JP6731654B2 - Hearing aid adjustment device, hearing aid adjustment method, and hearing aid adjustment program - Google Patents

Description

The present disclosure relates to a hearing aid adjustment device, a hearing aid adjustment method, and a hearing aid adjustment program.

In the hearing aid, adjustment (fitting) of the hearing aid is performed so that the user (user) of the hearing aid can easily hear. As an example of adjustment of a hearing aid, it is known that a hearing aid adjustment system measures intelligibility under a plurality of S/N ratios, calculates a difference from a hearing-impaired person, and sets a gain (Patent Document 1). reference). In addition, the hearing aid is often adjusted in the order of hearing measurement, first fit, and fine adjustment.

International Publication No. 2013/128411

In the conventional hearing aid adjustment system, an inadequate adjustment operation of the hearing aid reduces the intelligibility, and the user may not be able to fully realize the hearing aid effect.

The present disclosure has been made in view of the above circumstances, and provides a hearing aid adjustment device, a hearing aid adjustment method, and a hearing aid adjustment program that can suppress a reduction in clarity due to an adjustment operation of a hearing aid.

Hearing aid adjusting apparatus of the present disclosure provides a hearing aid adjustment apparatus for the adjustment gain of the hearing aid, and an input device for inputting the adjustment operation of the gain, first clarity in the non-mounted state of the user hearing aid, a processor for calculating a second articulation in a first fit state of the hearing aid by the user, the third articulation in the fine adjustment state of the hearing aid using the first gain corresponding to the adjustment operation, respectively, wherein the processor, based on the ratio between the third articulation and the first difference between the difference and the second articulation and the first articulation and clarity, the adjustment operation The degree of adjustment of the hearing aid is displayed on the output device .

Hearing aid adjustment method of the present disclosure provides a hearing aid adjustment method in a hearing aid adjustment apparatus for adjusting parameters including the gain of the hearing aid, prior to the operation for adjusting the parameters, first in the non-mounted state of the user hearing aid The intelligibility and the second intelligibility of the user in the first fit state of the hearing aid are calculated, the adjustment operation of the parameter is input, and the first gain corresponding to the adjustment operation is used to calculate the fineness of the hearing aid. The third intelligibility in the adjusted state is calculated , and the third intelligibility is calculated as the ratio of the difference between the third intelligibility and the first intelligibility and the difference between the second intelligibility and the first intelligibility. Based on this, the degree of adjustment of the hearing aid by the adjustment operation is displayed on the output device .

The hearing aid adjustment program of the present disclosure is a program for causing a computer to execute the above hearing aid adjustment method.

According to the present disclosure, it is possible to suppress a decrease in clarity due to the adjustment operation of the hearing aid.

Block diagram showing a configuration example of a hearing aid adjustment device in the first embodiment Schematic diagram explaining the outline of the adjustment procedure of the hearing aid by the hearing aid adjustment device Graph showing an example of changes in audio level by band Graph showing an example of change in SII for each band A graph in which an example of the target area for displaying the first guidance is set A graph in which an example of the target area for displaying the second guidance is set A graph in which an example of the target area for displaying the third guidance is set Schematic diagram showing the UI screen displayed on the display Flowchart showing operation procedure related to guidance display Graph showing an example of the result of audiometry (A)-(E) is a schematic diagram which shows the transition example of the guidance display displayed on the UI screen of a display at the time of a fine adjustment. Graph showing an example of changes in audio level for each band Graph showing an example of changes in intelligibility for each band Flowchart showing an example of operation procedure related to intelligibility

Hereinafter, embodiments will be described in detail with reference to the drawings as appropriate. However, more detailed description than necessary may be omitted. For example, detailed description of well-known matters and duplicate description of substantially the same configuration may be omitted. This is to prevent the following description from being unnecessarily redundant and to facilitate understanding by those skilled in the art. It should be noted that the accompanying drawings and the following description are provided for those skilled in the art to fully understand the present disclosure, and are not intended to limit the claimed subject matter by them.

(Background of Obtaining One Form of the Present Disclosure)
Hearing aid adjustments include, for example, prescription processing and fine tuning. In the prescription process, the gain of the audio signal output by the hearing aid is automatically set based on the result of the hearing measurement. In fine tuning, the gain is adjusted by the hearing aid adjuster via the input device if the user wishes to improve the results of the prescription process.

Clarity is likely to be sacrificed when adjusting the gain. In particular, a user who has just started to use the hearing aid often feels that the sound of the hearing aid set by the prescription process is “noisy”, and the volume is often finely adjusted. However, too much adjustment often causes the clarity to decrease, and the hearing aid effect cannot often be realized.

That is, if the fine adjustment is appropriately performed, the user's satisfaction with respect to the volume, sound quality, etc. output from the hearing aid increases. On the other hand, if the fine adjustment is not properly performed (for example, if the fine adjustment is excessively performed), the intelligibility of the audio signal output by the hearing aid may decrease, and the hearing aid effect may not be sufficiently obtained. The precision of the fine adjustment depends on the ability and experience of the hearing aid adjuster.

Hereinafter, a hearing aid adjustment device, a hearing aid adjustment method, and a hearing aid adjustment program that can suppress a decrease in clarity due to an adjustment operation of the hearing aid will be described.

(First embodiment)
[Configuration of hearing aid adjustment device]
FIG. 1 is a block diagram showing the configuration of a hearing aid adjustment device 5 according to the first embodiment. The hearing aid adjustment device 5 assists the adjustment of the hearing aid 50 and has a configuration including a processor 10, a display 20, an input device 30, and a hearing aid setting device 40.

The processor 10 includes, for example, an MPU (Micro Processing Unit), a CPU (Central Processing Unit), or a DSP (Digital Signal Processor). Various functions are realized by executing a program (for example, a hearing aid adjustment program) held in a memory (not shown).

