JP2010171674A - Hearing aid - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To extend the life of a battery of a hearing aid. <P>SOLUTION: A gain adjustor 13 includes: a channel power calculating section 14 with its input side connected between a frequency analyzer 8 and a gain setting unit 9; and a saturation gain suppressing section 15 and a gain table reference section 16, which are connected in parallel to the output side of the channel power calculating section 14. The output of the gain table reference section 16 is connected to the saturation gain suppressing section 15, the output side of a threshold setting section 17 is connected to the saturation gain suppressing section 15, and the output side of the saturation gain suppressing section 15 is connected to the gain setting unit 9. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a hearing aid.

  There are two types of signal processing for hearing aids, the subband method and the FFT method, but the FFT method is attracting attention because of its faster response. The structure of the FFT system is as follows (see, for example, Patent Document 1).

That is, a microphone, an AD (Analog to Digital) converter connected to the output side of the microphone, a frequency analyzer connected to the output side of the AD converter, and an output side of the frequency analyzer Gain setter, a frequency synthesizer connected to the output side of the gain setter, a DA (Digital to Analog) converter connected to the output side of the frequency synthesizer, and an output side of the DA converter And a gain adjuster having an input side connected between the frequency analyzer and the gain setter and an output side connected to the gain setter.
JP-A-6-105399

  The problem in the conventional example is that the battery life is shortened. That is, in the conventional example, when the sound input to the microphone becomes loud, the frequency synthesizer also needs a wide bit width in order to process the loud sound. If the bit width of the frequency synthesizer increases, the bit width of the DA converter on the output side naturally increases, and as a result, the power consumption in these frequency synthesizer and DA converter increases. This shortens the battery life.

  Therefore, the object of the present invention is to extend the battery life.

  In order to achieve this object, the present invention includes a microphone, an AD converter connected to the output side of the microphone, a frequency analyzer connected to the output side of the AD converter, and the frequency analyzer. A gain setter connected to the output side of this, a frequency synthesizer connected to the output side of this gain setter, a DA converter connected to the output side of this frequency synthesizer, and the output of this DA converter And a gain adjuster having an input side connected between the frequency analyzer and the gain setter and an output side connected to the gain setter, the gain adjuster comprising: A channel power calculation unit having an input side connected between the frequency analyzer and the gain setting unit, and a saturation gain suppression unit and a gain table connected in parallel to the output side of the channel power calculation unit. And connecting the output of the gain table reference unit to the saturation gain suppression unit, connecting the output side of the threshold setting unit to the saturation gain suppression unit, and connecting the output side of the saturation gain suppression unit to the saturation gain suppression unit Connected to the gain setter, thereby achieving the intended purpose.

  The present invention relates to a microphone, an AD converter connected to the output side of the microphone, a frequency analyzer connected to the output side of the AD converter, and a gain setting connected to the output side of the frequency analyzer. A frequency synthesizer connected to the output side of the gain setter, a DA converter connected to the output side of the frequency synthesizer, a receiver connected to the output side of the DA converter, A gain adjuster having an input side connected between the frequency analyzer and the gain setter and an output side connected to the gain setter, the gain adjuster comprising: the frequency analyzer and the gain setter; A channel power calculation unit having an input side connected in between, and a saturation gain suppression unit and a gain table reference unit connected in parallel to the output side of the channel power calculation unit. The output of the bull reference unit is connected to the saturation gain suppression unit, the output side of the threshold setting unit is connected to the saturation gain suppression unit, and the output side of the saturation gain suppression unit is connected to the gain setting unit. Therefore, the battery life can be extended.

  That is, in the present invention, when the sum value for each channel calculated by the channel power calculation unit of the gain adjuster is higher than the threshold value set by the threshold setting unit even in that one channel, the gain of each channel is set to each channel. Since the saturation gain suppression unit subtracts the value from the gain table reference unit set every time and supplies the value to the gain setter, there is no excessive input in the frequency synthesizer. As a result, it is not necessary to widen the bit width in the frequency synthesizer and the DA converter on the output side, thereby reducing the power consumption, and as a result, it is possible to extend the battery life. Is.

