EP2114089A1 - Method and device for calculating the extent of wear on hearing aids - Google Patents

Abstract

The method involves performing in-situ measurement of a transmission function between a receiver (2) and an auditory canal microphone (1) of a hearing device i.e. in-the-ear hearing device (10). The measured transmission function is compared with previously determined reference values or reference curves. An effective vent diameter is determined based upon the comparison result, where the effective vent diameter specifies a degree of closure in the hearing device. The transmission function is measured with a switched-off active occlusion suppression of the hearing device. Independent claims are also included for the following: (1) a computer program product encoded with instructions for performing a method for determining a degree of closure in a hearing device (2) a hearing device for determining a degree of closure.

Description

The invention relates to a specified in claim 1 method for determining a degree of closure in a hearing aid and a specified in claim 9 hearing aid for determining a degree of closure.

In order to meet the aesthetic needs of a wearer of a hearing aid, they should be as little visible on the wearer from the outside as possible. The therefore required miniaturization of the hearing aids on the one hand and on the other hand as versatile a range of functions as possible, as well as high-quality processing of the signals required to improve the hearing within the hearing aid are opposing requirements.

In the case of hearing aids, a closure effect perceived as unpleasant by the wearer - the so-called occlusion - can occur, since often the space for a pressure equalization bore - the so-called vent - is not sufficiently large. Because of this closure effect, the hearing aid wearer's own voice sounds louder and louder. The occlusion effect occurs z. B. by an inserted into the ear in-the-ear hearing aid or by earmold of a behind-the-ear hearing aid.

Vents with a diameter of up to 1mm serve almost exclusively for pressure equalization when inserting an in-the-ear hearing device into the ear or a section of the hearing device to be inserted into the ear. In addition, these small vents pressure equalization with temporally short pressure fluctuations in the environment, as z. B. in an airplane, door closing, in the elevator or swallowing can occur. Vents with a larger diameter have a large influence on the low-frequency response, but also reduce the occlusion effect in the ear canal when the hearing aid in the ear or is placed on the auricle, and this at least partially clogged the external auditory canal.

All holes and channels in a hearing aid are acoustically considered "long tubes" and have a low pass character, i. they prefer to "escape" low frequencies. Larger diameter holes have larger cutoff frequencies and less damping. In this case, however, a necessary sound separation function between a listener of the hearing device or a radiating sound tube and an ambient microphone in the vicinity of the ear from a certain acoustic amplification can no longer be satisfied, resulting in an acoustic feedback, a "whistling" comes. This acoustic feedback also depends on the diameter of the vents.

To measure the degree of occlusion, for example, as in the patent DE 10 2006 042 083 A1 described an open-loop gain measurement are performed. In this, the open loop gain over the frequency between a listener and a microphone, which is located on the side facing away from the auditory canal, determined and compared with stored reference curves.

In order to counteract the occlusion, the acoustic feedback but also other acoustic problems in a hearing aid, methods and devices are known which record the acoustic conditions in the external auditory canal by means of an ear canal microphone and provide signal processing within the hearing aid device. The patent DE 10 2006 047 965 A1 indicates a relevant procedure. With the help of this active occlusion reduction, the feeling of occlusion in the hearing device wearer can be reduced despite a small vent diameter. In order to adapt the active occlusion reduction to the acoustics of the individual auditory canal of the hearing device wearer, an initialization measurement has to be carried out on the ear of the wearer. This measurement should provide information about how effective the occlusion reduction will be.

Due to the complexity and the abundance of the resulting measurement data, a proper interpretation by a hearing care professional is difficult or not possible because it understandably does not have the necessary knowledge for active occlusion reduction.

It is therefore an object of the invention to provide a method and a device with which an interpretation of the initialization measurement - especially for a hearing aid acoustician - is easily possible.

According to the invention, the stated object is achieved with the method of independent claim 1 and the hearing aid of independent claim 9.

According to the invention, this object is achieved by a method for determining a degree of closure in a hearing device having at least one auditory canal microphone and at least one earpiece. The method includes in situ measuring a transfer function between the earpiece and the ear canal microphone, comparing the measured transfer function with pre-determined reference values and / or curves, and determining an effective vent diameter from the comparison, wherein the effective vent diameter indicates the degree of closure , The previously determined reference values or reference curves can, for example, be determined theoretically or recorded empirically. The advantage of this is that instead of a very abstract result of an initialization measurement, a very clear and easily interpretable variable, namely the effective vent diameter, is available. This is also understandable for a hearing care professional.

In a further embodiment, the hearing aid may comprise an active occlusion suppression. A transfer function with active occlusion suppression turned off can be measured, the measured transfer function can be compared with a maximum effect of active occlusion suppression, and
From the comparison, a theoretical, maximum effective vent diameter can be determined. It can thereby be determined which maximum improvement by active occlusion suppression is theoretically possible.

In a further development, the hearing aid can comprise active occlusion suppression, a first transfer function with active occlusion suppression switched off and a second transfer function with activated active occlusion suppression measured, first and second effective vent diameters are determined, the first is compared with the second effective vent diameter, and From the comparison, a quality factor of the active occlusion suppression can be determined. This has the advantage that an active occlusion suppression is easily assessable.

