EP2357851A1 - Method and assembly for adjusting a hearing aid by determining listening effort - Google Patents

Abstract

The method involves detecting the neuronal activity of the brain of a person in response to an acoustic stimulus. A measure of listening effort is determined from the detected neuronal activity. One of the hearing device parameters is changed as a function of the measure of listening effort determined. The determination is repeated and monitored by a computation and control unit until the measure of listening effort drops below a predefinable threshold value or is minimized in terms of a defined termination condition that can be predefined in the computation and control unit. An independent claim is also included for a device for the automatic, recursive adjustment of a hearing device worn by a person, where the device comprises a stimulus generator unit.

Description

The invention relates to a method and an arrangement for the automatic, recursive adaptation of a hearing aid worn by a person, wherein the person is given a hearing task for the solution and objectively an associated hearing effort is detected on the basis of neuropsychological correlates of the auditory processing.

Hearing aids have in principle as essential components an input transducer, an amplifier and an output transducer. The input transducer is usually a sound receiver, z. As a microphone, and / or an electromagnetic receiver, for. B. an induction coil. The output transducer is usually used as an electroacoustic transducer, z. As miniature speaker, or as an electromechanical transducer, z. B. bone conduction, realized. The amplifier is usually integrated in a signal processing unit. This basic structure is in FIG. 1 illustrated by the example of a behind-the-ear hearing aid 1. In a hearing aid housing 2 for carrying behind the ear usually two microphones 3 are incorporated for receiving the sound from the environment. Above the microphones 3 microphone openings 7 are formed in the hearing aid housing 2. Through the microphone openings 7, the sound can reach the microphones 3 in the interior of the hearing aid housing 2. A signal processing unit 4, which is also integrated in the hearing aid housing 2, processes the microphone signals and amplifies them. The output signal of the signal processing unit 4 is transmitted to a loudspeaker or receiver 5, which outputs an acoustic signal. The sound is optionally transmitted via a sound tube, not shown, which is fixed with an earmold in the ear canal, to the eardrum of the hearing aid wearer. The power supply of the hearing aid 1 and in particular that of the signal processing unit 4 is effected by a likewise integrated into the hearing aid housing 2 battery. 6

In the DE 10 2008 018 041 A1 such a behind-the-ear hearing aid with a microphone opening, with a volume control, with a programming jack, with a program button with off function and a battery compartment disclosed.

The adaptation of a hearing aid is usually in dialogue between a hearing aid wearer and a hearing care professional. The hearing aid wearer thereby different test signals are presented, which he perceives subjectively and tells his impressions to the acoustician. This compares the perception of the hearing aid wearer with the impressions of normal hearing with respect to the respective test signal. From the different perceptions, the acoustician derives hearing device parameters, which as a rule lead to an improved adaptation of the hearing device to the hearing device wearer. This procedure is repeated until the hearing-impaired subjectively feels a number of test signals subjectively similar to a normal hearing.

As the DE 41 28 172 A1 There has long been a need to replace subjective measurements of hearing with objective measurements and any subsequent correction of hearing aid parameters. Recent research in the field of the objective determination of hearing effort seems to offer new perspectives in this sense. For example, in DJ Strauss et al., "On the Cognitive Neurodynamics of Listening Effort: A Phase Clustering Analysis of Large-Scale Neural Correlates, 31st Annual International Conference of the IEEE EMBS Minneapolis, Minn., USA, September 2-6, 2009, pages 2048- 2081 proposed to determine the hearing effort from the brain's electrical neural activity through mathematical transformation analysis.

It is therefore an object of the invention to objectify the setting of hearing aids, to automate and in relation to to improve neuropsychological variables of hearing processing.

According to the invention, the stated object is achieved with the method and the arrangement of the independent claims.

The invention claims a method for the automatic, recursive adaptation of a hearing aid worn by a person controlled by a computer and control unit, whereby the person is provided with a listening task and an associated hearing effort is objectively recorded on the basis of neuropsychological correlates of the auditory processing. With the method, at least one acoustic stimulus is presented to the person, detects the neural activity of the brain of the person due to the acoustic stimulus, a measure of the hearing effort from the detected neural activity determined by a computing and control unit at least one hearing aid parameter depending on the determined Modified measure of Höranstrengung changed and the process controlled by the arithmetic and control unit repeatedly until the extent of Höranstrengung falls below a predetermined first threshold or is minimized in terms of a previously defined Abbruchskriteriums the computing and control unit. The invention offers the advantage that hearing aids can be adjusted objectively and automatically with regard to neuropsychological parameters in a very robust and reliable manner.

In a further development, several acoustic stimuli are presented, the neural activities recorded and the detected neural activities subjected to a mathematical analysis for feature extraction.