The processor 10 has a gain control function 11, a prescription formula processing function 12, an intelligibility calculation function 13, and a compensation adjustment amount calculation function 14. Further, the processor 10 controls each unit in the hearing aid adjustment device 5.

The processor 10 uses the prescription processing function 12 to theoretically calculate an initial setting value of a parameter including a gain (also simply referred to as a gain) of an audio signal by the prescription processing based on the result of the hearing measurement. As an example of the prescription processing, in NAL-NL/NL2, a gain that maximizes the intelligibility of voice is provided, under the restriction that the volume (loudness) of the sound output from the hearing aid does not exceed that of a normal hearing person. It is calculated.

The processor 10 uses the gain control function 11 to set the gain for each frequency band (also referred to as channel or simply “band”) to the hearing aid 50 according to the initial setting value and the setting value after fine adjustment calculated by the prescription formula process. Set.

The processor 10 uses the intelligibility calculation function 13 to calculate the intelligibility of the audio signal for each frequency band according to the initial setting and the gain setting after the fine adjustment. The calculated intelligibility for each band is displayed on the display 20 as a guidance display. An example of the index of clarity is SII (Speech Intelligibility Index).

The processor 10 uses the compensation adjustment amount calculation function 14 to increase the intelligibility SIIi of another band when lowering the intelligibility SIIi of a certain band i, for example, when lowering the intelligibility SIIi of the 3 KHz band to suppress howling. It may be corrected to compensate the intelligibility of the entire band.

The display 20 includes, for example, an LCD (Crystal Liquid Display). The display 20 performs various displays under the control of the processor 10. The display 20 displays a guidance, for example, when finely adjusting the gain.

The input device 30 receives the hearing information obtained from the result of the hearing measurement and the adjustment operation related to the fine adjustment. The input device 30 includes, for example, a touch panel integrated with the display 20, a mouse, and a keyboard.

The processor 10, the display 20, and the input device 30 are composed of, for example, a PC (Personal Computer) 8.

The hearing aid setting device 40 is an adapter that connects the PC 8 and the hearing aid 50 and transfers data between them. The parameter including the gain for each band set by the processor 10 is transmitted to the hearing aid 50. Thereby, the hearing aid 50 receives the parameter from the hearing aid setting device 40 and sets the parameter.

For example, the hearing aid setting device 40 may be one device that connects a USB (Universal Serial Bus) cable on the PC 8 side and a dedicated cable on the hearing aid 50 side. In addition, the hearing aid setting device 40 includes a device to which the USB cable on the PC 8 side is connected and a device to which a dedicated cable on the hearing aid 50 side is connected, and these devices are wirelessly connected (for example, Bluetooth (registered trademark)). ) May be connected. The hearing aid setting device 40 may be a device to which a USB cable on the PC 8 side is connected and which is wirelessly connected to the hearing aid 50.

The hearing aid setting device 40 may be integrated with the PC 8 as a part of the function of the PC 8 instead of as a device separate from the PC 8.

[Hearing aid adjustment procedure]
FIG. 2 is a diagram for explaining the outline of the procedure for adjusting the gain of the hearing aid 50 by the hearing aid adjustment device 5. Adjustment of hearing aids is usually performed in the order of hearing measurement, first fit, and fine adjustment.

In the audiometric measurement, for example, a lower limit value (audiovisual level) of a pure tone level for each frequency heard by a subject (user) in a soundproof room is measured.

In the first fit, the gain for each frequency band is set in the hearing aid 50 by using the initial setting value of the gain calculated by the prescription formula process theoretically obtained from the result of the hearing measurement. The first-fit hearing aid 50 is worn by the user, and the user confirms the hearing through the hearing aid 50. At the first fit stage, the user often requests improvement in the volume, sound quality, and the like of the audio signal output by the hearing aid 50, and in this case, the gain of the audio signal is finely adjusted.

In the fine adjustment, the hearing aid 50 is adjusted with respect to the hearing of the first-fit hearing aid 50 according to the user's comfort and timbre preference. The fine adjustment is performed according to the adjustment operation via the input device 30.

[Derivation of SII]
Next, an example of deriving SII will be described.

The processor 10 derives and compares SII in the bare-ear state, the fast-fit state, and the fine adjustment state (including SII during fine adjustment) for each channel. The first fit state is a state in which the processing relating to the first fit has been performed and fine adjustment has not been performed. The fine adjustment state is a state in which fine adjustment is further performed. The fine adjustment state may not be the state after the fine adjustment is completed, but may be the state during the fine adjustment.

The bare ear state is a state in which the user does not wear the hearing aid 50. During the first fit, the user may or may not wear the hearing aid 50. During fine adjustment, the user wears the hearing aid 50.

SII is represented by (Formula 1), for example.

“N” is the number of channels. "Ii" is a function (band importance function) representing the importance of each band with respect to the hearing of voice, and is a fixed value. “Ai” is a function (band audibility function) that represents how much each band is audible (easy to hear), and changes depending on the S/N ratio, hearing ability, voice level, and the like.

The processor 10 calculates the equivalent internal noise spectrum level X'i from the hearing level T'i of the frequency corresponding to each channel according to (Equation 2).
X′i=Xi+T′i (Equation 2)

Here, “Xi” is a reference internal noise spectrum level. For the specific value of “Xi”, refer to Reference Non-Patent Document 1.

(Reference non-patent document 1)
ANSI (1997). “ANSI S3.5-1997, American national standard methods for calculation of the speech intelligibility index”

Subsequently, the processor 10 calculates the equivalent speech spectrum level E'i in each user state (naked ear state, first fit state, fine adjustment state). In the calculation of E′i, the speech spectrum level measured as described in Reference Non-Patent Document 1 is used in the bare ear state. Alternatively, the standard speech spectrum level described in Reference Non-Patent Document 1 may be used. In the first fit state, a value obtained by adding a gain determined by prescription processing to the measured speech spectrum level or standard speech spectrum level is used. Similarly, in the fine adjustment state, a value obtained by adding the gain in the fine adjustment state to the speech spectrum level in the first fit state or the standard speech spectrum level is used.

