1. Field of the Invention
The present invention relates to a method for fitting a hearing aid, and more particularly to a method with which a user can adjust a hearing aid himself.
2. Description of the Related Art
In the fitting of a hearing aid, it is becoming increasingly common for the user of the hearing aid to be present at the fitting.
The fitting of a hearing aid can be extremely difficult, and the fitting will end up being unsatisfactory to the user unless there is good communication between the fitter and the user.
In view of this, there is a method in which the fitter performs a first fitting, and fine tuning is performed by the user himself, so that the user will be better satisfied with the result.
More specifically, after the first fitting, the user manipulates countless fitting points provided on a screen, and evaluates how well he can hear at that point, which allows the user to achieve the fitting best suited to his needs from among the countless fitting points provided.
For example, Patent Literature 1 below discusses a fitting method in which fitting points are manipulated on a screen.
In Patent Literature 1, because hearing aids are used in a wide variety of locations, the optimal parameters under a variety of environments are considered, with the goal of finding the parameters that suit the user's preferences. This method involves finding a good balance of adjustment parameters on a two-dimensional plane made up of the optimal parameters under a plurality of environments.
In Patent Literature 2 below, parameters produced by a genetic algorithm are evaluated, and the parameters with which the highest score was obtained are arranged in a matrix so that a listening comparison can be conducted at the end.
Patent Literature 1: Japanese Laid-Open Patent Application 2001-238294
Patent Literature 2: Japanese Laid-Open Patent Application 2001-175637
In Patent Literature 1 above, fine adjustment is carried out for a variety of environments, but when the goal is to adjust the hearing aid to suit the user's preferences in regard to his basic hearing, then in order to adjust the basic hearing of sounds, the adjustment must include not only parameters that allow the user to hear words clearly and the user's preferred sound quality, in addition to a space constituted on the basis of optimal parameters found for various environments as in prior art, but also parameters that cannot be heard clearly or are not to the user's liking, for example, so that the good parameters can be distinguished, and the user must decide on these.
With the method in Patent Literature 1, which utilizes a two-dimensional space constituted on the basis of optimal parameters under a variety of environments, it is difficult to realize a search space as a two-dimensional space so that the user will be comfortable with adjustment of basic hearing. Also, obtaining optimal parameters under various environments itself ends up taking a long time.
With Patent Literature 2, parameters arranged in a matrix are just those with a high score, and there is no hearing comparison with respect to the realistic parameters or parameters that are not of the user's preference. Accordingly, fine adjustment of hearing that is close to these parameters cannot be performed to the user's satisfaction. And finding parameters that give a high score takes a long time in the first place.
In view of this, the present invention provides a hearing aid fitting apparatus with which it is a simple matter to produce the space the user is looking for, and the basic hearing of the user can be simply and quickly checked by the user himself, which makes the process more convenient.
To achieve the stated object, the present invention comprises the steps of displaying the coordinate positions of a plurality of adjustment parameters and the results of evaluating these parameters on a display section, using those parameters with a good evaluation result to set a fine adjustment recommended area in the coordinate positions on the display section, displaying manipulated marks at the manipulated coordinate positions within the fine adjustment recommended area, putting selection candidate displays at the coordinate positions where favorable evaluations were obtained out of the coordinate positions where the manipulated marks have been displayed, and registering the selected coordinate position parameters, out of the coordinate positions where the selection candidate displays have been put, as fitting parameters in a hearing aid.
The present invention makes it more convenient to do the fitting of a hearing aid.
Specifically, with the present invention, since a fine adjustment recommended area is set in coordinate positions on a display section, the coordinate positions manipulated by the user can be narrowed down to a more suitable number. As a result, hearing aid fitting takes less time and the process is more convenient.
An embodiment of the present invention will now be described in detail along with the drawings. Embodiment 1
In
A display section 5 is provided to the fitting device 4. An input section 6 is also connected to the fitting device 4. In the configuration in
In this embodiment, parameters based on well known fitting theories, such as NAL-NL1, DSL,
In this state, as shown in
More specifically, in this case, of the four fitting theories, the user 2 picks No. 1 as the best, and No. 3 as the least favorable. Thus, a display indicating most favorable is made at the coordinate position of the parameters produced on the basis of the No. 1 fitting theory, and a display indicating unfavorable is made at the coordinate position of the parameters produced on the basis of the No. 3 fitting theory.
The above-mentioned parameter map has close parameters arranged in close cells, and has the parameters arranged so that the hearing is more different in distant cells than in close cells.
More specifically, those parameters with similar output characteristics for each frequency are disposed closer, and those with different characteristics are disposed farther away, making a gradual change on the parameter map. Giving the parameter map this feature allows the user to search for parameters more intuitively.
During production of the parameter map, parameters are produced over a range that allows fine adjustment, centering on parameter values calculated by a fitting theory from the user's hearing ability, or the current adjustment value upon switching to this adjustment mode, and the parameters thus produced are used to produce a predetermined N×N two-dimensional parameter map by means of a self-organized map (SOM) or another such dimensional compression technique. In producing parameters over a range that allows fine adjustment, it is preferable to take into account the limit to output without causing ear damage, the lowest value for output determined from hearing ability, and the like. How the map is produced is not limited to the above-mentioned method involving a self-organized map, and any other method may be used instead, such as multi-dimensional scaling.
In this embodiment, as shown in
Meanwhile, a fine adjustment non-recommended area 12B is set using the unfavorable parameter (No. 3). A method in which the gain at various frequencies is within ±10 dB may be used, for example, for the fine adjustment non-recommended area as well.
The fine adjustment recommended area 12A and the fine adjustment non-recommended area 12B may in some cases be near each other and overlap. If this happens, the recommend area is preferably set so that there is no overlap between the two areas.
The user 2 looks at the display section 5 in
In this embodiment, the manipulated marks 13 change the color of the coordinate positions, or apply hatching. In
In
Of the plurality of selection candidate displays 14, the selection confirmation display 15 that is subsequently selected and put in a coordinate position is displayed in a different form from that of the selection candidate displays 14, as shown in
In this embodiment, as discussed above, the fine adjustment recommended area 12A is set in the coordinate positions on the display section 5. Accordingly, the coordinate positions manipulated by the user 2 are narrowed down to a suitable number. As a result, manipulation time is shortened and the process can be made more convenient.
As shown in
In this embodiment, four fitting theories were utilized in the initial candidate calculation of S2, but the initial candidates are not limited to this method.
For instance, after one initial candidate has been found on the basis of one fitting theory and the user's hearing ability, changes can be made to that initial candidate, such as “emphasize the high band,” or “emphasize the low band,” or “raise the overall gain,” with a plurality of these being produced, and these can be the initial candidates used in S3.
As discussed above, with the present invention, a fine adjustment recommended area is set in the coordinate positions on the display section, so the coordinate positions manipulated by the user can be narrowed down to a suitable number. As a result, the manipulation time is shorter and the process can be made more convenient. Therefore, this method for fitting a hearing aid is expected to find wide application.
Number | Date | Country | Kind |
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2011-182399 | Aug 2011 | JP | national |