EP1205090A2 - Hearing aid adapting device - Google Patents

Abstract

Hearing perceptions are inputted (5) into an adaptation calculator (3) that calculates the changes to be made in the parameters (αx) of the hearing aid transmission function and transmits them to the hearing aid (7). The calculator (3) determines which audio test signal (T) is to be pressed on to the person using the hearing aid. To this end, the hearing aid adapting device comprises the above-mentioned calculator (3) and an audio storage medium-playback unit (9). The calculator (3) controls (E9) which audio test signal is to be played back.

Description

Hearing aid fitting device

The present invention relates to a hearing aid fitting device according to the preamble of claim 1.

Hearing aid technology is increasingly moving towards digitally processing audio signals. A digital signal processor unit is used to transmit audio signals, ultimately to an electrical / mechanical output coupler of the hearing aid. The transmission behavior of the hearing aid between the acoustic / electrical input transducer and the electrical / mechanical output transducer is created on the signal processor unit in such a way that individual hearing impairments are largely eliminated by the hearing aid.

It therefore goes without saying that optimum benefit can only be obtained from such hearing aids if - usually in steps - there is first a rough adjustment, then a fine adjustment of the hearing aid, in which the transmission parameters on the hearing aid are adapted to individual needs.

The first rough tuning is usually carried out on the basis of diagnostic data, such as audio programs. On the basis of such data, a first adjustment of at least some of the transmission parameters is carried out on the hearing aid or the hearing aid type is even selected.

The vote is then carried out in situ. In principle, an individual to whom one or two hearing aids are to be fitted is equipped with the hearing aids to be matched and test audio signals are exposed. Most of the time, the individual was A hearing aid is applied to the static data, and the in-situ coordination is now further carried out on the basis of its diagnostic data and / or on the basis of assessments of the individual about his or her listening experience, that is to say listening impressions from his everyday environment. On the basis of this information, it is customary for the hearing aid acoustician to select a test signal suitable for checking the individual assessment from a plurality of test audio signals available, to present this to the individual with the hearing aid applied via loudspeakers and, after a new assessment by the individual, to vote at least one part makes the transmission parameters on the hearing aid.

It is now readily apparent that manual fine-tuning of the transmission parameters on the hearing aids, on the ear of the individual, manually - as by potentiometer operation - is not feasible. For this reason, a communication link to an adaptation computing unit is created on the hearing aids of this type via a corresponding interface.

Based on the assessment by the individual, the computing unit determines, among other things on the basis of a database, which transmission parameters on the hearing aid are to be changed and how.

Experience-based knowledge is stored in the database as to which of the mentioned parameters are to be adjusted, as a function of the mentioned assessments, algorithmic relationships between parameter settings and assessment also being taken into account, for example between an assessment, for example “too loud” and the loudness enhancement or the loudness-determining parameters on the hearing aid. In the simpler case, but not in the most optimal use, the assessment of the individual is made orally to a specialist, such as a hearing care professional. After an appropriate implementation, the latter, on an input unit, usually a computer keyboard, inputs corresponding inputs to the adaptation computing unit.

In order to make the voting procedure in situ as short as possible and as rational as possible for the individual concerned, the move has been made to at least partially standardize the individual reactions and not to transmit them via the hearing aid specialists to the adaptation computing unit, but directly. Input units are used for this purpose, with simple keyboard fields that allow the individual to enter their assessment, for example on a scale. This input unit communicates directly with the adaptation computing unit.

Digital hearing aids are increasingly being adapted according to psycho-acoustic parameters, including loudness. In this regard, reference is made to EP-A-0 661 905 in accordance with US application No. 08/720 748 by the same applicant as the present application. It explains, for example, how the psychoacoustic perception quantity "loudness" can be evaluated scaled by an individual and how a computing unit, according to the test signal response, sets transmission parameters on the hearing aid for the specific critical frequency bands of human hearing. This procedure is described in detail in the document mentioned and is only of importance for the present invention in that it explains, for example, how an adaptation Computing unit, based on scaled loudness information from the individual, provides parameters of the transmission behavior on the hearing aid.