Subsequently, the processor 10 calculates the variables Li and Ki according to (Equation 3) and (Equation 4).

Li = 1-(E'i-Ui-10)/160 (Equation 3)
Here, "Ui" is a standard speech spectrum level at a normal volume. Refer to Reference Non-Patent Document 1 for specific numerical values of “Ui”.

Ki=(E'i-Di+15)/30 (Equation 4)
Here, “Di” is the larger value of the above X′i and the equivalent masking spectrum level Zi. When the influence of background noise or masking can be ignored, Di=X'i may be set. It should be noted that the processor 10 sets both Li and Ki to the value 0 when the value is less than 0, and sets the value 1 when the value is greater than 1.

Subsequently, the processor 10 calculates the Band audibility function Ai according to (Equation 5).
Ai=Li·Ki (Equation 5)
Incidentally, “·” indicates a multiplication code.

The processor 10 calculates the SIIi for each band according to the mathematical expression (6) using the Ai and the band importance function Ii. For the specific value of Ii, see Reference Non-Patent Document 1.
SIIi=Ai·Ii (Equation 6)

Since the sound level output from the hearing aid 50 is different in the naked ear state, the first fit state, and the fine adjustment state, the intelligibility SIIi at different sound levels is derived.

FIG. 3 is a graph showing changes in sound level (SPL: Sound Pressure Level) for each band. In this graph, data of audio levels of 8 channels (signal level of audio signals) is shown in the range of 250 Hz to 8 KHz. Graphs o1, o2, and o3 show the sound levels in the bare ear state, the first fit state, and the fine adjustment state, respectively.

In FIG. 3, the sound level in the bare ear state is low over the entire measurement band (here, 8 channels), as shown in the graph o1. The audio level in the first fit state is high near the 3 kHz band as shown in the graph o2. The sound level in the fine adjustment state is finely adjusted with respect to the sound level in the first fit state, as shown in the graph o3.

FIG. 4 is a graph showing an example of changes in SII for each band. In this graph, 8 channels of SIIi data are shown in the range of 250 Hz to 8 KHz. Graphs m1, m2, and m3 show SIIi at the sound level in the bare ear state, the first fit state, and the fine adjustment state, respectively.

In FIG. 4, the SIIi in the bare ear state is generally lower in the band of 1 kHz or more as compared with other user states (first fit state, fine adjustment state) as shown in the graph m1. As shown in the graph m2, the SIIi in the first fit state is generally higher in the band of 500 Hz or higher as compared with other user states (naked ear state, fine adjustment state). The clarity SIIi in the fine adjustment state is suppressed with respect to the clarity SIIi in the first fit state in the band of 1 kHz or higher as shown in the graph m3.

Note that the bands shown in FIGS. 3 and 4 are examples, and other bands may be used. The band classification method may depend on the model of the hearing aid 50, for example.

[Guidance display]
Next, the guidance display will be described.

In the present embodiment, when the intelligibility SIIi in the fine adjustment state becomes so small that the user cannot realize the hearing aid effect, the hearing aid adjustment device 5 outputs a caution or warning as a guidance display.

In other words, the processor 10 presents warning information such as cautions and warnings when the SII drops below a predetermined standard. As a result, the hearing aid adjustment device 5 can realize fine adjustment while maintaining the hearing aid effect.

Examples of the guidance display include the first guidance display to the third guidance display. The guidance display is confirmed by the fitting operator and is effectively utilized for the fine adjustment operation after this confirmation.

In each guidance display, for example, the guidance is shown in four bands of 500 Hz, 1 kHz, 2 kHz and 4 kHz. The four bands are bands that have a great influence on the hearing of the user. The guidance may be displayed in a band other than these four bands, or the number of bands may be other than four.

In the first guidance display, the processor 10 determines the difference ΔSII _F between SII _U in the bare ear state and SII _{F in} the first fit state, and SII _{U in} the bare ear state and intelligibility SII _A in the fine adjustment state. The guidance is displayed based on the difference ΔSII _A.

ΔSII _F indicates how much clarity is improved by the first fit with respect to the bare ear condition. ΔSII _A shows to what extent the fine adjustment improved the clarity for the bare-ear condition. Therefore, when ΔSII _F =0 and ΔSII _A =0, it indicates that the hearing aid 50 has no hearing aid effect.

FIG. 5 is a graph showing a target area in which the first guidance display is performed. In FIG. 5, the vertical axis is ΔSII _A and the horizontal axis is ΔSII _F , and the target region is shown two-dimensionally.

When ⅓·ΔSII _F ≦ΔSII _A <2/3·ΔSII _F , the processor 10 issues a warning via the display 20 that the intelligibility has deteriorated (see the area of light dot display in FIG. 5). .. Further, when ΔSII _A <1/3·ΔSII _F , the processor 10 issues a warning via the display 20 that the intelligibility is remarkably reduced and the hearing aid effect cannot be maintained (the dark dot display area in FIG. 5). See). Incidentally, “·” indicates a multiplication code.

According to the hearing aid adjustment device 5 shown in FIG. 5, guidance can be displayed based on the comparison between the improvement amount of SII in the first fit state and the improvement amount of SII in the fine adjustment state. For example, the hearing aid adjustment device 5 can perform a caution display and a warning display when the effect of improving the clarity in the fine adjustment state is lower than the first fit state by a predetermined reference or more.

