EP1239700A2 - Method of operating a hearing device or hearing system and a corresponding device and system - Google Patents

Abstract

In the case of a hearing aid (2; 11, 11 '), microphone signals of a first microphone (1; 12) and a spaced-apart second microphone (4; 12') are compared with one another to reduce feedback-related oscillations. If oscillations at the same frequency are detected in both microphone signals, these are tonal useful signals. In contrast, oscillations that are only present in one of the microphone signals are feedback-related and are suppressed by suitable measures. The hearing aid system can consist of two hearing aids, the first microphone being arranged in the first hearing aid and the second microphone being arranged in the second hearing aid. <IMAGE>

Description

The invention relates to a method for operating a hearing aid or hearing aid system with at least a first Microphone for generating a first microphone signal and a spaced-apart second microphone for generating a second microphone signal. The invention further relates to a Hearing aid or hearing aid system for performing the method.

Acoustic feedback is common in hearing aids especially when it comes to hearing aids with high Reinforcement acts. These feedbacks are expressed in strong feedback-related oscillations of a certain Frequency (feedback). This "whistling" is usually both for the hearing aid wearer as well as for people in his vicinity Environment very uncomfortable.

Feedback can occur when sound is heard through the microphone of the hearing aid, recorded by a signal amplifier amplified and output through the handset, back to the microphone reached and strengthened again. So that it's typical "Whistling" - mostly at a dominant frequency - two additional conditions must be met. The so-called loop gain of the system, i.e. the Product of the hearing aid amplification and the weakening of the Feedback path, must be greater than 1. Furthermore must the phase shift of this loop gain one correspond to any integer multiples of 360 °.

The simplest approach to reducing feedback Oscillation is the permanent reduction in hearing aid gain, so the loop reinforcement even in awkward Situations remains below the critical limit. The crucial disadvantage, however, is that this limitation the hearing aid reinforcement required for people with severe hearing loss can no longer be achieved.

Other approaches see a measurement of the loop gain during the hearing aid fitting before and reduce with the help So-called notch filter (narrow-band blocking filter) the hearing aid amplification targeted in the critical area. Since the However, loop reinforcement is constantly changing in everyday life the benefit is also limited.

For the dynamic reduction of feedback-related oscillations a number of adaptive algorithms have been proposed been automatically based on the respective feedback situation adjust and take appropriate measures. This Processes can be roughly divided into two classes:

The first class includes the so-called compensation algorithms, which with the help of adaptive filters the feedback portion in the Estimate the microphone signal and neutralize it by subtraction and therefore do not impair hearing aid amplification. Indeed put these compensation methods uncorrelated, i.e. ideally "white", input signals ahead. Tonale Input signals that always have a high temporal correlation lead to an incorrect estimate of the feedback path, which can mistakenly lead to that tonal input signal itself is subtracted.

The second class contains the algorithms that only then become active if there are feedback-related oscillations are. They generally contain a mechanism to detect oscillations of the microphone signal continuously supervised. Become feedback-typical oscillations detected, the hearing aid gain is reduced so far that the loop gain is below the critical limit sinks. The gain reduction can e.g. by lowering a frequency channel or by activating a suitable one narrow-band notch filter. adversely is that the oscillation detectors in principle not between tonal input signals and feedback whistles can distinguish. The result is that tonal input signals mistaken for feedback oscillations and then inadmissible through the reduction mechanism (e.g. notch filter) be lowered in level.

The compensation algorithms often become decorrelating acting delay elements in the signal processing chain introduced to prevent tonal signal sections with a length that is characteristic of speech signals be attacked noticeably. However, due to Echo effects and irritation through desynchronized visual and auditory information only delays in the millisecond range allowed. Therefore, for example, the reduction of music signals, often over a significantly longer period Period are correlated, cannot be avoided. A another countermeasure is to adapt the filter so slow that all relevant tonal useful signals not be attacked. However, this also has the consequence that the compensation filter changes rapidly Feedback paths can no longer follow fast enough, so that feedback-related oscillations for a certain time arise and only disappear when the Feedback path has stabilized and the filter is sufficient again is adapted enough. The negative consequences of incorrect detection One encounters oscillation detectors in that the resulting reduction in gain is limited Measurements take place, so erroneously for feedback-related Tonal useful signals held by oscillations (e.g. Alarm signals) remain audible. However, this hides the Danger that the gain reduction is not in the case of feedback sufficient to go below the critical limit and thus to eliminate the "whistle".

In summary, it can be said that the mode of operation all adaptive feedback reduction procedures Input signals that a dominant sinusoidal signal have an embossed tonal character (e.g. triangle tones, Alarm signals). This often leads to unacceptable deterioration in sound of the input signal.