As mentioned, the present invention relates to a hearing aid fitting device of the above-mentioned type, primarily irrespective of how the assessment of the individual is transmitted to the device, directly or via the interpreting specialist knowledge of the specialist. Furthermore, it is irrelevant for the present invention in which way the fitting device is operatively connected to the hearing device (s), e.g. whether wired or wireless. Regardless of these system variants, the present invention addresses the problem that, with regard to the selection of the audio test signals presented to the individual, a high level of specialist knowledge of the person carrying out the adaptation is required and / or that the audio test signals mentioned are not optimally selected in accordance with the respective test situation. The object of the present invention is to remedy this problem.

This is achieved by realizing the hearing aid fitting device of the type mentioned at the outset according to the characterizing part of claim 1. Accordingly, the adaptation device according to the invention comprises an audio storage medium playback unit, the control inputs of which are operatively connected to an output of the computing unit and the audio output of which are connected to a connection for a loudspeaker unit.

This ensures that the selection of presented audio test signals can be optimally situational. The fact that the intended audio storage medium playback unit is controlled by the computing unit makes it possible, in function of the respective assessment, and possibly also diagnostic data to optimally and automatically select the next audio test signal to be presented.

The audio storage medium playback unit can be any such unit, in particular also include one or more memory chips for audio signals or a CD-ROM unit, but is preferably implemented today by a unit that plays audio CDs.

In order, in particular when using a playback unit in which non-intended audio storage media can also be used, such as on an audio CD playback unit with regard to hearing aid adaptation, non-intended CDs, it is proposed according to the wording of claim 3 that a test unit is provided, which checks an audio storage medium for a predetermined identification and, if it is not recognized, blocks the playback unit and preferably outputs a display on a display unit. The labeling mentioned can be of any type, for example in the form of a bar code. In particular, the type of labeling mentioned depends on which category the playback unit is from and which type of audio storage medium is played with it.

If, as preferred, an audio CD playback unit is used, the temporal length information of at least one of the tracks on the CD is preferably fed from an output of the playback unit to a decoding unit of the computing unit, which has a control signal at its output, and according to the wording of claim 4 generated for the operation of the playback unit, as a function of the track time length specification. This procedure, in which track length information is generally used as coding for playback, makes it possible to use audio CDs, that is, non-hybrid CDs to encode information conforming to audio storage.

In this case, length information of tracks on the audio CD that are not intended for the playback of test signals are preferably used, although time length information of tracks that also contain audio test signals can also be used for this. This is because the time length of audio test signals is not critical. It can therefore be immaterial whether an audio test signal and thus the associated track lasts 13 seconds or 15 seconds, although the 2 seconds difference in the sense of the coding mentioned can define different playback modes. However, the aforementioned time length coding is preferably only provided on the audio test signal track if there is certainty that the addressed audio track will also be played when the coded information is required.

This can be the case with an audio track, for example, which is to be played back with every tuning process.

With regard to the above-mentioned marking for determining the playability, track number 20, for example, is thus defined with a length of 11 seconds.

The above-mentioned audio CD coding technique, which is generally specified in claim 4, however, enables further information to be coded flexibly. To check speech intelligibility, it is possible to record speech on the same audio CD.

Provide audio test signals in multiple languages. The tracks assigned to the respective languages are grouped into track groups. The indication of how many track language groups are provided on an audio CD and how many tracks each Including groups is applied to the CD by consistently following the information coding by means of track time lengths, and is accordingly read out and interpreted.

In the automated presentation of audio test signals according to the invention, it is also extremely important to calibrate the loudness level of the presented signals, corresponding to a loudspeaker operating point of the hearing aid. How the audio signal emitted by a loudspeaker unit is ultimately received by the hearing device also depends on the head position and distance between the loudspeaker unit and the individual.