FIG. 6 is a graph showing a target area in which the second guidance display is performed. Similar to FIG. 5, in FIG. 6, the vertical axis represents ΔSII _A and the horizontal axis represents ΔSII _F , and the target region is shown two-dimensionally.

In the second guidance display, guidance is displayed based on SII _F in the first fit state and intelligibility SII _A in the fine adjustment state.

For ΔSII _F ≧ 0.12, When it is _{1/3 · ΔSII F ≦ ΔSII} A <2/3 · ΔSII F, the processor 10 issues a note through the display 20. When ΔSII _A <1/3·ΔSII _F , the processor 10 issues a warning via the display 20.

0.08 If ≦ΔSII _F <0.12, then ΔSII _F −0.08 ≦ΔSII _A <ΔSII _F −0.04, the processor 10 issues a warning via the display 20. Further, when ΔSII _A <ΔSII _F −0.08, the processor 10 issues a warning via the display 20.

When ΔSII _F <0.08, 0≦ΔSII _A <1/2·ΔSII _F , the processor 10 issues a warning via the display 20. If ΔSII _A <0, the processor 10 issues a warning via the display 20.

For example, when ΔSII _F in the first fit state was relatively good with a value of 0.12, but ΔSII _A in the fine adjustment state fell below 0.08, the hearing aid adjustment device 5 , Give attention. Further, when the ΔSII _A in the fine adjustment state related to the further fine adjustment decreases to a value less than 0.04, the hearing aid adjustment device 5 issues a warning.

As described above, the hearing aid adjustment device 5 shown in FIG. 6 sets the target area of attention (attention area) to be wider than the attention area related to the first guidance display, so that a warning is issued immediately during fine adjustment. Can be suppressed. In particular, in the range of ΔSII _F <0.08, it is possible to prevent a sudden warning display and a sudden hitting of the fitting operator. In other words, the hearing aid adjustment device 5 can display guidance in stages so that a warning is issued from a warning even if ΔSII _F is relatively low (for example, a value of 0.08 or less).

FIG. 7 is a graph showing a target area in which the third guidance display is performed. In the third guidance display, SII _F in the first fit state and SII _A in the fine adjustment state are used, and the target area is set without using the difference between the clarity SII _U in the bare ear state. .. In FIG. 7, the vertical axis is SII _A and the horizontal axis is SII _F , and the target region is shown two-dimensionally.

If 1/2·SII _F ≦SII _A <3/4·SII _F , the processor 10 issues a warning via the display 20. When SII _A <1/2·SII _F , the processor 10 issues a warning via the display 20.

As described above, according to the third guidance display, the hearing aid adjustment device 5 can display guidance based on the comparison between the SII in the first fit state and the SII in the fine adjustment state. That is, it is possible to visually confirm the amount of improvement in SII in the fine adjustment state based on the first fit state.

FIG. 8 is a schematic diagram showing the UI screen 25 displayed on the display 20.

The UI screen 25 includes a graph gdh showing the audio level for each frequency band, and a slider section sdb for varying the audio level for each frequency band. The slider unit sdb is an example of the input device 30.

The graph gdh shows the sound level in the first fit state and the sound pressure level in the fine adjustment state in eight frequency bands of the band 250 Hz to 8 kHz.

For example, a graph gd2 showing the sound pressure level in the first fit state and a graph gd1 showing the sound pressure level in the fine adjustment state when the input voice level is 40 dB are shown.

Further, a graph gd4 showing the sound pressure level in the first fit state and a graph gd3 showing the sound pressure level in the fine adjustment state when the input voice level is 60 dB are shown.

Further, a graph gd6 showing the sound pressure level in the first fit state and a graph gd5 showing the sound pressure level in the fine adjustment state when the input voice level is 90 dB are shown.

On the UI screen 25, a color-coded display (for example, a background color of yellow (indicated by a light dot in the figure)) indicating an attention in the frequency band of 750 Hz to 3 kHz is overlay-displayed so as to overlap with the graph gdh. In addition to the color-coded display, or instead of the color-coded display, the character information relating to the attention (for example, the character “attention”) may be displayed.

Further, on the UI screen 25, a color-coded display (for example, a red background color (indicated by a dark dot in the figure)) indicating a warning in the frequency band of 3 kHz to 5 kHz is overlay-displayed so as to overlap with the graph gdh. In addition to the color-coded display or in place of the color-coded display, character information related to the warning (for example, the character “warning”) may be displayed.

The slider unit sdb includes sliders sr1 to sr8 for adjusting the audio levels in eight frequency bands of the band 250 Hz to 8 kHz, and a slider sr9 for collectively adjusting the audio levels in all bands.

When the user slides the sliders sr1 to sr8, the processor 10 changes the gain in each frequency band. As a result, the audio level of each frequency band is changed. Further, when the user slides the slider sr9, the processor 10 collectively changes the gains of all bands. As a result, the sound level is collectively changed.

Note that the sound level may be adjusted by the button bt instead of the slider portion sdb. Like the slider, the button bt enables adjustment of the audio level in each frequency band, and can also collectively adjust the audio level of all bands.

FIG. 9 is a flowchart showing an operation procedure relating to guidance display by the hearing aid adjustment device 5.

The processor 10 inputs the hearing information (the result of the hearing measurement) received by the input device 30, for example (S1).

FIG. 10 is a graph showing a change in the hearing level for each frequency band as a result of the hearing measurement. Here, the hearing level is measured in eight frequency bands within the range of 125 Hz to 8 kHz. In FIG. 10, for example, the hearing level is high in the band of 250 Hz to 2 kHz used for human conversation.

The processor 10 calculates SII _U in the bare ear state from the result of the hearing measurement (S2). The SII _U in the bare ear state is calculated, for example, according to (Equation 1) described above. The SII _U calculation in the bare ear state may be performed before the guidance is displayed, that is, before S9 described below.