The object of the present invention is to provide a method for Operation of a hearing aid or hearing aid system and a Specify hearing aid or hearing aid system in which feedback-related Oscillations can be avoided without doing so the sound quality deteriorate noticeably.

From DE 693 27 992 T2 is one Feedback suppression arrangement with adaptive filtering known for a hearing prosthesis, which in a special Embodiment has two microphones. A detection of Oscillations are not carried out.

From US 6,072,884 A is a device for suppressing known from feedbacks, which are also two microphones having. A detection or a comparison of oscillations is not performed.

DE 199 22 133 A1 describes a hearing aid with a Oscillation detector known. This device only instructs Microphone on, allowing a comparison of multiple microphone signals not possible.

The task for the method is solved by the features of claim 1. Advantageous process variants are characterized in claims 2 to 8. The hearing aid or part of the task relating to the hearing aid system is solved by the features of claim 9. Advantageous Device variants are in the claims 10 to 16 specified.

The invention can be used with all common hearing aid types can be used, for example, behind the ear wearable Hearing aids, in the ear portable hearing aids, implantable hearing aids or handheld devices. Farther one of several can be used to care for the hearing impaired Existing hearing aid systems are used, e.g. a hearing aid system with two hearing aids worn on the head for binaural care. The microphone signals used for Detect feedback-related oscillations analyzed different devices.

In the invention, microphone signals are at least two spaced microphones generated. At least it has to a microphone be arranged so that it is feedback-related Hearing aid device does not oscillate or at most in a weakened form. useful signals are said to be similar in the microphones concerned Way to be included. By analyzing and comparing the Microphone signals or signals derived from them are a distinction between feedback-related oscillations and useful signals with high security possible. In particular The tonal useful signals then differ from the microphones hardly generated any microphone signals, so this are recognized as useful signals. In contrast to this through the arrangement of the microphones feedback-related signals recorded very differently by the microphones, so that this results from the comparison of the microphone signals as feedback recognized and reduced by suitable measures can be.

The distance between the microphones, their microphone signals can be compared with each other, for example by the Attaching a microphone to a collar clip become. Another possibility is a hearing aid system with two hearing aids for binaural care. The comparison can then between a microphone signal or a derived signal of a hearing aid with a Microphone signal or a signal derived therefrom second hearing aid. Useful signals are then from the two microphones recorded approximately the same and due to feedback Oscillations on a hearing aid arise, are not detected by the other hearing aid. For signal transmission is between the hearing aids a signal path is provided. The signal transmission can done wirelessly or wired. To the for data transmission keep the required energy requirements as low as possible, it is advantageous not to directly use the microphone signal transmitted, but a signal derived from it. The derived one Signal comprises characteristic parameters of the microphone signal, that are relevant to detecting oscillations are. For example, these are the oscillation frequencies of the Microphone signal and the signal strength at the respective oscillation frequencies.

Occurs in both hearing aids of a hearing aid system feedbacks at the same time, so they will still differ. The differences can be differentiated on the one hand Gain settings and frequency responses the hearing aids, due to a mostly different Severe hearing damage to both ears become. On the other hand, individual variances cause Feedback paths of the ears, e.g. through different Seat of the hearing aids, different oscillations. Farther device tolerances will also contribute to the fact that two different hearing aids occurring simultaneously Distinguish feedback-related oscillations. This means that there is a high likelihood of feedback Oscillations in the individual hearing aids occur at different frequencies. A tonal useful signal, e.g. a sine signal, however, appears on both Sides at the same frequency. So becomes one on one side Oscillation detected, so it is only a Feedback signal when from the microphone signal of the other Hearing aid detected no oscillation at this frequency becomes. In contrast, can be used on both hearing aids determine oscillation at the same frequency it is almost certainly a sinusoidal input signal.

To compare the microphone signals of two spaced-apart microphones to detect feedback-related oscillations in a variant of the invention, a correlation analysis performed. Different frequencies due to feedback Oscillations in two microphone signals mean that the Oscillation signal of one microphone is not essential correlated signal components in the other microphone signal exist. In the case of feedback, both are microphone signals correlated little. In contrast to this results in there is a high correlation in the case of a tonal useful signal. This applies not only to tonal signals, but to everyone signal coming from a useful sound source coincides with a high cross-correlation value in two spaced apart Hearing aid microphones.

Was from the comparison of microphone signals or from these derived signals, feedback-related oscillations detected, so is the reduction in hearing aid gain a way to suppress it. Signal processing takes place in one hearing aid in several parallel Channels of a signal processing unit, according to one Variant of the invention, the hearing aid gain only in the frequency channels are reduced in which feedback-related There are oscillations.