In order to solve this problem, it is proposed, following the wording of claim 5, that a hearing device connected to the adapting device comprises a level detector which is operatively connected to the acoustic / electrical input converter of the hearing device. The computing unit is operatively connected on the output side to an enable control input for the level detector, and the level detector is operatively connected on the output side to an input of the computing unit. The computing unit thus controls when the output of the level detector is effectively connected to it. The input of the computing unit, to which the level detector acts on the output side, is operatively connected to a TARGET level comparison unit, which is used to detect whether the loudness value detected in situ on the hearing aid corresponds to a TARGET value. The output of the level comparison unit is operatively connected to a level control input for the audio output of the playback unit, wherein the computing unit controls the playback unit to play a predetermined calibration memory sector and creates the operative connection from the level detector output to the computing unit. A calibration audio signal is stored in the aforementioned, predetermined calibration storage sector of the storage medium, with respect to which the TARGET level or TARGET value compared with the instantaneous level value is also set. Since this sector, in the case of an audio CD a calibration track, is to be played in any case, it is also quite suitable as a track with the aforementioned coding in its length.

So that the correct, optimally selected test audio signal can now be automatically presented to the individual with the hearing aid applied, the connection for the input unit on the adapting device is operatively connected to a selection unit on the computing unit, the output of which acts on a selection input on the playback unit at which the the next playable storage sector of the audio storage medium is selected or controlled. This basically creates the connection between the input unit and the audio test signal to be selected in each case.

In a further development, the selection unit has a test signal / reaction pattern storage unit, preferably designed as a read-only unit. A large number of different patterns of signals are pre-stored therein, which correspond to possible test signals, possible reaction signals or assessments - from the input unit - each of these test signals / reaction signal patterns defining a next test signal that is now to be activated.

The output of the above-mentioned memory unit is cyclically operatively connected to a comparison unit in a controlled manner. With the second input of the comparison unit mentioned the connection for the input unit is operatively connected. If the input unit therefore has an assessment of a test signal, the comparison unit determines which pattern of reactions or assessments with respect to the current test signal corresponds to the present reaction / test signal situation or at least best correlates it. If this pattern, which is one of the test signal / reaction signal pattern storage unit stored, is recognized, the fact that the output of the comparison unit acts on the output of the selection unit, the corresponding audio storage medium segment found to be optimal for this pattern Generation of the next test signal activated, according to claim 7.

In a further preferred embodiment, not only is the currently prevailing test signal / reaction pattern compared with the previously stored patterns, but, in addition, it is possible to include the test history by connecting pattern history memory units upstream of the connections of the comparison unit .

In a further preferred embodiment, the connection for the input unit is followed by a controlled decoder.

The advantages of the provision of such a decoder are to be explained on the basis of the detailed description below. However, it must be assumed in advance that standardized assessment criteria must ultimately be available on the computing unit for the parameter adjustment on the hearing aid. Is the assessment input, especially if it is made directly by the individual, with assessment terms of everyday language nom s, such as with terms "too dull", "too high-pitched" etc., the decoding unit mentioned, to which signals corresponding to these terms are applied, uses the decoding table to determine one or more situations on the output side which are determined by psychological Acoustic standard terms are defined and which, on the one hand, allow, in the sense of the present invention, automatic access to the audio test signals provided, but on the other hand also allow parameters to be set on the hearing aid.

The decoding is again based on empirical values.

The present invention further relates to a method for adapting a hearing aid according to the wording of claim 10 and an audio CD according to the wording of claim 11.

The invention is subsequently explained using figures, for example. These show:

1 shows an overview of a signal flow / function block diagram of the matching device according to the invention;

FIG. 2 in the form of a simplified signal flow / function block diagram, a preferred selection technique for test signals on the device according to FIG. 1;

3 in the form of a simplified signal flow / function block diagram, a further possibility of selecting a test signal to be played next in the procedure according to the invention according to FIG. 1;

4 in the form of a simplified function block / signal flow diagram, precautions on the inventive fitting device according to FIG. 1 to prevent playback of non-intended audio storage media;

5 shows schematically the structure of an audio CD encoded according to the invention;

6 again in the form of a simplified signal flow / function block diagram, precautions on the device according to the invention according to FIG. 1 or FIGS. 1 and 2 for calibrating the audio test signals presented automatically according to the invention with regard to loudness level, and

7 in a representation analogous to FIGS. 1 to 6, precautions for decoding simple reaction inputs into standardized multi-signals on the device according to the invention.