The processor 10 calculates a gain for each frequency band by prescription formula processing (S3).

The processor 10 sets the gain calculated by the prescription process in the hearing aid 50 via the hearing aid setting device 40 (S4).

The processor 10 calculates the intelligibility SII _F in the first fit state in which the gain by the prescription process is set (S5).

When the parameters in the first fit state are set in the hearing aid 50, a fine adjustment operation is performed on the wearer (user) wearing the hearing aid 50 so that the sound volume, sound quality, and the like are appropriate. In the fine adjustment operation, for example, the hearing aid adjuster moves the sliders sr1 to sr9 of the slider portion sdb on the UI screen 25 displayed on the display 20 to adjust the gain.

The processor 10 inputs the gain adjustment value by the fine adjustment operation of the hearing aid operator through the input device 30 (S6).

The processor 10 sets the input gain adjustment value in the hearing aid 50 via the hearing aid setting device 40 (S7).

The processor 10 calculates the intelligibility SII _A in the fine adjustment state (S8).

The processor 10 follows the first guidance display (see FIG. 5), the second guidance display (see FIG. 6), or the third guidance display (see FIG. 7) along with the voice level graph gdh to indicate “attention” or “warning”. It is determined whether or not the guidance display accompanied by "is displayed" (S9).

When the processor 10 determines to display the guidance, the processor 10 displays the guidance on the display 20 (see FIG. 8) (S10).

After that, the processor 10 determines whether or not the fine adjustment is completed (S11). The fine adjustment is completed, for example, when the input device 30 receives a predetermined operation from the hearing aid adjuster or the user, or when a predetermined time has elapsed since the last fine adjustment operation was received by the timer.

When the fine adjustment is not completed, the processor 10 returns to the process of S6. That is, the fine adjustment is repeated. On the other hand, when the fine adjustment is completed, the processor 10 ends this operation.

The hearing aid adjustment device 5 can suppress an adjustment operation that is accompanied by a guidance display operation and that causes a reduction in clarity due to an erroneous operation or an excessive operation by a hearing aid adjuster.

Next, the transition of the guidance display during fine adjustment will be described.
11A to 11E are schematic diagrams showing an example of transition of guidance display displayed on the UI screen 25 of the display 20 during fine adjustment.

The transition of the guidance display shown in FIGS. 11A to 11E shows a case where the audio level is gradually lowered from the audio level in the first fit state by using the slider sr9 for the entire band. The sound level decreases as the state shifts from FIG. 11(A) to FIG. 11(E).

FIG. 11A shows a graph showing the sound level for each frequency band in the first fit state. FIG. 11B shows a graph showing the audio level for each frequency band when the audio level is lowered by 7 dB from the first fit state. At the stage of FIG. 11B, a color-coded display indicating caution is performed by overlay display in the 4 kHz band. Also, a balloon of the character "Caution" may be displayed.

FIG. 11C shows a graph showing the audio level for each frequency band when the audio level is lowered by 11 dB from the first fit state. At the stage of FIG. 11C, a color-coded display indicating caution is displayed by overlay display in the entire band (250 Hz to 4 kHz) to be the guidance target. Also, a balloon of the character "Caution" may be displayed.

FIG. 11D shows a graph showing the audio level for each frequency band when the audio level is reduced by 13 dB from the first fit state. At the stage of FIG. 11D, a color-coded display indicating a warning by overlay display is performed in the 4 kHz band. In addition, a balloon of the characters "warning" may be displayed.

FIG. 11E shows a graph showing the sound level for each frequency band when the sound level is reduced by 17 dB from the first fit state. At the stage of FIG. 11E, a color-coded display indicating a warning by overlay display is performed in the entire band (250 Hz to 4 kHz) to be the guidance target.

In this way, the hearing aid adjuster can suppress a decrease in clarity that makes it impossible to maintain the hearing aid effect by performing a fine adjustment operation via the slider portion sdb while viewing the guidance display.

[Clarity Compensation]
Next, the intelligibility compensation will be described.

In the present embodiment, when the intelligibility SIIi of a certain band is lowered, the hearing aid adjustment device 5 increases the gain of the other band to compensate so that the intelligibility or the sound level in the entire band becomes substantially constant. May be.

In the intelligibility compensation, when the intelligibility SIIi of a certain band is lowered or inevitably lowered, the processor 10 increases the SIIi of other bands in order to reduce the change of SII of the other bands. Adjust the gain of.

As an example of reducing the intelligibility SIIi of a certain band, when a countermeasure against howling is taken, lowering the gain of the 3 kHz band lowers the SIIi of the 3 kHz band. The reduction of the gain in the predetermined band (for example, 3 kHz) may be performed according to the operation by the input device 30, for example. Further, the processor 10 may detect the band in which the howling is occurring and the audio level and reduce the gain to a level capable of suppressing the howling.

Incidentally, the occurrence of howling in the audio signal is not usually taken into consideration in the prescription processing performed before the fine adjustment operation. The occurrence of howling often occurs when the user wears the hearing aid 50 and hears the sound output by the hearing aid 50 during the fine adjustment operation.

FIG. 12 is a graph showing changes in audio level for each band. In FIG. 12, the vertical axis represents the audio level and the horizontal axis represents the frequency. In the graph, the area are shows the variable range of SII (range between the maximum value and the minimum value of SII) in each frequency band.

FIG. 13 is a graph showing changes in SIIi for each band. In FIG. 13, the vertical axis represents SII and the horizontal axis represents frequency.

In order to suppress the howling, the processor 10 lowers the voice level in the 3 kHz band, that is, lowers the gain in the 3 kHz band, as shown by the arrow y1, with respect to the graph sg representing the voice level shown in FIG. In this case, as shown in FIG. 13, SIIi in the 3 kHz band decreases as indicated by arrow z1. Even if the SIIi in the 3 kHz band is lowered, the following two compensation methods are studied in order to reduce the change in the SII that is integrated in each frequency band. Here, the sum of SII in the band of 250 Hz to 4 kHz is made substantially constant before and after the howling countermeasure.

