EP1073314A1 - Method for fitting a hearing aid and hearing aid - Google Patents

Abstract

The method involves detecting auditory, involuntary body signals from the wearer of the hearing aid using a measuring device connected to the wearer. An evaluation device generates starting parameters for the hearing aid based on the measured values. These parameters are transferred to the signal processing unit of the hearing aid for individual adjustments. A signal may be fed to at least one ear of the wearer of the hearing aid. The measuring device detects the involuntary body signals caused by this signal. The signal may be acoustic, electrical, electromagnetic or mechanical.

Description

The invention relates to a method for adapting a Body portable or implantable hearing aid with at least an input converter, a signal processing unit and an output converter.

The invention further relates to a hearing aid for implementation of such a process.

A hearing aid is usually adapted in the Dialogue between a hearing aid wearer and an acoustician. The hearing aid wearer receives different test signals presented, which he perceives subjectively and his impressions communicates to the acoustician. This compares perception of the hearing aid wearer with the impressions of normal hearing to the respective test signal. From the different sensations the acoustician derives hearing aid parameters that are in generally for an improved adaptation of the hearing aid lead to the hearing aid wearer. This will last so long repeated until the hearing impaired a number of test signals subjectively feels similar to a normal hearing.

A method is known from EP 0 831 672 A2 in which a hearing aid wearer using an interactive fitting program in the performance of sound images on the resulting ones Listening impressions reacted. From the data obtained in this way hearing aid-specific setting parameters are calculated and then transfer to the hearing aid. The dialogue with The acoustician is largely replaced an interactive software.

From the relevant specialist literature, for example S. Hoth, Th. Lenarz "Electrical Reaction Audiometry", Springer-Verlag Berlin, Heidelberg, 1994, is a variety of audiometric Examination methods known, with the help of measurable physiological responses that are normally detectable associated with the hearing process. These procedures include among others: impedance audiometry, tympanometry, stapedius reflex measurement, Measurement of acoustically evoked potentials (AEP), Measurement of otoacoustic emissions (OAE).

The largely automated adaptation of hearing aids to non-cooperative or poorly communicated hearing impaired people with known fitting methods is problematic. Therefore one tries with these groups of people with the help of audiometric Methods an impression of a hearing loss To gain hearing loss. The acoustician then directs from this Parameters that he believes to be improved Guide hearing aid setting. This action takes takes a lot of time and often leads to an imperfect, sometimes even hearing impairment of the hearing aid to the hearing aid wearer.

The object of the present invention is to provide a method for Adapt hearing aids especially to non-cooperative ones or to indicate impaired hearing impaired. It is also an object of the invention to design a hearing aid device such that in this an improved adaptation in particular to non-cooperative or poorly communicated hearing impaired people is achievable.

According to the invention, this object is achieved by a method to adapt a wearable or implantable on the body Hearing aid device with at least one input transducer, a signal processing unit and an output converter, at least one connected to a hearing aid wearer Measuring device auditory, involuntary body signals of the hearing aid wearer and to an evaluation unit forwards the hearing aid-specific fitting parameters from the measured values generated, and wherein the adjustment parameters to the Signal processing unit of the hearing aid for individual Adjustment to be transferred.

The part of the task relating to the hearing aid is solved thanks to an internal measuring and evaluation unit, the adaptation parameters generated from the measured values.

The hearing aid device can be a pocket device Behind-the-ear device (BTE), an in-the-ear device (ITE) or act as an implantable hearing aid. As an input or output converter come electroacoustic transducers, too electromechanical, electromagnetic or electrical transducers (e.g. for direct stimulation of auditory cells) into consideration.

Under auditory, involuntary body signals all body signals related to hearing or caused by hearing understood that not the will of the hearing aid wearer subject to. Verbal utterances or other deliberately brought about Articulations in response to stimulation of hearing are not included.

