JP2004509543A5 - - Google Patents

Description

[0007]
Acoustic feedback is an important problem in known CIC hearing aids with a vent (CIC = c omplete i n the c anal ( full ear canal)). Because the presence of the vent and the short distance between the input and output transducers of the hearing aid result in low attenuation in the acoustic feedback path from the output transducer to the input transducer, the correlation in the signal is maintained due to the short delay time It is.

[0038]
According to a preferred embodiment of the present invention, the hearing aid operates in parallel with the first set of adaptive filters, ie acts on the same signal, but with a first convergence of the first set of adaptive filters There is further provided a second set of adaptive filters having a second convergence rate that is faster than the rate. The outputs of the first set of adaptive filters are provided to corresponding inputs of the processing unit whereby the acoustic feedback signal is substantially removed from the signal prior to processing by the processing unit. The outputs of the second set of adaptive filters are not used to correct the processor's input signal.

[0039]
In this embodiment, the controller is configured to estimate the amount of acoustic feedback by determining the parameters of the second set of adaptive filters. The fast second convergence rate allows the second adaptive filter to track the acoustic feedback more closely in time than the first adaptive filter. Furthermore, the desired signal is not distorted by the second adaptive filter, as the output signal of the second adaptive filter is not subtracted from the input transducer signal.

[0040]
Thus, in accordance with a preferred embodiment of the present invention, the second filter coefficients for suppressing feedback in the hearing aid by filtering the second band-filtered electrical signal into respective fourth electrical signals are used. Generating a fifth electrical signal by subtracting the second set of adaptive filters and the fourth electrical signal from the respective first band-filtered electrical signal, and processing the fifth electrical signal A hearing aid is provided, further comprising a coupling node for supplying the device, wherein the second filter coefficients are updated with a second convergence rate that is faster than the first convergence rate.

[0041]
The amount of acoustic feedback can be estimated by determining the ratio between the amplitude of the signal at the input of the second set of adaptive filters and the amplitude of the signal at the output of the second set of adaptive filters . In this way, a quick response to changes in the acoustic feedback path is achieved, while requiring very little processor power.

[0042]
The second parameter may be a second convergence rate or adaptation rate of the first set of adaptive filters. For example, the adaptation speed of the filtering may increase the adaptation speed of the first adaptive filter whenever the hearing aid approaches a high risk of producing unwanted sounds, eg caused by a sudden change in the acoustic environment Depending on the operating gain of the processor, or the attenuation of the second set of adaptive filters, or a combination thereof, it may be possible to quickly compensate for this change.

[0043]
As already described for the second set of adaptive filters, the convergence speed of the first set of adaptive filters may be adjusted by modifying the algorithm that updates the filter coefficients of the adaptive filters. As described further below, the algorithm may include one or more scaling factors that may be adjusted in response to the determination of the second parameter. For example, one or more scaling factors may be set as a predetermined function of the operating gain of the processing device.

[0044]
The first set of adaptive filters provides individual filtering of the signal in each frequency band. Preferably, the frequency band of the first set of adaptive filters is substantially identical to the frequency band of the second filter bank.

[0045]
The frequency bands of the first set of adaptive filters may differ in number and range from the frequency bands of the first filter bank and the second set of adaptive filters. However, in the preferred embodiment of the present invention, the second filter bank comprises a plurality of band pass filters, while the first set of adaptive filters corrects the processor's input signal in a single frequency band. It consists of a single adaptive filter that A hearing aid with frequency dependent compensation can thus be provided with a simple single-band acoustic feedback compensation loop.

[0046]
Thus, according to a preferred embodiment of the present invention, a second adaptation with a second filter factor which suppresses feedback in the hearing aid by filtering the second electrical signal into a fourth electrical signal. A filter and generating a fifth electrical signal by subtracting the fourth electrical signal from the first electrical signal and supplying the fifth electrical signal to the respective band pass filters of the first filter bank A hearing aid is obtained, further comprising a coupling node, wherein the second filter coefficients are updated with a second convergence rate that is faster than the first convergence rate.

