operating states are active in parallel in the hearing aid over a longer period since the output signal k (t) of the classifier 11 is none of the end values 0 or 1 reached. In the embodiment, the noise reduction would thus only partially effective. However, this is quite desirable and useful for the example given initial situation of a weak interference signal.

The embodiment according to FIG. 2 shows only one possible embodiment of a weighting function with automatically changing weighting. However, alternative solutions are also conceivable here. Furthermore, it is only a schematic block diagram. Thus, in the practical implementation even more, not shown here, but familiar to those skilled circuit elements necessary, was waived in favor of an improved clarity in the presentation. For example, in a realization in digital circuit technology, A / D converters are still required in order to convert the weighting functions k (t) and 1-k (t) into digital functions.

FIG. 3 also shows a further exemplary embodiment of the invention. Signal processing is also implemented in a signal path of a hearing device by a circuit unit 9 ', specifically by means of a computer unit 20 processing of the input signal s (t) adapted to a specific environmental situation. The signal processing in the arithmetic unit 20 is determined by a parameter set, in the exemplary embodiment the "hearing program 1". First, the output of the arithmetic unit 20 is identical to the output signal of the circuit unit 9 ', namely y (t). Now, by pressing a control element 21 to the "listening program 2" switched. For carrying out the switching operation, the circuit unit 9 'has a switching unit 22. This first causes the signal path of the hearing aid at least for a part of the signal path, namely between the signal input s (t) and the signal output y (t), in which differ the parameters of the signal processing of both hearing programs, parallel signal processing for the duration of the switching operation he follows. Taking into account the relevant parameter set for the hearing program 2, processing of the input signal s (t) is thus also carried out in a computer unit 23. In order to ensure a smooth transition between the two hearing programs, the outputs of the arithmetic units 20 and 23 are weighted and fed to a summer 24. The weighting also takes place in this exemplary embodiment by a signal a '(t) which jumps from the value 1 to the value 0. Via a low-pass filter 25 whose time constant can be controlled by the switching unit 22 via the signal b '(t), an output signal k' (t) of the low-pass filter 25 is generated which steadily drops from 1 to 0 within a specific period of time. For different weighting of the outputs of the arithmetic units 20 and 23, the signal k '(t) and the signal 1-k' (t) formed in the arithmetic unit 26 are supplied to a multiplier 27A and 27B, respectively. By means of this exemplary embodiment, a sliding transition from a hearing program 1 to a hearing program 2 is realized, wherein the duration of the switching process can be controlled by the switching unit 22 via a function b '(t).

In addition to manual switching by the operating element 21, the switching between two hearing programs can also be triggered automatically. Furthermore, the invention can be extended analogously to more than two programs, between which switching is based on the example of a switching between two listening programs.

If a classifier can not clearly recognize the current hearing situation, it changes very frequently and at short intervals between different listening situations. This results in connection with the invention has the advantage that then several hearing programs are operated automatically over a longer period of time in parallel in the hearing aid. If the situation recognition takes place, for example, by means of a circuit arrangement comparable to the classifier 11 according to FIG. 1, then the weighting of the respective hearing situation is on average approximately proportional to the time duration for which the respective hearing situation is determined.

Analogously, the exemplary embodiment shown on the basis of the switching process between two hearing programs can be transferred to any other switching processes in the hearing aid in which hitherto jumps of parameters that influence the signal processing take place.

As with the use of algorithms that cause signal processing in the hearing aid, the invention can also be applied to various functions of a hearing aid that can be activated, deactivated or changed in terms of their setting. In the hearing device according to FIG. 4, a microphone arrangement with the microphones 30, 31 and 32 makes it possible to set different microphone receiving characteristics. If a switch S is in a first switching position, then only the omnidirectional microphone 30 is connected to a signal processing unit 33. Through the electrical connection of the two omnidirectional microphones 31 and 32 with a delay element 34 and a differential element 35, a directional microphone 31, 32 is realized. If the switch S is in the second switching position shown in FIG. 4, then the directional microphone 31, 32 is connected to the signal processing unit 33. Such a switchable microphone system is known in the art. When switching the switch S can on the one hand caused by the switching noise, but also unnatural sound changes in the signal transmission by the hearing aid arise. In order to avoid this, a circuit arrangement, as illustrated in the block diagram according to FIG. 5, is provided for the signal input. Here, too, there is a choice between an omnidirectional reception by the microphone 30 and a directional reception by the microphones 31 and 32 in conjunction with the delay element 34 and the difference element 35. At least during the switching operation, the output of the omnidirectional microphone 30 is a signal processing unit 33A and the output of the microphone system 31, 32 fed to a signal processing unit 33B. Trigger for the switching operation is the switching element 36. The switching operation can be triggered either manually, for example by pressing a control element, or automatically, eg in conjunction with the change of the hearing program. The triggering subsequent automatic switching operation is controlled by a switching unit 37. This determines which parts of the signal processing are to be executed in parallel during the switching process and, if appropriate, at which point y "(t) in the signal path of the hearing aid a common further processing can take place. Thus, the two differently weighted signal paths in the summer 38 can be brought together and end-reinforced together.