In order to be able to generate fitting parameters for the hearing aid device, are detailed knowledge of the function or malfunction hearing aid wearer's hearing. According to the Invention this should be objective by measuring and not that Body signal subjected to the hearing aid wearer's will become. It is usually used to carry out an audiological Measure the ear by applying a test signal (Stimulus) stimulates in a certain way and the response detected on the test signal. The inventive method can also be based on measurements on the hearing that cannot be evoked in response to stimulation. An example of this are spontaneous otoacoustic emissions.

Various types of signals are used to stimulate the hearing (Stimuli) such as acoustic, electrical, electromagnetic or mechanical signals possible. The stimuli are audible both via the hearing aid and externally, for example by means of external speakers, as well as via direct connections to auditory cells, for example electromagnetic or mechanical stimulation, deliverable. When stimulating Via the hearing aid, this is either acoustic from the outside or electrical or electromagnetic or optical Test signals supplied, or the test signals are in the hearing aid stored and read out, or they will generated in the hearing aid. These are also synthetic in particular generated test signals can be used to stimulate the hearing. They preferably pass through the hearing aid supplied test signals the signal processing unit of the Hearing aid, and the resulting stimulation of the hearing takes place via the output converter of the hearing aid.

The hearing response to the stimuli can be varied Way to be measured. Essential objective methods for this are:

-Impedance measurement:

Reflect the mechanical properties of the middle ear system in its impedance (complex acoustic resistance) again. This size depends largely on the masses of the ossicles, the dimensions of the external ear canal and Tympanic cavity and the gradients of those in the middle ear Ligaments and muscles. It follows from measuring the impedance the possibility to draw conclusions about to draw pathological changes to the middle ear system. Determination is one of the most important forms of impedance measurement the static impedance, i.e. Impedance measurement when the middle ear system is at rest and the dynamic impedance, i.e. Measurement of impedance during changes in the Middle ear system, e.g. under changes in air pressure outside Ear canal (tympanometry) when opening the ear trumpet (Tube function test) or during contraction of the middle ear muscles (Reflex test). The volume-dependent contraction of the Stapedius muscle when the ear is sonicated Effective especially with very loud sound events and represents a kind of protective mechanism for the hearing. Newer Studies show that there is a connection between the Reflex and subjective thresholds like the MCL (most comfortable level) and the UCL (uncomfortable level). The Stapedius reflex measurement can be done directly by capturing muscle potentials or indirectly by determining the change in impedance respectively.

-Electroencephalography (EEG):

Using an electroencephalograph, bioelectric Potential fluctuations in the brain registered as Spontaneous activity (spontaneous EEG) or as by external Stimulated evoked activity (evoked potentials). The electrodes of the equipped with discharge channels Devices are placed on the top of the skull so that the Combination of two different electrodes (bipolar lead) or a different electrode u. a reference (unipolar derivative) for simultaneous derivatives of different Leads to brain areas. The EEG the potential fluctuations triggered by the acoustic stimuli (evoked potentials) determined.

-Magnetoencephalography (MEG):

Magnetoencephalography is biomagnetic recording of the magnetic fields generated by electrical brain waves. Specifically Multi-channel systems allow the localization of sources bundled nerve cell activity with a time resolution in the Millisecond range and a spatial resolution in the millimeter range. The measurement method provides essential information about the central processing of auditory stimuli.

-Measurement of acoustically evoked currents and / or potentials (AEP):

These include those triggered by sound stimuli and normally electrical associated with auditory perceptions Currents or tensions of physiological origin that in signal forwarding and / or processing in the Nerve cells occur in different parts of the body are derivable. Evoked currents and / or potentials arise during the hearing process, especially in the cochlea, in the auditory nerve, in the brain stem or in the cortex. Often these are signals however, not or only with great difficulty in the places of their greatest Intensity can be tapped. Easier for signal tapping accessible places are the skull surface or suitable Placement of the inner ear or outer ear canal.

-Measurement of otoacoustic emissions:

The ear is not just a receiver of sound waves, it is in turn also sends low intensity acoustic signals out. This acoustic impulse response of a functional Ohrs is called "otoacoustic emission". she allows conclusions to be drawn about the functionality of the ear. For the measurement, the ear is stimulated acoustically and the reaction by means of a highly sensitive one directed into the ear canal Microphones detected.