In a further embodiment, the feature extraction may also be defined on the image area of suitable mathematical transformations (eg, complex time-frequency transformations).

Furthermore, the acoustic stimulus may comprise a word sequence, a speech sequence or a sequence of tones.

In a development of the method, the neuronal activity of the brain can be detected by an electroencephalogram.

In a preferred embodiment, an auditory late response can be determined from the EEG.

Furthermore, from complex transformations (e.g., Hilbert, complex wavelet transformation, Gabor frame transformation) of at least two auditory late responses, the inter-trial phase stability obtained via the feature of the instantaneous phase can be determined.

Preferably, the inter-trial phase stability can be the measure of the hearing effort.

In a further embodiment of the method, the neuronal activity of the brain can be detected by a magnetoencephalogram.

In another embodiment of the method, the neuronal activity of the brain may also be detected by functional imaging techniques (e.g., fMRI, PET, SPECT, fOCT).

Preferably, the changes in the hearing aid parameters can be determined by means of evolutionary algorithms. This allows multidimensional stochastic optimization.

The invention also claims an arrangement for automatic recursive adjustment of at least one hearing aid worn by a person controlled by a computer and control unit. The arrangement comprises a stimuli generator unit which supplies at least one acoustic signal to the hearing aid Stimulus outputs, a signal acquisition unit with at least one sensor that detects a neuronal activity of the brain of the person due to the acoustic stimulus, a computing and control unit that determines a measure of the hearing effort from the detected neural activity and determines changes in hearing aid parameters, as well as a Hearing aid control unit that changes the hearing aid parameters. The computing and control unit repeatedly causes the stimuli generator unit to deliver a hearing stimulus and the hearing aid control unit to selectively change a hearing aid parameter according to an optimization rule until the amount of hearing effort falls below a predefinable first threshold or in the sense of another previously defined in the arithmetic and control unit Termination condition is minimized.

In a development of the arrangement, the acoustic stimulus may comprise a word sequence, a speech sequence or a sequence of tones.

In a further embodiment of the arrangement, the signal acquisition unit and the at least one sensor can detect the neuronal activity of the brain by means of electroencephalography.

Furthermore, the signal acquisition unit can determine at least one auditory late response.

The arithmetic and control unit can preferably determine a mean inter-trial phase stability from at least two auditory late responses.

In the arrangement, the instantaneous phase determined by way of complex transformations can preferably be used for calculating the inter-trial phase stability, which is used as a feature for quantifying the hearing effort.

In a further embodiment, the signal acquisition unit and the at least one sensor can detect the neuronal activity of the brain by means of magnetoencephalography.

In a further embodiment of the arrangement, the neuronal activity of the brain may also be detected by functional imaging techniques (e.g., fMRI, PET, SPECT, fOCT).

In addition, in the computing and control unit, the changes in the hearing aid parameters can be determined by an evolutionary algorithm.

Other features and advantages of the invention will become apparent from the following explanations of several embodiments with reference to schematic drawings.

Figur 1:

ein Blockschaltbild eines Hinter-dem-Ohr Hörgeräts gemäß Stand der Technik,

Figur 2:

ein Ablaufdiagramm des Verfahrens zur Einstellung eines Hörgeräts durch Ermittlung der Höranstrengung aus der IPS und

Figur 3:

ein Blockschaltbild einer Vorrichtung zur Anpassung von Hörgeräteparametern mit Hilfe eines EEG.

Show it:

FIG. 1:

a block diagram of a behind-the-ear hearing aid according to the prior art,

FIG. 2:

a flowchart of the method for adjusting a hearing aid by determining the hearing effort from the IPS and

FIG. 3:

a block diagram of a device for adaptation of hearing aid parameters using an EEG.

FIG. 2 shows a flowchart of the inventive method for adjusting at least one hearing aid parameter of a hearing aid. In the first step 100, a person is prepared for the hearing aid setting.

The person carries on each ear a switched on and functional hearing aid, ie the person carries the hearing aid according to the instructions behind the ear. The hearing aid parameters, such as channel gain, compression rate, compression breakpoint, microphone characteristic, noise reduction, time constants, are in a basic setting, which was determined, for example, by an audiogram.

To measure a summed electrical activity of the subject's brain, the voltage fluctuations on the subject's head surface must be recorded by electroencephalography (EEG). The electroencephalogram (also abbreviated to EEG) is the graphical representation of these fluctuations. Cause of the potential fluctuations are physiological processes of individual brain cells, which contribute by their electrical state changes to the information processing of the brain. Depending on their specific spatial arrangement, the potentials generated by individual neurons add up so that potential changes distributed over the entire head can be measured. For evaluation, a recording in several channels of different electrode combinations is needed. For this purpose, the person several electrodes are attached to the scalp.