For the time being, it should be emphasized that all of the following design examples open up many system implementation variants for the person skilled in the art. The person skilled in the art also has many possibilities for the electronic detailed realization of the embodiments presented.

1, the hearing aid adapter 1 comprises a computing unit 3, which acts on the output side on a connection A ₃ for one or two hearing aids 7. The computing unit 3 also has, on the input side, a connection E ₃ for an input unit 5, be it a conventional input keyboard, be it a keyboard with a few scaling keys, be it a voice input unit, a mouse, a joystick ect.

On the output side, the computing unit 3 is further operatively connected to control inputs E _{9 of} an audio storage medium playback unit 9, the audio output A _{9 of which is} connected to a loudspeaker unit 11 is operatively connected or operably connectable - via a connection A _xl - by means of which 7 test signals T are transmitted to the hearing aid worn in situ.

The device shown in FIG. 1 basically works as follows:

The individual wearing the hearing aid 7 is exposed to a test signal T. The reaction or assessment of the individual to the test signal T is fed via the input unit 5 to the computing unit 3 of the adaptation device 1 by direct manual input or by oral reporting to a specialist and subsequent input.

FIG. 2 shows a first embodiment variant of how, viewed in combination with FIG. 1, the playback unit 9 is controlled by the computing unit 3. It denotes H "manual entry". On the basis of an individual's assessment of his or her hearing experience with a hearing aid to be tuned, a hearing aid acoustician will preferably convert the assessment into psycho-acoustic terms, such as loudness, speech intelligibility and sound quality, and enter the weights corresponding to the individual assessment, such as loudness " too high "etc., in terms of speech intelligibility" too shrill ", in terms of sound quality" too reverberant ".

This input with the appropriate weighting is fed to a selection unit 8. In the simplest case, the selection unit 8 assigns an assigned audio test signal T to each implemented assessment B1, B2 ... in accordance with the manual inputs. Since several assessments B can be optimally assigned one and the same audio test signal T and, in a further development of the invention, the test signals T can be assigned to B assessments based on logical combinations such as AND, OR etc., is preferably - and as in Fig. 2 also shown - a selection unit 8 is provided, on the one hand the assessment _signals B are supplied and on the other hand - as _shown schematically with H _L0G - the logical link type can be entered, with which the assessment inputs B are to be linked and which on the output side Trigger the optimal test signal T for the assessment combination at hand.

Looking back at FIG. 1, the arithmetic unit 3, based on and in function of the assessment of corresponding inputs R-, controls the playback unit 9 via the control input E _g to play a selected audio test signal, and the test signal T is played back via the loudspeaker unit 11.

In this case, the selected audio test signal T is preferably played back in a looping or repeating manner, and — as shown schematically in FIG. 1 with the switching unit 10 — the operator manually activates the parameter adjustment on the hearing device 7, in which the computing unit 3 and the transmission behavior of the hearing aid is adjusted in accordance with the then prevailing assessment signals B according to FIG. 2.

The manual inputs according to H from FIG. 2 are made via the connection E ₃ for the input unit 5 from FIG. 1.