  Hereinafter, embodiments of the hearing aid of the present invention will be described in detail with reference to the drawings.

(Embodiment 1)
As shown in FIG. 1, the hearing aid in the present embodiment is provided with a microphone 3, a battery insertion port 4, and a volume knob 5 on the face plate 2 of the main body case 1, and on the opposite side of the face plate 2. A sound port 6 is provided.

  FIG. 2 shows electrically the functional components provided in the main body case 1. That is, the microphone 3 shown in FIG. 1 is disposed on the most upstream side, and is connected to the microphone 3, the AD converter 7 connected to the output side of the microphone 3, and the output side of the AD converter 7. Frequency analyzer 8, gain setting device 9 connected to the output side of frequency analyzer 8, frequency synthesizer 10 connected to the output side of gain setting device 9, and output side of frequency synthesizer 10 The D / A converter 11 connected to the D / A converter, the receiver 12 connected to the output side of the D / A converter 11, the frequency analyzer 8 and the gain setting unit 9 are connected to the input side, and the output side is connected to the output side. And a gain adjuster 13 connected to the gain setting unit 9.

  The gain adjuster 13 includes a channel power calculation unit 14 whose input side is connected between the frequency analyzer 8 and the gain setting unit 9, and a saturation connected in parallel to the output side of the channel power calculation unit 14. A gain suppression unit 15 and a gain table reference unit 16; the output of the gain table reference unit 16 is connected to the saturation gain suppression unit 15; and the output side of the threshold setting unit 17 is connected to the saturation gain suppression unit 15 The output side of the saturation gain suppression unit 15 is connected to the gain setting unit 9.

  Further, the frequency analyzer 8 is connected in series from the AD converter 7 to the gain setter 9, a buffer unit 18, an analysis window setting unit 19, and a fast Fourier transform unit (hereinafter referred to as FFT) 20. ing.

  Furthermore, the frequency synthesizer 10 connects an inverse fast Fourier transform unit (hereinafter referred to as IFFT) 21 to the output side of the gain setting unit 9, and connects an overlap addition unit 22 to the output side of the IFFT 21. At the same time, the input side of the buffer unit 23 is connected to the IFFT 21, the overlap adding unit 22 is connected to the output side of the buffer unit 23, and the DA converter 11 is connected to the output side of the overlap adding unit 22. It has a configuration.

  The sound output from the receiver 12 is radiated to the user's eardrum through the sound port 6.

  In the above configuration, the sound input from the microphone 3 is converted into a multi-bit digital signal by the AD converter 7 as shown in FIG. 3, and this digital signal is supplied to the dividing window setting unit 19 via the buffer unit 18. The FIG. 3 illustrates the sound that enters the microphone 3 as a sine wave for easy understanding.

  In the divided window setting unit 19, the input of FIG. 3 is converted as shown in FIG. 4 using a Hanning window function, for example. Next, the values in FIG. 4 are Fourier-transformed from the time axis signal to the frequency axis signal by the FFT 20 as shown in FIG.

  The Fourier-transformed value is supplied to the channel power calculation unit 14 of the gain adjuster 13, where the value is divided for each channel as shown in FIG. Further, the channel power calculation unit 14 adds the values in the frequency band of each channel shown in FIG. At this time, since the addition is performed in a decibel state, the maximum value of each channel shown in FIG.

  It should be noted here that the limit value of the sound pressure output from the receiver 12 is, for example, 110 decibels as can be understood from the gain characteristics of each channel shown in FIG. At this time, as understood from the enlarged view of FIG. 7 shown in FIG. 8, the threshold in the threshold setting unit 17 is determined for each channel. For example, the threshold of channel 3 is 110 decibels. With respect to the threshold value of 110 dB of channel 3, the sum value of each of the above-mentioned channels that can be understood from FIG. is there.