In the following preparatory step 101, the person is given a hearing task by a hearing care professional, for example to recognize the spoken syllable "pa" from a spoken syllable sequence with the spoken syllables "pa", "da" and "ba", the speech syllables in any order and repetition may occur.

In step 102, the person is presented with an auditory stimulus in the form of a spoken syllable sequence mentioned above. The presentation can be done directly with the hearing aid or indirectly via headphones or speakers. In the latter case, the hearing aid acoustically picks up the auditory stimulus. The person tries ("struggles") to solve the listening task ("Recognize the Syllabus" pa ""). Optionally, also tone sequences or complete sentences can be presented.

In step 103, which is performed in parallel to step 102, the neuronal activity of the subject's brain is measured by EEG. That is, it will be the electrical potentials measured between scalp-mounted electrodes.

In step 104, the acoustically evoked potential, in particular the auditory late response ALR, is determined from the EEG.

Steps 102 to 104 are repeated several times to improve the signal-to-noise ratio of the very weak potentials. From the ALRs thus determined, the determination of an Inter-Trial Phase Stability (IPS) obtained via complex transformations and the instantaneous phase is carried out in step 105, which is a measure of the hearing effort LE. The IPS can take values between "0" and "1", where "1" means a large listening effort LE. The IPS indicates the stability of the instantaneous phase of the ALRs for defined times.

In the following step 106, at least one hearing aid parameter is automatically changed with the aim of reducing the hearing effort LE. This multi-dimensional optimization problem is preferably solved by means of an evolutionary algorithm running in a computing and control unit.

The optimization progress of the hearing aid parameters is checked in step 107 by repeating steps 102 to 106 after each change in the hearing aid parameters and determining the change in the hearing effort LE between two examinations of the hearing effort LE. If the change falls below a predefinable second threshold value, for example 0.2, the method is terminated with step 108 and the hearing device is optimally adjusted with respect to the listening effort. Alternatively, another, previously defined termination condition in the computing and control unit may detect a minimum listening effort (LE).

Optionally, other physiological stimuli, such as visual or tactile, may also be presented to the person. In addition, the person can optionally also have an operating unit signal the subjective solution of the listening task. This can be used to monitor the improvement in the hearing aid setting.

FIG. 3 shows a simplified block diagram of an inventive arrangement for adaptation of hearing aid parameters using a determined listening effort. A person 16 wears two hearing aids 10 for the treatment of a deafness and for measuring a neural activity of the brain a plurality of electrodes 11 on the scalp, which can derive electrical potentials. The electrodes 11 are connected to a signal detection unit 13, which detects the signals received by the electrodes 11 in the form of an EEG.

In addition, an actuating unit 20, for example a push button, is connected to the signal detection unit 13. The person 16 can operate the operation unit 20 when he feels a asked hearing task to have solved. This can be objectively checked whether asked listening tasks are actually solved. A simple listening task would be to recognize a given spoken syllable or a tone with a certain pitch.

By means of a stimuli generator unit 12, which is connected to the hearing aids 10, the person 16 acoustic stimuli in the form of sound sequences, speech syllables or sentences presented. The person 16 must try to solve the task of hearing from the stimulus, that is, for example, to recognize the given syllable. The effort involved is referred to in German as Hörastrengung (actually "Zuhöranstrengung") and in English as "Listening Effort". Alternatively, the auditory stimulus can also be presented via loudspeaker 17 or headphones 18. In these cases, the hearing aids 10 pick up the sound and give it changed and amplified to the person 16 again.

The stimuli generator unit 12 may also deliver optional stimuli 19, for example in the form of visual and / or tactile stimuli.

With the aid of a hearing aid control unit 14, a wide variety of hearing aid parameters, such as, for example, channel amplification, compression rate, compression kink point, microphone characteristic, noise reduction or time constants, can be changed in order to allow adaptation of the hearing aids to the hearing or the hearing impairment of the person 16.

A computing and control unit 15, which is connected to the stimuli generator unit 12, the hearing aid control unit 14 and the signal detection unit 13, controls these units and determines the listening effort from the recorded signal progressions of the EEG. Preferably, ALR are determined from a test series and the mean IPS calculated from it. The middle IPS is a very robust and reliable measure of listening effort. The mean IPS is now used in a differential evolution algorithm of the computing and control unit 15 to determine the change in hearing aid parameters. After each change in the hearing aid parameters, further auditory stimuli are presented until the different or several differences of the detected hearing effort deviate from each other by only a second threshold value.

The middle IPS can take values between "0" and "1", the second threshold is preferably "0.2". Differential Evolution is a mathematical method for optimizing a multi-dimensional function.