FIG. 3 schematically shows, based on a simplified function block / signal flow diagram, a further development of the device according to the invention or the inventive according to the appropriate adjustment procedure. An individual storage unit 50 and a standard storage unit 52 are provided on the arithmetic unit 3. The audio test signals T _G that are experienced during the in-situ adaptation procedure and, coupled with them, the individual assessments that are experienced are correspondingly coupled in the individual storage unit 50 the input signals at E ₃ of FIG. 1 are stored and continuously supplemented during the procedure. Thus, the adaptation procedure that has been experienced so far is stored in this memory 50. Analogously, a large number of possible test signal and assessment histories that have been lived through are stored in the standard memory unit 52 as a database, together with the respective identification of an audio test signal T ₀ to be played next, which was found to be optimal for a further adaptation step in the respective histories. The data in the standard storage unit 52 were determined by tests and experience and stored in the unit 52, which is preferably designed as a read-only memory. According to FIGS. 1 and 2, when the input for the assessment of significant quantities according to B of FIG. 2 is made at the moment, the individual memory 50 is updated on the one hand. The adjustment history that is now lived through, stored in the individual memory 50, is carried out on a comparison unit 53 compared with the standard adaptation stories stored in the standard storage unit 52 and ascertaining from them the one which best matches the one currently stored in the individual memory 50. Thereupon, the assigned audio test signal T ₀ , which is optimally to be played next, is read from the found history from the standard memory unit 52 and, according to FIG. 1, the assigned medium sector is controlled at the control input E _{9 of} the playback unit 9. In this way, the procedure according to the invention, according to FIG. 1, basically enables the automatic triggering of audio test signals T to be played back after assessment inputs, directly and / or in a refined form, taking into account already experienced individual adaptation steps.

Some preferred, further functions of the matching device 1 according to the invention, which is presented in principle with reference to FIGS. 1 to 3, will then be considered.

Particularly when using a playback unit 9, which can also be supplied with storage media 20 that are not specific to hearing aid adaptation, according to FIG. 4, when the audio storage medium 20 is read into the playback unit 9, the output A_. _{2 of} a number plate detector 22 - as shown schematically with the switch S ₂₂ - fed to the one input E _{24 of} a comparator unit 24, at the second comparison input E _{242 of} which the output A_. _{s of} a TARGET identification memory 26 is supplied. If the identifier KZ registered by means of the detector 22 does not match the one previously stored in the memory 26, the playback of the medium 20 which has just been inserted is blocked at a control input E _{91 of} the playback unit 9, the medium possibly ejected and the situation on a display unit 28 displayed. If the detected identifier KZ matches the DESIRED identifier KZ-SOLL, then a signal is transmitted from the output Y of the comparator unit 24 to an input E _{31 of} the computing unit 3, possibly also - as shown in dashed lines - to the display unit 28, with which the adaptation procedure can start.

Information on the medium 20 is preferably used as the identifier which is to be detected with the detector 22 provided, which is read out with the same device as the audio signals afterwards. In the case of an audio CD, the identification information is therefore preferably applied to the medium 20 like audio information and is read out first when a CD is inserted.

Although it is readily possible to provide coding by applied audio signals, for example frequency-selective, in the case of an audio CD, which is preferably used today as the playback medium, a preferred coding technique, which is per se considered to be inventive, is subsequently shown schematically using

5 explains which also shows the structure of an audio CD according to the invention.

An audio CD according to the invention, shown in its track structure in FIG. 5, comprises a first group M of tracks, which comprises non-language-specific audio test signals, for example music, noises, etc. The CD further comprises one or more group (s) S _ιr S ₂ ... of tracks which contain group-specific speech recognition test signals in a corresponding number of different languages. For example, group S. is built up by German-language tracks, group S ₂ by English-language tracks, etc.

The CD according to the invention now further comprises one or more coding track (s) C _τ , which may at least partially also include audio test signals, but only in exceptional cases.

It is essential that - like the other tracks on the CD and, as is customary with any audio CD player - the time lengths Δt of the respective tracks are read out and output at an output, according to FIG. 4, corresponding to FIG. ₁₂ . As is now shown in a table in FIG. 5, the length of the tracks CT is thus brought that this length contains information for the operation of this CD. For example, the track length Δt _x on a CT track No. 1 of 15 seconds means that four language groups S are provided on the CD, a track length of 14 seconds means that only four S groups are provided, etc. On another CT track means, for example, a length Δt ₂ of 15 seconds that five tracks are provided in each of the language groups S, the length 14 seconds that only four tracks are provided, etc.

Looking back at the problem of CD detection mentioned above, it is now readily apparent that one of the CT tracks with a predetermined length is used for this purpose, and that every audio CD whose corresponding track is not of a predetermined length is ejected as an impermissible CD becomes. For this, e.g. the loudness calibration track already described in the introduction, which is to be played in any case, is used.