Another way to reduce feedback The invention forms oscillations by means of these narrow-band filter, whose cut-off frequencies roughly match the To eliminate oscillation frequencies. The Filters can e.g. be designed as a notch filter. Enough a notch filter does not turn off when it is detected again of oscillations further notch filters at the respective frequency activated.

Is an adaptive filter for reduction in a hearing aid device feedback-related oscillations used, so is detected according to a variant of the invention when feedback-related Oscillations the adaptive compensation filter customized. For example, the operating parameters of the filter are changed so that an increase in the Adaptation speed takes place. The rate of adaptation is reversed of the adaptive compensation filter reduced, if no feedback-related oscillations are detected become. This principle can also be applied analogously to frequency range-based Apply compensation filter. Either the correlation analysis to identify feedback-related Oscillations as well as the regulation of the adaptation speed can advantageously be frequency-specific.

Detects a hearing aid device according to the invention due to feedback At least oscillations based on a correlation analysis two microphone signals (cross correlation), so there is another way to reduce these oscillations therein, uncorrelated frequency components of the microphone signals to suppress. Then only the signal components processed further, essentially in all microphone signals are equally present.

Figur 1 schematisch ein Hörhilfegerät, bei dem durch Vergleich zweier Mikrofonsignale rückkopplungsbedingte Oszillationen erkannt werden, und

Figur 2 zwei Hörhilfegeräte, zwischen denen zum Erkennen rückkopplungsbedingter Oszillationen ein Signalaustausch vorgesehen ist.

Further details of the invention are explained in more detail below with reference to the exemplary embodiments shown in the drawing. Show it:

Figure 1 schematically shows a hearing aid in which feedback-related oscillations are detected by comparing two microphone signals, and

Figure 2 shows two hearing aids, between which a signal exchange is provided to detect feedback-related oscillations.

The hearing aid shown schematically in Figure 1 includes a microphone 1, a signal processing unit 2 and one Handset 3. Receives sound that is output through the handset 3 becomes microphone 1 again, feedback-related Oscillations (feedback) arise. Conditions for this are that the so-called loop gain of the system, i.e. the product of hearing aid amplification and attenuation of the feedback path is greater than 1 and that the phase shift this loop gain an integer Corresponds to multiples of 360 °. According to the hearing aid Figure 1 is an evaluation and control unit 5 in addition to the Microphone signal of the microphone 1 another microphone signal supplied by a microphone 4. The two microphones 1 and 4 are arranged so that useful sound from both microphones is in is recorded approximately equally. Outgoing from the handset 3 However, sound cannot be attenuated, or at least greatly attenuated get to the microphone 4. For this purpose, the microphone 4 for example on a collar clip outside the housing, in which the microphone 1 is arranged attached. In the evaluation and control unit 5 are those emanating from the microphones Microphone signals analyzed and compared. For example, through auto correlation analysis Oscillations in the individual microphone signals are detected become. If there are oscillations in both microphone signals, so their frequencies are determined and compared with each other. With oscillations in both microphone signals are equally present, it is with great certainty around tonal input signals. With oscillations that only in a microphone signal, especially that of a microphone 1 outgoing microphone signal are present with a high probability of feedback-related oscillations. To eliminate them, the Signal processing unit 2 by means of the evaluation and control unit 5. For example, for filtering out the oscillation frequencies in the signal processing unit 2 narrowband Notch filter can be activated and adjusted.

As shown in Figure 1, the microphone signals of the Microphones 1 and 4 also initially each have a signal preprocessing unit 6 and 7 can be supplied. The signal preprocessing can, for example, an A / D conversion or a Include signal pre-amplification.

Figure 2 shows two hearing aids 11 and 11 ', each with one Microphone 12 or 12 ', a signal processing unit 13 or 13 'and a receiver 14 or 14'. One oscillation detector each 15 or 15 'continuously monitors the microphone signal on oscillations and determined when oscillations are detected the oscillation frequencies. Between the hearing aids 11 and 11 'there is a signal path 17 for signal exchange between the hearing aids, the wireless or wired can be done. So according to the invention the signal path 17 an exchange of the detected oscillation frequencies. In the comparison units 16 and 16 ' the oscillation frequencies of the hearing aid in question with the oscillation frequencies of the other hearing aid compared. With matching oscillation frequencies it is almost certainly not a question of feedback Oscillations, but the useful signal has at these frequencies a strong tonal character. Will be against in a hearing aid an oscillation at a certain Frequency detected at which there is no oscillation in is reported to the other hearing aid in each case it is most likely a feedback-related Oscillation. The oscillation frequency will then turn on the control unit 18 or 18 'passed on. This control unit calculates and activates this at the present oscillation frequency suitable notch filter N1 or N1 ', which is then targeted at the frequency at which the oscillation is detected the gain has been reduced. The loop reinforcement this decreases for a narrowband frequency range below the critical limit and the feedback-related oscillation disappears. Because very narrow-band notch filters can be used, the effect is limited to one narrow frequency range, so that appreciable gain losses or loss of sound can be avoided. Submits Notch filter does not turn off, so if Oscillations of further notch filters N2 to NN or N2 'to NN' be activated at the respective frequencies.