In the first compensation method, the processor 10 increases the gain in the peripheral band (here, adjacent bands, 2 kHz band and 4 kHz band) of the band in which the gain is reduced (here, 3 kHz band), and sets the voice level to the arrow y2. , Y3. In this case, SII is about 0.15 in the 2 kHz band and about 0.1 in the 4 kHz band.

As a result, even if the SII in the 3 kHz band is lowered as indicated by the arrow z1, the SII in the adjacent band is raised as indicated by the arrows z2 and z3. Therefore, the hearing aid adjustment device 5 can suppress a decrease in SII in the entire compensation band (for example, the band of 250 Hz to 4 kHz) including the 3 kHz band, as shown in the graph mg. The compensation band may be the entire band (for example, 250 Hz to 8 kHz).

In the second compensation method, the processor 10 sets the gain in the band (here, 1 kHz band) in which the distance from the currently set gain to the upper limit U1 of the area are in the frequency band is long (large margin), Raise as indicated by arrow y4. In this case, the SII in the 1 kHz band is about 0.15.

As a result, even if the SII in the 3 kHz band falls as shown by the arrow z1, the SII in the band with a large margin rises as shown by the arrow z4. Therefore, the hearing aid adjustment device 5 can suppress the decrease in SII in the entire compensation band including the 3 kHz band, as shown in the graph mg. The compensation band may be the entire band (for example, 250 Hz to 8 kHz).

FIG. 14 is a flowchart showing an operation procedure related to intelligibility compensation.

As in the case of the guidance display, the processor 10 inputs the result of the hearing measurement via the input device 30, for example (S21).

The processor 10 calculates the gain for each frequency band by prescription formula processing (S22).

The processor 10 sets the gain calculated in S22 in the hearing aid 50 via the hearing aid setting device 40 (S23).

The processor 10 inputs the gain adjustment value by the hearing aid adjuster or user's adjustment operation via the input device 30 (S24). The input by the adjustment operation here includes, for example, an input by a fine adjustment operation and an input for reducing the gain of a specific band as a countermeasure against howling.

The processor 10 calculates the intelligibility SII _A in the fine adjustment state (S25).

The processor 10 determines the frequency band to be compensated by, for example, the first compensation method or the second compensation method based on the intelligibility SII _A in the fine adjustment state, and determines the amount of gain to be compensated (compensation adjustment amount). Calculate (S26).

The processor 10 sets the calculated gain for the determined frequency band in the hearing aid 50 via the hearing aid setting device 40 (S27).

After that, the processor 10 determines whether or not the adjustment of the intelligibility compensation is completed (S28). The fine adjustment is completed, for example, when the input device 30 receives a predetermined operation from the hearing aid adjuster or the user, or when a predetermined time has elapsed since the last fine adjustment operation was received by the timer.

When the fine adjustment is not completed, the processor 10 returns to the process of S24. That is, the fine adjustment is repeated. On the other hand, when the fine adjustment is completed, the processor 10 ends this operation.

The hearing aid adjusting device 5 performs the operation related to the intelligibility compensation, and even if the intelligibility of an arbitrary frequency band is lowered by the fine adjustment operation, by increasing the intelligibility of other frequency bands, the intelligibility in the entire band or the compensation band is increased. You can maintain the degree.

[Effects, etc.]
In this way, when the hearing aid adjustment device 5 adjusts the parameters including the gain of the hearing aid 50, the slider unit sdb inputs the gain adjustment operation by the user. The processor 10 can calculate the intelligibility of the user with or without the hearing aid 50. The processor 10 calculates the first intelligibility using the first gain according to the adjustment operation, and calculates the second intelligibility before the adjustment operation. The processor 10 assists in adjusting the hearing aid 50 based on the first intelligibility and the second intelligibility.

The wearing state of the hearing aid 50 includes, for example, a first fit state or a fine adjustment state. The non-wearing state of the hearing aid 50 includes, for example, a bare ear state. The adjustment operation is, for example, a fine adjustment operation. The first intelligibility is, for example, SII _A in the fine adjustment state. The second intelligibility is SII _F in the first fit state or SII _U in the bare ear state.

As a result, the hearing aid adjustment device 5 can suppress the decrease in clarity due to the adjustment operation of the hearing aid 50, and can perform the adjustment while maintaining the hearing aid effect.

Further, the display 20 may display warning information for suppressing adjustment of the hearing aid 50 based on the first intelligibility and the second intelligibility under the control of the processor 10.

The display 20 is an example of an output device. Displaying the warning information is an example of outputting the warning information. The display of the warning information includes, for example, a color-coded display for warning and a character display, and a color-coded display and character display for a warning.

This allows the user to adjust the hearing aid 50 according to the warning information, suppress excessive adjustment, and simplify suitable adjustment operations.

Further, the display 20 may display caution and warning in stages as warning information.

As a result, the user can make fine adjustments according to the warning information that is output in stages, and the operability is improved. In addition, it is possible to prevent the warning from being issued abruptly (for example, without the attention being given), and the user can perform a suitable adjustment operation with a margin.

Further, the processor 10 may determine the second gain by prescription processing before the adjustment operation and calculate the second intelligibility according to the second gain. The second gain is, for example, a gain in the first fit state. The second intelligibility is, for example, SII _F in the first fit state.

Thereby, the hearing aid adjustment device 5 can display guidance based on the comparison between the clarity in the first fit state and the clarity in the fine adjustment state. That is, it is possible to visually confirm the amount of improvement in SII in the fine adjustment state based on the first fit state.