LIST OF REFERENCE NUMBERS

1

Behind-the-ear hearing aid

2

hearing aid housing

3

microphone

4

Signal processing unit

5

receiver

6

battery

7

Microphone opening in the hearing aid housing 2

10

hearing Aid

11

EEG electrodes

12

Stimuli generator unit

13

Signal detection unit

14

Hearing Aids control unit

15

Computing and control unit

16

person

17

speaker

18

headphone

19

Optional stimuli

20

operating unit

100

preparation

101

Set the listening task

102

Presenting a hearing / speech syllable

103

Recording an EEG

104

Determination of the ALR

105

Determination of IPS / listening effort LE

106

Change at least one hearing aid parameter

107

Comparison of the values of two hearing effort measures

108

Cancel the adjustment of the hearing aid

ALR

Auditory late response

EEG

Electroencephalogram / graph

IPS

Inter-trial phase stability

LE

listening effort

Claims (18)

Method for the automatic, recursive adaptation of a hearing aid (10) worn by a person (16), wherein the person (16) is provided with a hearing task and an associated hearing effort (LE) is detected, with the following steps: a) presenting (102) at least one acoustic stimulus to the person (16), b) detecting (103, 104) the neural activity of the brain of the person (16) due to the acoustic stimulus, c) determining (105) a measure of the hearing effort (LE) from the detected neural activity, d) changing (106) at least one hearing device parameter as a function of the determined measure of the hearing effort (LE) and e) by a computing and control unit (15) controlled repetition of steps a) to d) until the amount of hearing effort (LE) falls below a predetermined first threshold or minimized in the sense of a predefined in the computing and control unit (15) defined termination condition is. Method according to claim 1,
characterized by : Repeating steps a) and b) and - mathematical analysis of the acquired neuronal activities for improved extraction of neuropsychological correlates of hearing effort (LE). Method according to claim 2,
characterized,
that the extraction is also defined on the image area of suitable mathematical transformations, in particular complex time / frequency transformations. Method according to one of the preceding claims, characterized
that the acoustic stimulus comprises a sequence of words, a speech syllable sequence or a tone sequence. Method according to one of the preceding claims,
characterized,
that the neuronal activity of the brain is detected by an (EEG). Method according to claim 5,
characterized,
that an auditory late response (ALR) is determined from the electroencephalogram (EEG). Method according to claim 6,
characterized,
that is determined from at least two Auditory Late Responses (ALR) has an average inter-trial Phase Stability (IPS). Method according to claim 7,
characterized,
that the Inter-Phase Stability Trial (IPS) is the measure for the listening effort (LE). Method according to one of claims 1 to 4,

characterized,
that the neuronal activity of the brain is detected by a magnetoencephalogram (MEG). Method according to one of the preceding claims,
characterized,
that the changes in the hearing aid parameters are determined by means of a differential evolution algorithm. Arrangement for the automatic, recursive adaptation of at least one hearing aid (10) carried by a person (16) with: a stimulus generator unit (12) which emits at least one acoustic stimulus to the hearing aid (10), - A signal detection unit (13) with at least one sensor (11) which detects a neuronal activity of the brain of the person (16) due to the acoustic stimulus, - A computing and control unit (15), which determines a measure of the hearing effort (LE) from the detected neural activity and determines changes in hearing aid parameters, and a hearing aid control unit (14) which changes the hearing aid parameters, wherein the computing and control unit (15) repeatedly causes the stimuli generator unit (12) to deliver a hearing stimulus and the hearing aid control unit (14) to change a hearing aid parameter until the amount of hearing effort (LE) falls below a predefinable first threshold value or in the sense of in the computing and control unit (15) predeterminable defined termination condition is minimized. Arrangement according to claim 11,
characterized,
that the acoustic stimulus comprises a sequence of words, a speech syllable sequence or a tone sequence. Arrangement according to claim 11 or 12,
characterized,
that the signal detection unit (13) and the at least one sensor (11) detects the neuronal activity of the brain using electroencephalography (EEG). Arrangement according to claim 13,
characterized,
that the signal detection unit (13) at least one Auditory Late Response (ALR) determined. Arrangement according to claim 14,
characterized,
in that the arithmetic and control unit (15) determines from at least two auditory late responses (ALR) an inter-trial phase stability (IPS) from its instantaneous phase. Arrangement according to claim 15,
characterized,
that the Inter-Phase Stability Trial (IPS) is the measure for the listening effort (LE). Arrangement according to claim 11 or 12,
characterized,
in that the signal detection unit (13) and the at least one sensor (11) detect the neuronal activity of the brain by means of magnetoencephalography (MEG). Arrangement according to one of claims 11 to 17,
characterized,
in that the arithmetic and control unit (15) the changes in the hearing aid parameters by a differential evolutionary algorithm are determined.

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