The invention is not based on the illustrated embodiments limited, but expandable by a variety of variants. For example, feedback-related can be used to identify Oscillations also have more than two microphone signals be compared with each other. Furthermore, the signal processing in parallel with a hearing aid according to the invention take place in several channels of the signal processing unit. The comparison of microphone signals or the correlation analysis can then also run in parallel in several channels respectively. Measures to reduce detected feedback-related Oscillations are then advantageous only to that channels concerned. In addition, the comparison or the correlation analysis of microphone signals continuously or depending on certain parameters (e.g. the set hearing program or volume setting) done only temporarily.

Claims (16)

Method for operating a hearing aid device or hearing aid system (11, 11 ') with at least one first microphone (1; 12) for generating a first microphone signal and a second microphone (4; 12') spaced therefrom for generating a second microphone signal, characterized in that by comparing the microphone signals or signals derived therefrom, feedback-related oscillations are recognized and measures are taken to reduce the feedback-related oscillations when feedback-related oscillations are detected. Method for operating a hearing aid device or hearing aid system according to claim 1, characterized in that both microphone signals are examined for the presence of oscillations and a feedback-related oscillation is determined at an oscillation frequency in which oscillation is only present in one of the two microphone signals. Method for operating a hearing aid device or hearing aid system according to claim 1 or 2, characterized in that the microphone signals are subjected to a correlation analysis and feedback-related oscillations are recognized at the frequencies at which there are no correlated signal components in another microphone signal for an oscillation in a microphone signal. Method for operating a hearing aid device or hearing aid system according to one of claims 1 to 3, characterized in that the hearing aid gain is reduced when feedback-related oscillations are detected. Method for operating a hearing aid device or hearing aid system according to claim 4, wherein the signal processing takes place in several parallel channels of a signal processing unit (2; 13, 13 '), characterized in that when feedback-related oscillations are detected, the hearing aid gain of the channel in which the oscillation frequency lies is reduced , Method for operating a hearing aid device or hearing aid system according to one of claims 1 to 5, characterized in that detected feedback-related oscillations are reduced by activating and / or adapting filters (N1, N2, NN, N1 ', N2', NN '). Method for operating a hearing aid device or hearing aid system according to one of claims 1 to 6 with an adaptive compensation filter for reducing feedback-related oscillations, characterized in that the adaptive compensation filter is adapted when feedback-related oscillations are detected. Method for operating a hearing aid device or hearing aid system according to one of Claims 1 to 7, characterized in that uncorrelated frequency components of the microphone signals are reduced in order to suppress feedback-related oscillations. Hearing aid or hearing aid system (11, 11 ') with at least one first microphone (1; 12) for generating a first microphone signal, a second microphone (4; 12') spaced apart from it for generating a second microphone signal and a signal processing unit (2; 13, 13 '), characterized in that the hearing aid or hearing aid system (11, 11') comprises means for comparing the microphone signals or signals derived therefrom for recognizing feedback-related oscillations and means for reducing recognized feedback-related oscillations. Hearing aid or hearing aid system according to claim 9, characterized in that the hearing aid or hearing aid system (11, 11 ') means for detecting an oscillation and for determining the oscillation frequency in the first microphone signal, means for detecting an oscillation and for determining the oscillation frequency in the second microphone signal and has means for comparing the oscillation frequencies determined in the two microphone signals. Hearing aid or hearing aid system according to claim 9 or 10, characterized by means for performing a correlation analysis of the microphone signals. Hearing aid or hearing aid system according to one of claims 9 to 11, characterized by means for reducing the hearing aid gain. Hearing aid or hearing aid system according to one of Claims 9 to 12, in which the signal processing takes place in a plurality of parallel channels of the signal processing unit (2; 13, 13 '), characterized by means for reducing the hearing aid amplification in one channel. Hearing aid or hearing aid system according to one of claims 9 to 13, characterized by adaptive filter means with adjustable operating parameters for reducing detected feedback-related oscillations. Hearing aid system according to one of claims 9 to 14 with at least one first hearing aid and a second hearing aid, characterized in that the first microphone (12) for generating the first microphone signal in the first hearing aid (11) and the second microphone (12 ') for generating of the second microphone signal is arranged in the second hearing aid (11 '). Hearing aid system according to claim 15, characterized by a wireless signal path (17) for transmitting the microphone signals or signals derived therefrom between the hearing aid devices (11, 11 ').

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