1. Field of the Invention
The invention is directed to a method for operating a hearing aid device or hearing device system having at least one first microphone for generating a first microphone signal and a second microphone distanced from the first for generating a second microphone signal. The invention is also directed to a hearing aid device or hearing device system for implementing the method.
2. Description of the Related Art
Acoustic feedback frequently occurs in hearing aid devices, particularly for hearing aid devices having a high gain. This feedback is expressed in pronounced feedback-caused oscillations having a specific frequency, called “whistling”, that is usually extremely unpleasant both for the hearing aid user and as well as for people in the immediate surroundings.
Feedback can occur when sound that is picked up via the microphone of the hearing aid device is amplified by a signal amplifier and output via the earphone proceeds back to the microphone and is re-amplified. In order for the typical “whistling” to occur (usually at a dominant frequency), however, two further conditions must be met. First, the “loop amplification” of the system, i.e., the product of the hearing aid gain and the attenuation of the feedback path, must be greater than 1. Second, the phase shift of this loop amplification must correspond to an arbitrary whole-numbered multiple of 360°.
The simplest approach for reducing feedback-conditioned oscillations is to permanently reduce the hearing aid gain so that the loop amplification remains below the critical limit value even in unfavorable situations. The critical disadvantage of this approach, however, is that the hearing aid gain required given more pronounced hearing impairment can no longer be achieved as a result of this limitation.
Other approaches provide a measurement of the loop amplification during the hearing aid adaptation and reduce the hearing aid gain in designational fashion in the critical range with the assistance of what are referred to as notch filters (narrow-band blocking filters). Since the loop amplification, however, can constantly change during daily life, the benefit is likewise limited.
A number of adaptive algorithms have been proposed for dynamic reduction of feedback-conditioned oscillations, these automatically adjusting to the respective feedback situation and implementing corresponding measures. These methods can be roughly divided into two categories.
The first category comprises “compensation algorithms” that estimate the feedback part in the microphone signal with the assistance of adaptive filters and neutralize the feedback by subtraction and, thus, do not deteriorate the hearing aid gain. However, these compensation methods assume uncorrelated, i.e., ideally, “white”, input signals. Tonal input signals that always exhibit a high time correlation lead to an incorrect estimate of the feedback path, which can lead to the fact that the tonal input signal itself is erroneously subtracted.
The second class contains the algorithms that only become active when feedback-conditioned oscillations are present. They generally contain a mechanism for detecting oscillations that continuously monitors the microphone signal. When feedback-typical oscillations are detected, the hearing aid gain is reduced to such an extent that the loop amplification drops below the critical limit. The gain reduction can ensue, for example, by lowering a frequency channel or by activating a suitable narrow-band stop filter (notch filter). This is disadvantageous because the oscillation detectors can fundamentally not distinguish between tonal input signals and feedback whistling. The result is that tonal input signals are interpreted as feedback oscillations and are then incorrectly reduced in level due to the reduction mechanism (for example, notch filters).
Delay elements that have a decorrelating effect are often introduced into the signal processing chain in the compensation algorithms in order to prevent tonal signal segments having a length characteristic for voice signals from being noticeably attacked. Due to echo effects and irritations as a result of desynchronized visual and auditive information, however, only delays in the range milliseconds are allowed. For example, the reduction of music to signals, which are often correlated over a clearly longer time span, cannot be avoided. A further counter-measure is comprised in retarding the adaptation of the filter so long that all relevant tonal useful signals are not attacked. However, this also results in the compensation filter no longer being able to follow rapid changes of the feedback path quickly enough, so that feedback-conditioned oscillations arise for a certain time and in turn disappear only when the feedback path has stabilized and the filter has again adequately adapted. The negative consequences of incorrect detection of oscillation detectors are countered in that the resulting reduction in gain occurs to only a limited extent, so that tonal useful signals erroneously considered to be feedback-conditioned oscillations (for example, alarm signals) still remain audible. This, however, harbors the risk that the reduction of gain in the feedback case does not suffice in order to fall below the critical limit and thus eliminate the “whistling”.
In summary, the functioning of all adaptive feedback-reduction methods is deteriorated by input signals that exhibit a tonal character affected by dominant sine signal parts (for example, triangle tones, alarm signals). This often leads to unacceptable tonal deteriorations of the input signal.