  The saturation gain suppression unit 15 reduces the gain of each channel as a whole when at least one of the total values of the channels 1 to 5 becomes larger than the threshold value of each channel of the threshold setting unit 17 in this way. It will be. Specifically, FIG. 9 shows a gain table set for each user stored in the gain table reference unit 16, and as can be understood from FIG. Each gain table has a different value.

  Therefore, the value suppressed by the saturation gain suppression unit 15 is also a value considering the characteristics of the gain table reference unit 16.

  This portion will be described in more detail. As described above, the total value of channel 3 is 120 decibels, and the threshold value of channel 3 is 110 decibels, so it is larger than the threshold value. At this time, the value to be suppressed by the saturation gain suppression unit 15 is to perform gain suppression of minus 10 dB over the entire channel 1 to channel 5 so as to be a limit value as understood from FIG. Become.

  Returning to FIG. 6 and FIG. 9 again, when the value of channel 1 is confirmed, the total value is approximately 50 decibels. Therefore, as can be understood from FIG. , Requesting to increase the gain.

  However, since the saturation gain suppression unit 15 is set to lower the 10 decibel gain as described above, as a conclusion, the gain setter 9 as this channel 1 is subtracted by 10 plus 10 decibels as shown in FIG. Decibel = 0 dB is transmitted. For this reason, the sum value 50 dB of channel 1 is not added or subtracted by the gain setting unit 9, and as a result, for the channel 1, as shown by the thick line A in FIG. 50 decibels will be output.

  This is the same for each output of channel 2 to channel 5. However, when a particularly characteristic channel 3 is described, the total value of channel 3 is 120 as shown in FIG. Since it is decibel, let's make it correspond to 120 decibel of FIG. As shown in FIG. 9, the 0 decibel gain is adjusted. Since the saturation gain suppression unit 15 is set to lower the 10 dB gain as described above, as a conclusion, as shown in FIG. Ten decibels are transmitted. As a result, the output of the gain setting device 9 outputs 110 decibels for the channel 3 as shown in FIG.

  A thin line B in FIG. 11 indicates the total value of the channel 1 to the channel 5 in the channel power calculation unit 14, and the appropriate negative value is applied to all of the channels 1 to 5 shown in FIGS. 6 and 9 described above. By subtracting 10 decibels, appropriate subtraction is performed for channel 1 to channel 5 as shown in FIG.

  However, what is important here is that the output of the channel 3 exceeding the threshold of 110 decibels is significantly suppressed by 10 decibels as shown in FIG. 11, but the output from the gain setting unit 9 after the correction of the channels 1 to 5 is 11 shows almost the same tendency as that of the thin line B in FIG. 11 that approximates the characteristics before correction, and this does not give the user a sense of incongruity.

  Then, the output from the gain setting unit 9 of the thick line A in FIG. 11 is converted from the frequency axis signal to the time axis signal by the IFFT 21, which has been conventionally performed, and this is the buffer unit 23 and the overlap addition unit. After passing through 22, it is converted into an analog signal by the DA converter 11 and converted into sound by the receiver 12, and this is discharged from the sound opening 6 to the eardrum of the user as described above.

  In the present embodiment, the frequency bandwidth of channel 1 to channel 5 is set as channel 2 <channel 1 <channel 3 <channel 4 <channel 5 to enhance the user experience. . By the way, channel 3 is in a state of covering the most frequently used area by setting it to about 600 to about 1400 hertz. In addition, channel 1 is approximately 400 hertz or less, channel 2 is approximately 400 to approximately 600 hertz, channel 4 is approximately 1400 hertz to approximately 2900 hertz, and channel 5 is approximately 2900 hertz or more.

  In the present embodiment, as a conclusion, the output from the gain setting unit 9 is set to a state where it does not exceed 110 decibels as shown by the thick line A in FIG. 11, that is, the output level is appropriately suppressed. 10 and the DA converter 11 do not need to widen the bit width, and thus power consumption in the frequency synthesizer 10 and the DA converter 11 can be suppressed. As a result, although not shown in FIG. The life of the battery for operating each part shown can be significantly increased.