In this way, it is possible to change the CDs according to the invention in a highly flexible manner and to encode the information required for the playback operation on the CDs without using any coding means that are foreign to the type for the production of audio CDs.

Before test signals are now output, it is practically essential to calibrate their loudness level to the operating point of the hearing device 7. 1, it can be seen that this should also be done because, for example, the distance between loudspeaker unit 11 and hearing device 7, head position and ear shaping etc. of the individual have an effect on the loudness level recorded on hearing device 7. The calibration procedure also explained with reference to FIG. 6 can be triggered at any time by manual input to the computing unit, that is, also between two audio test signals T. Triggered by the calibration switch S _κ shown schematically in FIG. 6, the computing unit 3 outputs an output A ₃₂ to the playback unit 9, to a control input E ₉₂ , a control signal SELKAL, which positions a drive 29 for the readout device 31 - as shown schematically - on a predetermined calibration storage sector 33 of the medium 20. The calibration test signal T _κ is transmitted from this sector 33 to the loudspeaker unit 11 and transmitted to the hearing aid 7 shown enlarged in FIG. 3 on the ear of the individual.

A level detection stage (not explicitly shown) is provided on the digital signal processing unit DPS of the hearing aid 7, which outputs an output signal P (T _κ ) dependent on the current loudness level at an output A ₇₁ . Simultaneously with the creation of an operative connection between the output A _{71 of} the level detector and the computing unit 3 - shown schematically by closing the switch S ₇ - the computing unit 3 controls the playback of the calibration sector on the medium 20. The level signal P (T _K ) is applied to one input E _{351 of} a calibration comparison unit 35. The comparison unit 35 is further supplied, at a second input E ₃₅₂ , with a SET level signal P _s . The comparison result or the comparison difference Δ is fed to the gain control input E _{36 of} an amplifier stage 36 provided in the audio signal path of the playback unit / loudspeaker unit, whereupon the gain G is repeatedly adjusted in a regulating sense until the calibration signal received by the hearing device 7 Test signal T _κ the SET Level P _s corresponds and thus the loudness operating point of the hearing aid 7.

With reference to FIG. 2 in combination with FIG. 1, it was explained how an audio test signal ultimately resulted from the input and weighting of psycho-acoustic terms - derived from the assessment of the listening experience by the individual, directly or through the use of logical combinations of assessment variables B. T is selected and output.

In particular, if the aim is that the individual inputs his assessment inputs directly to the arithmetic unit - that is, according to FIG. 1 to E ₃ - this procedure has to be refined because the individual is not trained to convert his or her listening experience into the weighted, standardized psychological to implement acoustic greats. For this purpose - as will be explained with reference to FIG. 7 - a decoding unit is provided on the computing unit. The representation is based on a procedure in which, switchable, both inputs by the specialist, according to FIG. 2, and inputs by the individual should be possible. In FIG. 7, the signal paths B denote the assessment variables which have already been explained, expertly entered and weighted using FIG. 2. I also refer to the individual assessment values, which are also entered at input E ₃ with a view to FIG. 1, as generally "reverberant", "dull", "distorted".

A decoding unit 40 is provided on the arithmetic unit 3 according to FIG. 1, in which, in the form of a decoding table, the standardized psychoacoustic evaluation variables, corresponding to B, are used to represent the individually entered I. For example, the Individually entered terms "distorted" mean that the loudness is too high and / or the intelligibility is too high and / or the sound quality is distorted. On the output side of the decoding unit 40, those psycho-acoustic evaluation variables corresponding to B are switched through to the selection unit 8 according to FIG. 2 which best represent the individually entered evaluation criterion psycho-acoustically. The selection unit 8 then controls the playback of the correspondingly optimal audio test signal, as previously explained.

With the adapting device according to the invention, it becomes possible to tune, in particular fine-tune, hearing aids in a highly targeted and economical manner. In order to take into account different auditory practices, for example, according to different language regions, adapted ones can be made

Audio storage media are used, or test signals in different languages are provided on one and the same storage medium, each of which is selected by initial language selection at a control input unit.