[0047]
Thus, in the preferred embodiment of the present invention, the processing unit and the second adaptive filter are divided into channel (s) covering the same frequency band (s) while the first adaptive filter is , Not divided into a plurality of channels. In addition, the controller may be configured to control the individual maximum gain limit G _max of each processor channel in response to the determination of the attenuation of the corresponding first adaptive filter channel. The controller further has a gain of G _{max for the} corresponding processor channel The second convergence rate of one of the second set of adaptive filters may be configured to increase the second convergence speed of the second set of adaptive filters when limited by a limit and thus the duration of the gain limit is reduced. Furthermore, the controller may be configured to adjust the gain limit and / or the convergence rate according to the current operating mode of the hearing aid. The term operating mode is explained below.

である。[0051]
In the FIR filter or the warped FIR filter, the next sample Y (t + T) is calculated according to the following equation.
[Equation 7]

It is.

[0070]
The output signal 80 is sent to the output transducer 5 and an optional (optional) delay Δ, and the delayed signal 83 is provided to the adaptive filter A, reference numeral 10. The output transducer 5 converts the output signal 80 into an acoustic output signal. A portion of this acoustic signal propagates to the input transducer 1 along a feedback path 6 with a transfer function H _fb . Preferably, the time delay of the delay line Δ is substantially equal to the transit time along the feedback path 6 from the output transducer 5 to the input transducer 1. Other time delays may be selected. However, shorter time delays or zero time delays complicate the filtering. For example, if the filter is a finite impulse response filter, a longer filter, i.e. a filter with more taps, is required. For this purpose, a further delay is inserted into the circuit at the output of the processing unit 7 and the delayed signal is supplied to the output transducer 5 and the optional delay Δ, whereby the input signal 4 and the filtered signal 85 Correlation may be reduced.

[0071]
In the adaptive filter 10, the delayed signal 83 is filtered to obtain a filtered signal 85 which is an estimate of the acoustic feedback. That is, the filtered signal 85 is an estimate of a portion of the transducer generated signal 4 generated by receiving the sound originating from the output transducer 5. The filtered signal 85 is subtracted from the digital input signal 4 at the combining node 9 to obtain a feedback compensation signal 86, which is input to the digital processing unit 7. In order to compensate for changes in the acoustic feedback path, the filter coefficients of the adaptive filter 10 are continuous so that the filtered signal 85 remains substantially identical to the feedback signal 6 propagating along the feedback path 6 Updated to

[0079]
FIG. 2 shows a multi-channel embodiment of a hearing aid according to the invention, in which each channel operates generally in the same way as the single-channel embodiment shown in FIG. There is. Corresponding parts of FIGS. 1 and 2 are indicated with the same reference numerals, except that the reference numerals of FIG. 2 have been suffixed. Only three channels are illustrated in FIG. 2 for simplicity. However, it should be noted that the hearing aid may include any suitable number of channels.

[0087]
The hearing aid illustrated in FIG. 3 corresponds to the hearing aid in FIG. 1 provided with an additional measuring device. Corresponding parts are indicated with the same reference symbols and the description of the operation of these parts is not repeated. The hearing aid shown in FIG. 3 additionally operates in parallel with the first adaptive filter A, 10, ie operates on the same signal as the first adaptive filter A, 10, but the first adaptive filter A, a second adaptive filter B operating at a second convergence rate faster than the first convergence rate of A, 10, reference numeral 11. The output 85 of the first adaptive filter A, 10 is supplied to the coupling node 9 and subtracted from the signal 4 to generate a signal 86 which is input to the processing unit 7, whereby the acoustic feedback signal is processed by the processing unit 7. The signal is substantially removed prior to processing by the It should be noted that the output 89 of the second adaptive filter B, 11 is not used for correction of the processor input.

[0088]
In this embodiment, the control unit 13 is adapted to estimate the amount of acoustic feedback by determining the parameters of the second adaptive filter B, 11. The high first convergence rate allows the second adaptive filter 11 to track acoustic feedback more closely over time than the first adaptive filter 10. Furthermore, the desired signal is not distorted by the second adaptive filter 11 since the output signal 89 of the second adaptive filter 11 is not subtracted from the input transducer signal 4.

[0089]
The first adaptive filter 10 may be any type of adaptive filter, but preferably an FIR filter or warp type using a power-normalized least mean square (power-n LMS) algorithm It is a FIR filter.