The alternating weighting of the parallel microphone signal paths also takes place in the hearing device according to FIG. 4 by a binary signal a "(t), which changes from 1 to 0 when switching from an omnidirectional reception through the microphone 30 to a directional reception by the microphone system 31, 32 From a low-pass filter 39 whose time constant is controllable by a signal b "(t) emanating from the switching unit 37, a signal k" (t) is output which, for example, steadily drops from 1 to 0 and as one of the input signals of a multiplier 40A is used, in a computer unit 41 formed signal 1-k '' (t) is supplied to an input of a multiplier 40B. At the second input of the multiplier 40A there is a signal originating from the microphone 30, at the second input of the multiplier 40B there is a signal coming from the interconnected microphones 31 and 32.

The circuit according to the block diagram allows a soft and smooth switching between an omnidirectional and a directional microphone reception. Also in this hearing aid, it is possible that by a very frequent switching at short time intervals by the switching element 36, e.g. caused by a not clearly determinable listening situation, both microphone characteristics over a longer period of time parallel in the hearing aid are available.

The soft, smooth transition between omnidirectional and directional microphone reception is additionally graphically illustrated by the directional diagrams A to H in FIG. Shown is the transition starting from the first operating state, in which only an omnidirectional reception takes place (directional characteristic A). Diagrams B through G then show the transition for which both operating states are present in parallel in the hearing aid, i.e., both the omnidirectional microphone and the directional microphone receive and process an input signal. Due to the time-varying weighting of the processed and summed microphone signals, the directional characteristics B to G arise. Finally, after the switching process has ended, only the second operating state is present in the hearing aid and the directional characteristic has the kidney shape illustrated in FIG. 6H.

Claims (19)

1. Method for operating a hearing aid (1) having an input transducer for picking up an input signal and converting it to an electrical signal, a signal processing unit (7) for processing and amplifying the electrical signal, and an output transducer, a switching event being triggered for switching the hearing aid (1) from a first operating mode into a second operating mode and a sliding transition ensuing from the first operating mode to the second operating mode, characterized in that, during the switching event, a signal path within the hearing aid is split, between a signal input, at which an input signal (s(t)) is present, and a signal output, at which an output signal (y(t)) is present, into a first signal path and a parallel second signal path, the input signal (s(t)) passing through both signal paths, in the first signal path the first operating mode being used in the hearing aid (1) and in the second signal path the second operating mode being used in the hearing aid (1), a first signal that results from the first operating mode and a second signal that results from the second operating mode being linked with one another via a weighting function, and the weighting of the first signal decreasing and the weighting of the second signal increasing during the switching event.
2. Method according to Claim 1, wherein an algorithm for signal processing is switched on in the first operating condition and switched off in the second operating condition.
3. Method according to Claim 1, wherein an algorithm for signal processing is switched off in the first operating condition and switched on in the second operating condition.
4. Method according to Claim 1, wherein an algorithm is modified in the second operating condition compared to a first operating condition.
5. Method according to one of Claims 2 to 4, wherein the algorithm relates to the frequency response, the reduction of noise signals, the boosting of voice signals, the directional microphone characteristic or the compression.
6. Method according to Claim 1, wherein a function of the hearing aid (1) is activated in the first operating condition and not activated in the second operating condition.
7. Method according to Claim 1, wherein a function of the hearing aid (1) is not activated in the first operating condition and activated in the second operating condition.
8. Method according to Claim 1, wherein an activated function of the hearing aid (1) is modified in the second operating condition compared to the first operating condition.
9. Method according to one of Claims 6 to 8, wherein the function relates to the generation of a signal for tinnitus therapy.
10. Method according to one of Claims 1 to 9, wherein parameters for controlling the signal processing can be set in the hearing aid, and wherein at least one parameter in the second operating condition exhibits a modified value compared to the value of the parameter in the first operating condition.
11. Method according to one of Claims 1 to 10, wherein, during the switching event, the weight of the first parameter decreases and the weight of the second parameter increases.
12. Method according to Claim 11, wherein the sum of the weights amounts to one.
13. Method according to one of Claims 1 to 12, wherein the switching event is controlled by a switchover algorithm.
14. Method according to one of Claims 1 to 13, wherein the switching event is triggered manually.
15. Method according to one of Claims 1 to 13, wherein the switching event is triggered automatically.
16. Method according to one of Claims 1 to 15, wherein the duration of the switching event is set.
17. Hearing aid (1) for implementing the method according to one of Claims 1 to 16, having an input transducer for picking up an input signal and converting it into an electrical signal, a signal processing unit (7) for processing and amplifying the electrical signal and an output transducer, a switching event from a first operating mode to a second operating mode of the hearing aid (1) being able to be triggered and means for the sliding transition of the hearing aid (1) from the first operating mode to the second operating mode being present, characterized in that a signal path within the hearing aid (1) is split, in a subregion between a signal input, at which an input signal (s(t)) is present, and a signal output, at which an output signal (y(t)) is present, into a first signal path and a parallel second signal path, so that the input signal (s(t)) passes through both parallel signal paths, in the first signal path the first operating mode being used in the hearing aid (1) and in the second signal path the second operating mode being used in the hearing aid (1), the hearing aid (1) having means for the weighted linkage of a first signal that results from the first operating mode and a second signal that results from the second operating mode, and, during the switching event, the weighting of the first signal decreasing and the weighting of the second signal increasing.
18. Hearing aid (1) according to Claim 17, wherein the duration of the switching event can be set.
19. Hearing aid according to Claim 18, wherein, during the switching event, the weight of the signal from the first operating condition decreases beginning with one and the weight of the signal from the second operating condition increases beginning with zero, and wherein the sum of the weights amounts to one.

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