German patent document DE 693 27 992 T2 discloses a feedback-suppression arrangement with adaptive filtering for a hearing prosthesis that comprises two microphones in a specific embodiment. It does not implement a detection of oscillations.
U.S. Pat. No. 6,072,884 A discloses a device for suppressing feedbacks that likewise comprises two microphones. It does not implement a detection or a comparison of oscillations.
German patent document DE 199 22 133 A1 discloses a hearing aid device with an oscillation detector. This device comprises only one microphone, so that a comparison of a plurality of microphone signals is not possible.
An object of the present invention is to provide a method for operating a hearing aid device or hearing device system as well as a hearing aid device or hearing device system that avoids feedback-conditioned oscillations without noticeably deteriorating the sound quality.
This object is inventively achieved by a method for operating a hearing aid device or hearing device system, comprising generating a first microphone signal from at least one first microphone; generating a second microphone signal from at least one second microphone that is distanced from the at least one first microphone; comparing the first microphone signal and the second microphone signal; recognizing feedback-conditioned oscillations based on the comparing; and reducing the feedback-conditioned oscillations when they are recognized as such.
This object is also achieved by a hearing aid device or hearing device system, comprising at least one first microphone configured to generate a first microphone signal; at least one second microphone distanced the first microphone configured to generate a second microphone signal; a signal processing unit configured to process the first microphone signal and the second microphone signal; a comparison unit configured to compare the first and second microphone signals or signals derived from them and to recognize feedback-conditioned oscillations; and a feedback-conditioned oscillation reducer.
The invention can be employed in all standard types of hearing aid devices, for example, given hearing aid devices to be worn behind the ear, hearing aid devices to be worn in the ear, implantable hearing aid devices or pocket devices. Furthermore, a hearing device system composed of a plurality of devices can also be utilized for serving a hearing-impaired person, for example, a hearing device system having two hearing devices worn at the head for binaural coverage. The microphone signals that are analyzed for the recognition of feedback-conditioned oscillations can then also proceed from different devices.
In the invention, microphone signals of at least two microphones distanced from one another are generated. At least one microphone must be arranged such that it does not pick up feedback-conditioned oscillations of a hearing aid device or at most picks them up in highly attenuated form. Useful signals, however, should be picked up by the appertaining microphones in a similar way. By analysis and comparison of the microphone signals or signals derived from them, a distinction can be made between feedback-conditioned oscillations and useful signals with high reliability. In particular, the microphone signals generated by the microphones also hardly differ given tonal useful signals so that these are recognized as useful signals. Feedback-conditioned signals, which differ from these, are picked up very differently by the microphones due to the arrangement of the microphones, so that these signals are recognized as feedback-conditioned from the comparison of the microphone signals and can be reduced with suitable measures.
The distance between the microphones whose microphone signals are compared to one another can, for example, be produced by attaching one microphone to a collar clip. Another possibility is to provide a hearing aid system having two hearing devices for binaural coverage. The comparison can then ensue between a microphone signal or a signal derived from it from the one hearing aid device to a microphone signal or a signal derived from it from the second hearing aid device. Useful signals are then registered in approximately the same way by the two microphones and feedback-conditioned oscillations that arise at a hearing aid device are not acquired by the other hearing aid device. A signal path is provided for the signal transmission between the hearing aid devices. The signal transmission can occur wirelessly or wire-bound. In order to keep the energy consumption required for the data transmission as low as possible, it is advantageous to not directly transmit the microphone signal but a signal derived from it. The derived signal comprises characteristic quantities of the microphone signal that are relevant for the recognition of oscillations. For example, these are the oscillation frequencies of the microphone signal and the signal strength at the respective oscillation frequencies.
When feedback simultaneously occurs in both hearing aid devices of a hearing device system, then it can still nonetheless be detected due to differences in the feedback. The differences can be caused, on the one hand, by different gain settings and frequency responses of the hearing aid devices, due to what is usually a different degree of hearing impairment at the two ears. On the other hand, individual variances of the feedback paths of the ears, for example, due to a different seating of the hearing aids, cause different oscillations.