[0091]
An important advantage of the embodiment shown in FIG. 3 is that the output signal generated by the second adaptive filter 11 is not supplied to the main signal path from the input transducer 1 to the output transducer 5. This main signal path consists of an input transducer 1, digital conversion means (not shown), a coupling node 9, a digital processing unit 7 and an output transducer 5. Thus, the signal processing by the second adaptive filter 11 does not directly affect the signal in the main signal path. Because of this, no signal distortion of the signal in the main signal path is created by the second adaptive filter 11 and thus the adaptation rate of the second adaptive filter 11 to the adaptation rate of the first adaptive filter 10 It can be made substantially higher. Since the adaptation speed of the second adaptive filter 11 can be made substantially higher than the adaptation speed of the first adaptive filter 10, the feedback path is set by the second adaptive filter 11 more than that of the first adaptive filter 10. Even over time can be monitored much more closely. Preferably, the second adaptation rate is a fixed high adaptation rate, but this adaptation rate may be adjusted, for example by correcting one or more scaling factors. For example, it may be preferable to adjust the adaptation speed of the second adaptive filter according to the actual gain or input power level at the processor.

[0093]
In the event of a rapid change in the acoustic environment, the first adaptive filter 10 of FIG. 3 can not immediately adapt to such changes to compensate for these changes. Therefore, an uncompensated feedback signal will begin to be generated. However, the second adaptive filter 11 is much faster than the first adaptive filter 10 and adapts to changes in the feedback path.

[0094]
In one embodiment, the controller controls the adaptation speed of the first adaptive filter 10 such as, for example, to control the value of μ based on the rapid response of the second adaptive filter 11 to changes in the feedback path. Control. Therefore, when a change in the feedback path is indicated by a characteristic of the second adaptive filter 11, for example, a filtering characteristic such as attenuation, the first adaptive filter 10 is controlled accordingly. For example, if the gain is close to the feedback limit, the adaptation speed of the first adaptive filter 10 is increased. By increasing the adaptation speed of the first adaptive filter 10, the first adaptive filter may compensate for changes in acoustic feedback more quickly, for example, before acoustic feedback results in the generation of unwanted sound.

[0096]
In yet another embodiment, the controller reduces the gain in the digital processor when a change in feedback is detected by the second adaptive filter 11. In particular, this can be selectively performed in different channels of the digital processing device.

[0101]
The multi-channel embodiment of the invention according to FIG. 4 adds to the same components as the single-channel embodiment shown in FIG. , And a filter bank 16 for outputting a set of first adaptive filters and a set of second adaptive filters 11a, 11i and 11n. Each second set of adaptive filters 11a, 11i, 11n is filtered to be combined with the respective signal 86a, 86i, 86n from the coupling node 9a, 9i, 9n at the respective coupling node 12a, 12i, 12n. Provide a signal.

[0102]
In the multi-channel embodiment shown in FIG. 4, a more detailed estimation of the transfer function of the feedback path is achieved. Additionally, signal processing may be performed at lower sampling frequencies at lower frequency bands, a technique known as decimation. Decimation is particularly easy in these filters since the output signal from the second set of adaptive filters is not fed to the main signal path, so no anti-aliasing filter is required for the system It can be used for

[0103]
The embodiment shown in FIG. 4 can be controlled in the same manner as the embodiment shown in FIG. However, the embodiment shown in FIG. 4 selectively reduces the gain in each individual channel and selects the adaptation speed of each individual adaptive filter in the first set of adaptive filters 10a, 10i, 10n. Adjustment is possible. As a result, it is possible to maintain the gain at a high value at a frequency at which feedback resonance is unlikely to occur, and to obtain the further advantage of being able to maintain the distortion at a low level.

[0104]
FIG. 5 shows a multiple channel embodiment which is similar in construction and operates in the same manner as the embodiment shown in FIG. However, the embodiment shown in FIG. 5 has a first set of adaptive filters constituted by a single adaptive filter 10 and is more because the combining node 9 is a single combining node It is simple.

[0106]
In particular, it is possible to use a digital signal processor 7 with a relatively small number of channels, and a second set of adaptive filters, including more filters. Alternatively, the individual adaptive filters of the first set of adaptive filters may operate on the combination with the channel in the digital signal processor 7, for example two or more of the digital signal processors 7. Either the channel operates with the same G _max determined by the particular adaptive filter of the second set of adaptive filters, or one channel of the digital signal processor 7 is the adaptive filter of the second set of adaptive filters G _max which is the lowest gain among two or more gains determined by It may operate using However, at present, an embodiment comprising a single first adaptive filter 10 and a set of multi-channel second adaptive filters 11 is preferred.

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