Further, the processor 10 calculates the third intelligibility when the hearing aid 50 is not worn, and calculates the difference between the second intelligibility and the third intelligibility, and the first intelligibility and the third intelligibility. The warning information may be displayed according to the difference between

The third intelligibility is the intelligibility SII _U in the bare ear state, for example. The difference between the second intelligibility and the third intelligibility is ΔSII _F , for example. The difference between the first clarity and the third clarity is ΔSII _A , for example.

Thereby, the hearing aid adjustment device 5 can display guidance based on the comparison between the improvement amount of clarity in the first fit state and the improvement amount of clarity in the fine adjustment state. For example, the hearing aid adjustment device 5 can perform a caution display and a warning display when the effect of improving the clarity in the first fit state is lower than the fine adjustment by a predetermined reference or more.

Further, the processor 10 may calculate the intelligibility SIIi for each frequency band and assist the adjustment of the hearing aid 50 for each frequency band.

Thereby, the hearing aid adjustment device 5 can adjust the hearing aid 50 for each frequency band. Therefore, the hearing aid adjustment device 5 can assist the adjustment of the hearing aid 50, for example, by emphasizing the reduction in the clarity of the band that has a great influence on the hearing of the user.

Further, the processor 10 calculates the intelligibility for each frequency band, and uses the first gain according to the adjustment operation to reduce the first intelligibility in the first frequency band (for example, 3 kHz band). The gain according to the adjustment operation in the second frequency band may be controlled so that the first clarity in the second frequency band other than the first frequency band is increased.

Accordingly, the hearing aid adjustment device 5 can maintain the clarity of the entire band by increasing the clarity of the other frequency bands even if the clarity of the first frequency band is lowered by the adjustment operation.

Moreover, the second frequency band may include a frequency band (for example, a band of 2 kHz or 4 kHz) adjacent to the first frequency band.

Thereby, the hearing aid adjustment device 5 can suppress the change in the sound quality of the audio signal by increasing the clarity of the adjacent frequency bands, and can reduce the change in the hearing of the user.

The processor 10 may also determine the second frequency band based on the difference between the first intelligibility using the first gain in each frequency band and the maximum intelligibility in the same frequency band. Good. The maximum clarity is, for example, the upper limit value U1 of the area Are.

As a result, the hearing aid adjustment device 5 can increase the amount of compensation for compensating for the decrease in clarity in a specific frequency band, and can suppress the influence on the hearing of the user.

The clarity may be SII.

As a result, it is possible to use the intelligibility with high versatility and suppress the decrease in intelligibility due to the adjustment operation of the hearing aid.

(Other embodiments)
As described above, the first embodiment has been described as an example of the technique according to the present disclosure. However, the technology of the present disclosure is not limited to this, and can be applied to embodiments in which changes, replacements, additions, omissions, etc. have been made.

In the first embodiment, it is shown that the hearing aid adjustment device 5 displays guidance based on at least one of SII in the bare ear state and SII in the first fit state and SII in the fine adjustment state. However, the adjustment of the hearing aid 50 may be prohibited in the range where the guidance is displayed.

That is, the processor 10 may limit the adjustment range of the gain of the hearing aid 50 based on at least one of the SII in the bare ear state and the SII in the first fit state and the SII in the fine adjustment state. As a result, the hearing aid adjustment device 5 is prohibited from performing a fine adjustment operation that worsens the hearing aid condition by a predetermined level or more, as compared with the bare ear state or the first fit state, and thus excessive adjustment can be avoided.

In the first embodiment, as an output mode of the warning information, the display 20 performs a color-coded display in which the background color is changed for each band on the graph of the sound pressure level displayed on the UI screen 25, and the warning character is displayed. It was displayed in a balloon, but it is not limited to this. For example, when the sound pressure level enters a warning target area, the display 20 may blink a part of the graph of the area. Further, although the display 20 expresses the decrease in the clarity as the warning information in two stages of caution and warning, it may express the decrease in the clarity in three or more stages so that the degree of the warning can be more understood. ..

In the first embodiment, the display 20 indicates that guidance is displayed for each frequency band to be adjusted, but SIIi of each frequency band is added, that is, SII represented by (Equation 1) is displayed. You may make it display the guidance with respect to the whole.

In the first embodiment, the case where SII is used as the index of clarity is shown, but another index of clarity (for example, ESII (extended SII) or STI (Speech Transmission Index)) may be used. Details of the clarity index ESII are shown in Reference Non-Patent Document 2. Details of the clarity index STI are shown in Reference Non-Patent Document 3.

(Reference non-patent document 2)
Rhebergen et al. (2006). “Extended speech intelligibility index for the prediction of the speech reception threshold in fluctuating noise,” J. Acoust. Soc. Am. 120 (6), pp. 3988-3997.

(Reference non-patent document 3)
IEC (2011). “IEC 60268-16:2011, Sound system equipment-Part 16: Objective rating of speech intelligibility by speech transmission index”

Although the hearing aid adjustment device 5 outputs the warning information by displaying the display 20 in the first embodiment, the warning information may be output by another method. For example, instead of the display on the display 20, the hearing aid adjustment device 5 may output the warning information by displaying the display 20 and outputting sound by a speaker (not shown) or vibration by a vibrator (not shown).

Although the gain of the hearing aid 50 is adjusted in the first embodiment, parameters other than the gain of the hearing aid 50 may be adjusted together, and this parameter may be set in the hearing aid 50. In addition, when the hearing aid 50 has a function of nonlinear amplification, the hearing aid adjustment device 5 adjusts the parameters of the nonlinear amplification (for example, compression ratio, compression threshold, time constant, etc.). The gain may be adjusted by adjusting.

In the first embodiment, it is described that the processor 10 may increase the gain of another frequency band when the gain of the specific frequency band is decreased. However, when increasing the gain of another frequency band, Alternatively, guidance may be displayed as a guide for gain control.