The previous reactions of an ear to certain Stimuli are only a part of possible hearing reactions The invention is therefore not mentioned by way of example Reactions and their metrological recording limited. The reactions can be used individually to calculate Adjustment parameters are used, but there are also any Combinations of measurements possible, the total ultimately leads to the hearing aid adaptation. In particular, merging and evaluating different ones Measurements in an evaluation unit improved the adaptation and shortens the measurement and adaptation time considerably.

A preferably neural structure of the evaluation unit has been improved the evaluation of results from different measurements and has a positive effect on the convergence behavior of the Adjustment parameters. Control technology is due to the amount of data and the complexity of the measurement results from fuzzy logic to signal processing in the evaluation unit advantageous.

The evaluation unit makes statements from the measurement results about the malfunction of the hearing and generated by means of a suitable software hearing aid parameters for the used Hearing aid. The adaptation parameters determined in this way act the signal processing unit of the hearing aid individual adaptation to the hearing aid wearer.

This is no longer possible with the inventive method subjective perception of the hearing impaired in a particular Stimulus situation on the adjustment parameters, but objective physiological reactions that are not voluntary control subject to the hearing impaired. The negative influence communication difficulties during adaptation between the hearing impaired and the acoustician is thus eliminated.

The inventive method is particularly not or only able to cooperate or have poor communication skills Hearing impaired an advantage. So that's another Circle of hearing impaired people for the use of hearing aids accessible. This particularly includes children or multiple disabled.

The hearing aid wearer is usually located for adaptation in a suitable measuring room and the stimuli presented of an acoustic nature and are via external speakers fed. This has the advantage that it interacts directly with it hearing and hearing aid with the current hearing aid settings under largely natural conditions is verifiable.

According to a further method variant according to the invention the stimuli are directly via the output transducer of the hearing aid fed. For example, in the case of BTE or ITE hearing aids, acoustic signals, it can for example with implantable hearing aids, but also electromagnetic ones or mechanical signals. The hearing aid can be connected to an external device via a signal path are connected to the generation of test signals. Test signals can, however, also be stored in the hearing aid or only be generated in this. So that's it, in particular then, if the measuring and evaluation unit in the hearing aid is integrated, possible automatic adjustment without having to carry out further device units. For example the hearing aid another acoustic-electrical Input converter on, for recording and converting otoacoustic Emissions is directed into the ear canal the hearing aid automatically measures a hearing malfunction and adapt it accordingly.

It is advantageous to use several methods for the method according to the invention Execute iterations or a control loop. To do this stimuli delivered to the hearing, hearing reactions measured, Adaptation parameters generated from the measured values and to the Signal processing unit of the hearing aid. The stimulation is then carried out with the same stimuli and the changed adjustment parameters. From the comparison of several measurements can thus be a strategy for optimizing the adjustment parameters deduce. Especially when stimulating for the first time hearing during an adjustment can be used to generate the stimuli directly from reference values, i.e. without Change through the hearing aid to be given to the hearing.

In an advantageous embodiment of the inventive method there are so many iterations with one test signal until the measured values of the hearing aid wearer reach a certain Test signal are normalized. As a rule, it is necessary the adaptation with different test signals, for example with different frequencies with acoustic stimulation, perform.