Claims

Claims:

1. Hearing aid adapter with an arithmetic unit (3), operatively connected on the input side with a connection (E ₃ ) for an input unit (5), on the output side with a connection (A ₃ ) for a hearing aid (7), characterized in that an audio storage medium Playback unit (9) is provided, whose control inputs (E ₉ ) are operatively connected to the computing unit (3) on the output side and whose audio output (A ₉ ) is operatively connected to a connection for a loudspeaker unit (11).

2. Adaptation device according to claim 1, characterized in that the playback unit (9) comprises at least one audio memory chip or, and preferably, is a CD playback device, particularly preferably an audio DC playback unit.

3. Adaptation device according to one of claims 1 or 2, characterized in that a test unit (24) is provided, which tests an audio storage medium (20) on the playback unit (9) for a predetermined identification and, if not known, the Play unit (9) blocks and preferably outputs a display on a display unit (28).

4. Adaptation device according to one of claims 1 to 3, characterized in that the playback unit (9) is an audio CD playback unit, that the length (Δt) of at least one of the tracks from an output (A ₂₂ ) of the playback unit ( 9) is supplied to a decoding unit of the computing unit, which generates a control signal for the operation of the playback unit at its output.

5. fitting device according to one of claims 1 to 4, characterized in that a hearing aid (7) to the connection (A ₃ ) for a hearing aid of the computing unit is connected, that on the hearing aid (7) a level detector (DPS) is operatively connected to the acoustic / electrical converter (7a) of the hearing aid (7), that furthermore the computing unit (3) on the output side (A ₃₂ ) creates the operative connection between the output signal (A ₇₁ ) of the level detector (DPS) and an input (E ₃₅₁ ) of the computing unit (3) in a controlled manner, which input (E ₃₅₁ ) is operatively connected to a TARGET level comparison unit (35) , whose output (Δ) acts on a level control input (E ₃₆ ) for the audio output (A ₉ ) of the playback unit (9), the computing unit (3) responding to a control signal (SELKAL) the playback unit (9) for playing a controls the predetermined storage sector (33) of the audio storage medium (20) and creates the operative connection between the level detector output and the computing unit (A _71; E ₃₅₁ ) (S ₇ ).

6. Adaptation device according to one of claims 1 to 5, characterized in that the connection (E ₃ ) for the input unit is operatively connected to a selection unit (8; 50, 53, 52) on the computing unit (3), the output of which a selection input (E ₉ ) on the playback unit (9) is operatively connected, whereby a storage sector of the audio storage medium (20) is selected on the playback unit for playback.

7. Adaptation device according to claim 6, characterized in that the selection unit comprises a test signal / reaction signal pattern storage unit (52), preferably designed as a read-only storage unit, that the output of this storage unit (52) with the one input one Comparison unit (53) is operatively connected to the second input of the comparison unit (53), the connection (E ₃ ) for the input unit (5), the output of the comparison unit (53) being operatively connected to the output of the selection unit.

8. fitting device according to claim 7, characterized in that the connections of the comparison unit (53) model history storage units (50, 52) are connected upstream.

9. Adaptation device according to one of claims 1 to 8, characterized in that the connection (E ₃ ) for an input unit (5) is operatively connected to a decoding unit (40), which from input data (I) from the Input unit, after stored decoding tables, generates output data at a decoding unit output which is operatively connected on the input side to the computing unit (3) and is preferably operatively connected to a display device.

10. Method for adapting a hearing aid in situ, in which an individual with at least one applied hearing aid is subjected to an audio test signal in accordance with an assessment input about his hearing experience and in accordance with the respective reaction of the individual parameters influencing the transmission behavior of the hearing aid on the hearing aid optimized, characterized in that an audio test signal is automatically selected and played as a function of the input.

11. Audio CD with a plurality of tracks, characterized in that the temporal length of at least one track uniquely identifies at least one structure of tracks provided on the CD.