  The present invention relates to a microphone, an AD converter connected to the output side of the microphone, a frequency analyzer connected to the output side of the AD converter, and a gain setting connected to the output side of the frequency analyzer. A frequency synthesizer connected to the output side of the gain setter, a DA converter connected to the output side of the frequency synthesizer, a receiver connected to the output side of the DA converter, A gain adjuster having an input side connected between the frequency analyzer and the gain setter and an output side connected to the gain setter, the gain adjuster comprising: the frequency analyzer and the gain setter; A channel power calculation unit having an input side connected in between, and a saturation gain suppression unit and a gain table reference unit connected in parallel to the output side of the channel power calculation unit. The output of the bull reference unit is connected to the saturation gain suppression unit, the output side of the threshold setting unit is connected to the saturation gain suppression unit, and the output side of the saturation gain suppression unit is connected to the gain setting unit. Therefore, the battery life can be extended.

  That is, in the present invention, when the sum value for each channel calculated by the channel power calculation unit of the gain adjuster is higher than the threshold value set by the threshold setting unit even in that one channel, the gain of each channel is set to each channel. Since the saturation gain suppression unit subtracts the value from the gain table reference unit set every time and supplies the value to the gain setter, there is no excessive input in the frequency synthesizer. As a result, it is not necessary to widen the bit width in the frequency synthesizer and the DA converter on the output side, thereby reducing the power consumption, and as a result, it is possible to extend the battery life. Is.

  Therefore, application as a hearing aid using a battery is greatly expected.

The perspective view which shows one Embodiment of this invention Control block diagram Operation explanation diagram Operation explanation diagram Operation explanation diagram Operation explanation diagram Operation explanation diagram Operation explanation diagram Operation explanation diagram Operation explanation diagram Operation explanation diagram

DESCRIPTION OF SYMBOLS 1 Main body case 2 Faceplate 3 Microphone 4 Battery insertion port 5 Volume knob 6 Sound port 7 AD converter 8 Frequency analyzer 9 Gain setting device 10 Frequency synthesizer 11 DA converter 12 Receiver 13 Gain adjuster 14 Channel power calculation part 15 Saturation gain suppression unit 16 Gain table reference unit 17 Threshold setting unit 18 Buffer unit 19 Analysis window setting unit 20 FFT
21 IFFT
22 Overlap addition part 23 Buffer part

Claims (8)

A microphone,
An AD converter connected to the output side of the microphone;
A frequency analyzer connected to the output side of the AD converter;
A gain setter connected to the output side of this frequency analyzer;
A frequency synthesizer connected to the output side of this gain setter;
A DA converter connected to the output side of the frequency synthesizer;
A receiver connected to the output side of the DA converter;
Between the frequency analyzer and the gain setting device, an input side thereof is connected, and an output side thereof is provided with a gain adjuster connected to the gain setting device,
The gain adjuster is
A channel power calculation unit having an input side connected between the frequency analyzer and the gain setting unit;
A saturation gain suppression unit and a gain table reference unit connected in parallel to the output side of this channel power calculation unit,
The output of the gain table reference unit is connected to a saturation gain suppression unit, and the output side of the threshold setting unit is connected to the saturation gain suppression unit,
A hearing aid in which the output side of the saturation gain suppression unit is connected to the gain setting device. The hearing aid according to claim 1, wherein a threshold value in the threshold setting unit is determined based on an upper limit value of the output sound pressure of the receiver. The hearing aid according to claim 1 or 2, wherein the channel power calculation unit is configured to divide into five channels and to add up the outputs of the five channels. The hearing aid according to claim 3, wherein the frequency bandwidth of channel 1 to channel 5 is set as channel 2 <channel 1 <channel 3 <channel 4 <channel 5. The hearing aid according to claim 4, wherein the channel 3 is approximately 600 to approximately 1400 hertz. The hearing aid according to claim 4 or 5, wherein the channel 2 is approximately 400 to approximately 600 hertz. The hearing aid according to any one of claims 4 to 6, wherein the channel 1 is approximately 400 hertz or less. The hearing aid according to any one of claims 4 to 7, wherein the channel 4 is approximately 1400 hertz or higher.

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