Furthermore, device tolerances also contribute to the fact that feedback-conditioned oscillations occurring simultaneously in two different hearing aid devices differ. This means that there is a high probability that feedback-conditioned oscillations in the individual hearing aid devices occur at different frequencies. A tonal useful signal (for example, a sine signal), in contrast, appears at the same frequency at both sides. When an oscillation is detected at one side, then it is a feedback signal issue only when no oscillation at this frequency is detected from the microphone signal of the other hearing aid device. When, in contrast, an oscillation at the same frequency is detected at both hearing aid devices, then there is a great probability that this is a sine-shaped input signal.
In one embodiment of the invention, a correlation analysis is undertaken for comparing the microphone signals of two distanced microphones for recognizing feedback-conditioned oscillations. Different frequencies of feedback-conditioned oscillations in two microphone signals mean that no significant, correlated signal parts exist in the respectively other microphone signal for the oscillation signal of the one microphone. In the feedback case, the two microphone signals are thus only slightly correlated. In contrast, a high correlation is present in the case of a useful tonal signal. This is true not only of tonal signals; each signal coming from a useful sound source enters two hearing aid microphones distanced from one another with a high cross-correlation value.
When feedback-condition oscillations have been recognized from the comparison of microphone signals or signals derived from them, then reducing the hearing aid gain provides one possibility of suppressing these oscillations. When the signal processing in a hearing aid occurs in a plurality of parallel channels of a signal processing unit, then the hearing aid gain in one embodiment of the invention can be reduced only in the frequency channels in which feedback-conditioned oscillations are present.
The invention provides another possibility for reducing feedback-conditioned oscillations by eliminating these oscillations with narrow-band filters whose limit frequencies approximately coincide with the oscillation frequencies or with other feedback-conditioned oscillation reducers. For example, the filters can be implemented as notch filters. When one notch filter does not suffice, then further notch filters at the respective frequency are activated given a renewed detection of oscillations.
In another embodiment of the invention, when an adaptive filter for reducing feedback-conditioned oscillations is employed in a hearing aid device, then the adaptive compensation filter is adapted when feedback-conditioned oscillations are recognized. For example, the operating parameters of the filter can be varied such that the adaptation speed is increased. Conversely, the adaptation speed of the adaptive compensation filter is reduced when no feedback-conditioned oscillations are detected. This principle can be analogously applied to compensation filters based on the frequency range. Both the correlation analysis for recognizing feedback-conditioned oscillations as well as the regulation of the adaptation speed can advantageously take place in a frequency-specific manner.
When a hearing aid device of the invention recognizes feedback-conditioned oscillations on the basis of a correlation analysis of two microphone signals (cross-correlation), then there is a further possibility for reducing these oscillations by suppressing uncorrelated frequency parts of the microphone signals. Only those signal parts that are essentially uniformly present in all microphone signals are then further-processed.
Further details of the invention are explained in greater detail below on the basis of the exemplary embodiments shown in the drawings.
The hearing aid device schematically shown in
As shown in
The invention is not limited to the illustrated exemplary embodiments but can be expanded by a number of modifications. For example, more than two microphone signals can also be compared to one another for the recognition of feedback-conditioned oscillations. Furthermore, the signal processing in a hearing aid device of the invention can ensue in parallel in a plurality of channels of the signal processing unit. The comparison of microphone signals or the correlation analysis can then likewise ensue in parallel in a plurality of channels. Measures for reducing recognized feedback-conditioned oscillations are then advantageously limited only to the appertaining channels. Furthermore, the comparison or the correlation analysis of microphone signals can ensue continuously or only at times dependent on specific parameters (for example, the hearing program that has been set or the volume setting).
The particular implementations shown and described herein are illustrative examples of the invention and are not intended to otherwise limit the scope of the invention in any way. Indeed, for the sake of brevity, conventional electronics, control systems, optics, software development and other functional aspects of the systems (and components of the individual operating components of the systems) may not be described in detail. Furthermore, the connecting lines, or connectors shown in the various figures presented are intended to represent exemplary functional relationships and/or physical or logical couplings between the various elements. It should be noted that many alternative or additional functional relationships, physical connections or logical connections may be present in a practical sensor device. Moreover, no item or component is essential to the practice of the invention unless the element is specifically described as “essential” or “critical”.
The above-described method and apparatus are illustrative of the principles of the present invention. Numerous modifications and adaptations will be readily apparent to those skilled in this art without departing from the spirit and scope of the present invention.
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101 10 258 | Mar 2001 | DE | national |
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20020176594 A1 | Nov 2002 | US |