An embodiment of the invention is based on a Drawing explained in more detail. The figure shows schematically a measuring room 1 for sound reinforcement on the head 2 of a hearing aid wearer worn hearing aid 3. Via a signal path 4 is the hearing aid 3 with a measuring and evaluation unit 5, the measuring device and an evaluation unit includes connected. At the head 2 of the hearing aid wearer a sensor arrangement 6 is attached and via the signal path 7 connected to the measuring and evaluation unit 5. The hearing of the Hearing aid wearer and the hearing aid 3 is, by the measuring and evaluation unit 5 controlled via the signal path 8 and the speakers 9 for stimulation an acoustic test signal fed. The hearing generates in response to the test signal potential of the hearing aid wearer. This are from the sensors 6 on the surface of the head 2 and tapped in the ears by means of the sensors 10 and via the Signal path 7 of the measuring and evaluation unit 5 supplied. There the signals are amplified and processed. From the Comparison with previous measurements and the measurement results Normal listeners to the same test signal are from the Measured values generated hearing aid-specific fitting parameters. These adjustment parameters are the hearing aid 3 on the Signal path 4 supplied. They bring about changes in the Signal processing of the hearing aid 3. The so adapted Hearing aid settings are further sound checked with the same test signal and possibly further improved. Then the optimization for others takes place Test signals.

Claims (21)

Method for adapting a hearing aid device that can be worn or implanted on the body with at least one input converter, a signal processing unit and an output converter, wherein at least one measuring device connected to a hearing aid wearer detects auditory, involuntary body signals of the hearing aid wearer and forwards them to an evaluation unit that generates hearing aid-specific fitting parameters from the measured values, and the adaptation parameters being transmitted to the signal processing unit of the hearing aid device for individual adaptation. Method for adapting a hearing aid according to claim 1, wherein a signal is fed to at least one ear of the hearing aid wearer, and wherein the measuring device connected to the hearing aid wearer detects involuntary body signals of the hearing aid wearer evoked by this signal. Method for adapting a hearing aid according to claim 2, the ear being an acoustic or electrical or supplied electromagnetic or mechanical signal becomes. Method for adapting a hearing aid according to claim 2 or 3, the ear receiving the signal via the hearing aid (3) is supplied. Method for adapting a hearing aid according to claim 4, wherein the signal fed to the ear in the hearing aid (3) is stored or generated in the hearing aid (3) becomes. Method for adapting a hearing aid according to claim 4, the hearing aid (3) having an acoustic or electrical or electromagnetic or optical test signal is fed. Method for adapting a hearing aid according to claim 6, the test signal being the signal processing unit of the hearing aid (3) and the output converter. Method for adapting a hearing aid device according to a or more of claims 1 to 7, wherein the measuring device evoked currents and / or potentials detected. Method for adapting a hearing aid according to claim 8, the measuring device evoked currents and / or Potentials of the cochlea and / or the auditory nerve and / or the Brain stem and / or the cortex. Method for adapting a hearing aid according to claim 8 or 9, the measuring device evoked currents and / or potentials on the skull surface of the hearing aid wearer and / or on the ear. Method for adapting a hearing aid device according to a or more of claims 1 to 10, wherein the measuring device the acoustic middle ear impedance detected. Method for adapting a hearing aid device according to a or more of claims 1 to 10, wherein the measuring device the strength of the Stapedius reflex detected. Method for adapting a hearing aid device according to a or more of claims 1 to 10, wherein the measuring device otoacoustic emissions recorded. Method for adapting a hearing aid device according to one or more of claims 1 to 13, characterized by a measuring device for electroencephalography (EEG). Method for adapting a hearing aid device according to one or more of claims 1 to 13, characterized by a measuring device for magnetoencephalography (MEG). Method for adapting a hearing aid according to one or more of claims 1 to 13, characterized by a measuring device for tympanometry. Method for adapting a hearing aid according to one or more of claims 1 to 13, characterized by a measuring device for impedance audiometry. Method for adapting a hearing aid device according to a or more of claims 1 to 17, wherein the adjustment parameters taking into account the adjustment parameters from at least a previous measurement. Method for adapting a hearing aid device according to a or more of claims 1 to 18, wherein the adjustment parameters from the difference between measured values of normal hearing and of the hearing aid wearer can be determined. Hearing aid with an input converter, a signal processing unit and an output converter for carrying out the method according to one or more of claims 1 to 19, characterized by a measuring and evaluation unit (5) which generates adaptation parameters from the measured values. Hearing aid according to one or more of claims 1 to 20, characterized by an acoustic-electrical input converter for recording and converting otoacoustic emissions.

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