For example, when the hearing aid 50 is worn by the user, a sound signal that is a source of howling and is fed back from a speaker (not shown) of the hearing aid 50 to a microphone (not shown) is measured. Based on this measurement value, the processor 10 determines how much the gain of the hearing aid 50 can be increased. That is, the processor 10 can determine whether or not to perform howling when a 60 dB audio signal is converted to an 80 dB audio signal, for example. Therefore, the display 20 may display the warning information under the control of the processor 10 in the range of the sound level at which howling is expected to occur.

In the first embodiment, the intelligibility compensation when the gain of the hearing aid 50 decreases and the audio level decreases has been described, but the processor 10 compensates the intelligibility when the gain of the hearing aid 50 increases and the audio level increases. You may.

In the first embodiment, the processor 10 may have any physical configuration. Further, if the programmable processor 10 is used, the processing content can be changed by changing the program, so that the degree of freedom in designing the processor 10 can be increased. The processor 10 may be configured with one semiconductor chip or may be physically configured with a plurality of semiconductor chips. When it is configured with a plurality of semiconductor chips, the respective controls of the first embodiment may be realized by different semiconductor chips. In this case, it can be considered that the plurality of semiconductor chips form one processor 10. Further, the processor 10 may be composed of a member (a capacitor or the like) having a function different from that of the semiconductor chip. Further, one semiconductor chip may be configured so as to realize the function of the processor 10 and the other functions.

The present disclosure is useful for a hearing aid adjustment device, a hearing aid adjustment method, a hearing aid adjustment program, and the like that can suppress a decrease in clarity due to an adjustment operation of a hearing aid.

5 Hearing aid adjustment device 8 PC
10 processor 11 gain control function 12 prescription type processing function 13 clarity calculation function 14 compensation adjustment amount calculation function 20 display 25 UI screen 30 input device 40 hearing aid setting device 50 hearing aid are area gd1, gd2. gd3, gd4, gd5, gd6, m1, m2, m3, mg, o1, o2, o3, gdh, sg graph sdb slider section sr1 to sr9 slider y1, y2, y3, y4, z1, z2, z3, z4 arrow

Claims (12)

A hearing aid adjustment device for adjusting the gain of a hearing aid, comprising:
An input device for inputting the gain adjustment operation,
The first clarity of the hearing aid when the user does not wear the hearing aid, the second clarity of the hearing aid in the first fit state of the hearing aid, and the fineness of the hearing aid that uses the first gain according to the adjustment operation. comprising a processor for calculating a third articulation of the adjustment states respectively, a,
Wherein the processor is based on the ratio between the third articulation and the difference between the difference and the second articulation and the first articulation of the first articulation, the hearing aid by the adjusting operation The adjustment degree of is displayed on the output device ,
Hearing aid adjustment device. The hearing aid adjustment device according to claim 1 , wherein
The processor stepwise displays the degree of adjustment of the hearing aid on the output device based on the ratio ,
Hearing aid adjustment device. The hearing aid adjustment device according to claim 2 , wherein
Before Symbol processor,
When the ratio satisfies the first condition , the caution information indicating that the intelligibility is lowered by the adjusting operation is displayed on the output device,
If the ratio is the first condition is different from the second condition is satisfied, that displays warning information indicating that the hearing aid effect by the hearing aid can not be maintained by the adjustment operation to the output device,
Hearing aid adjustment device. The hearing aid adjustment device according to claim 2 or 3, further comprising:
The processor determines a second gain by prescription processing before the adjusting operation, and calculates the second intelligibility according to the second gain.
Hearing aid adjustment device. The hearing aid adjustment device according to claim 1, further comprising:
The processor limits the gain adjustment range of the hearing aid based on at least one of the first intelligibility and the second intelligibility and the third intelligibility .
Hearing aid adjustment device. A hearing aid adjustment apparatus according to any one of claims 1 to 5,
The processor calculates the second intelligibility for each frequency band and assists the adjustment of the hearing aid for each frequency band,
Hearing aid adjustment device. The hearing aid adjustment device according to claim 1, wherein
The processor is
Calculating the third intelligibility for each frequency band,
When the third intelligibility in the first frequency band is reduced by using the first gain according to the adjustment operation, the second gain in the second frequency band other than the first frequency band is used. Controlling the first gain in the second frequency band so as to increase the clarity of 3 ;
Hearing aid adjustment device. The hearing aid adjustment device according to claim 7 , wherein
The second frequency band includes a frequency band adjacent to the first frequency band,
Hearing aid adjustment device. The hearing aid adjustment device according to claim 7 , wherein
The processor determines the second frequency band based on a difference between the third intelligibility and the maximum intelligibility using the first gain in each frequency band,
Hearing aid adjustment device. The hearing aid adjustment device according to any one of claims 1 to 9 ,
The first intelligibility , the second intelligibility, and the third intelligibility are SII (Speech Intelligibility Index),
Hearing aid adjustment device. A hearing aid adjustment method in a hearing aid adjustment device for adjusting a parameter including a gain of a hearing aid, comprising:
Prior to the operation of adjusting the parameters, the first clarity of the user in the non- wearing state of the hearing aid and the second clarity of the user in the first fitting state of the hearing aid are calculated,
Enter the adjustment operation of the parameters,
Calculating the third intelligibility of the hearing aid in the fine adjustment state using the first gain according to the adjustment operation,
Based on the ratio of the difference between the third intelligibility and the first intelligibility and the difference between the second intelligibility and the first intelligibility , the adjustment degree of the hearing aid by the adjustment operation is calculated . Display on output device ,
Hearing aid adjustment method. A hearing aid adjustment program for causing a computer to execute the hearing aid adjustment method according to claim 11 .

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