Preferably, a quality measure of the active occlusion suppression can be determined from a comparison of the theoretical, maximum effective vent diameter with the second effective vent diameter. This determines to what extent active occlusion suppression can achieve its theoretical effects in practice.

In a further embodiment, the hearing device can be switched to a measurement mode for performing the in-situ measurement and determining an effective vent diameter. This eliminates external influences.

Furthermore, the effective vent diameter may be output for information and / or documentation via a hearing aid interface. Thus, the value is easily accessible to a hearing care professional, for example.

In a further embodiment, the method can be carried out exclusively with means of the hearing device.

The advantage of this is that no additional measuring devices are required.

The invention also provides a hearing device for determining a degree of closure with at least one auditory canal microphone and at least one earpiece, wherein the hearing device comprises a control and memory unit for carrying out the method according to the invention, wherein the earpiece and the auditory canal microphone are connected to the control and storage unit.

In a further development, audible measuring signals can be emitted by the listener.

In a further embodiment, the auditory canal microphone can record the acoustic measurement signals emitted by the listener and / or the acoustic measurement signals reflected in the auditory canal.

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 In-dem-Ohr Hörgeräts,

Figur 2:

ein Ablaufdiagramm eines Verfahrens zur Ermittlung eines effektiven Ventdurchmessers,

Figur 3:

ein Ablaufdiagramm eines Verfahrens zur Ermittlung eines Gütefaktors und

Figur 4:

eine Übertragungskurve.

Show it:

FIG. 1:

a block diagram of an in-the-ear hearing aid,

FIG. 2:

a flow chart of a method for determining an effective vent diameter,

FIG. 3:

a flowchart of a method for determining a figure of merit and

FIG. 4:

a transmission curve.

Hearing aids basically have as essential components an input transducer, an amplifier and an output transducer. The input transducer is usually a sound receiver, such as a microphone, and / or an electromagnetic receiver, such as an induction coil. The output transducer is usually as an electro-acoustic transducer, eg as a miniature speaker, or as an electromechanical transducer, eg as a bone conduction listener. The amplifier is usually integrated in a signal processing unit.

This basic structure is also found in FIG. 1 the example of an in-the-ear hearing aid 10 again. In a hearing aid housing 7 for carrying in the ear, a microphone 3 for receiving the sound from the environment, a control and storage unit 4 with a signal processing unit, not shown, a hearing aid 2 and an ear canal microphone 1 are installed. A battery 5 supplies the electrical components of the hearing aid 10. The output of the microphone 3 is connected to an input of the control and storage unit 4. The processed microphone signals are provided at an output of the control and storage unit 4 and supplied to the handset 2. The thus amplified sound signals enter the external auditory canal 9 via a hearing channel 12. Sound signals reflected in the ear canal 9 and by the eardrum are fed to the ear canal microphone 1 via a microphone channel 11. From an output of the auditory canal microphone 1, the converted sound signals reach an input of the control and storage unit 4. The sound signals received by the gyroscope microphone 1 are used in the control and storage unit 4 for controlling the active occlusion suppression. A vent 6, also referred to as a ventilation duct, ensures pressure equalization when inserting the in-the-ear hearing device 10 into the ear. The Vent 6 also reduces the occlusion feeling of a hearing aid wearer. The hearing aid 10 is sealed on the side facing away from the eardrum by a face plate 8.

To determine a degree of closure of the in-the-ear hearing device 10 when the hearing device is inserted, measurement signals or measurement signal sequences are emitted into the auditory canal 9 by the listener 2 in a measurement mode. These measurement sound signals are reflected in the ear canal 9 and the eardrum and then reach the ear canal microphone 1. From the control and memory unit 4, these signals received from the ear canal microphone 1 are evaluated by the auditory canal microphone 1 received measurement signals, a transfer function is determined and this is compared with stored reference transfer functions or reference values. From this comparison, the control and storage unit 4 calculates an effective vent diameter EV. The effective vent diameter EV is a theoretical measure of occlusion suppression. It indicates how large the diameter of a physical vein would have to be to produce the same occlusion suppression effect. The stored in the control and storage unit 4 reference data were either determined theoretically or come from empirical studies or measurements.

Effective Vent Diameters EV can be determined with or without active occlusion suppression turned on.

In FIG. 2 an inventive method for determining a degree of closure of a hearing aid with at least one auditory canal microphone and at least one listener is shown in a flow chart. In step 100, a hearing aid is placed in a measurement mode. Subsequently, the hearing aid is inserted into the auditory canal at step 101. In step 102, an in-situ measurement of a transfer function takes place between the earpiece and the auditory canal microphone. The measured transfer function is stored in a control and storage unit and compared in step 104 with previously determined reference values or reference curves 103. From the comparison, an effective vent diameter EV is determined in step 105. The effective vent diameter EV is a measure of the degree of closure. The measured transfer function shows a high-pass characteristic, which means that low frequencies are attenuated more than higher ones. In FIG. 4 an example of a measured transfer function with high-pass characteristic is shown.

A flowchart of a further method according to the invention is shown in FIG FIG. 3 shown. A hearing aid is set to a measurement mode in step 200 and to a measurement in step 201 Auditory canal of a hearing aid wearer used. A first in-situ measurement of a transfer function between the earpiece and the ear canal microphone takes place in step 202. Subsequently, with step 203, a first effective vent diameter EV1 is obtained from a comparison of the transfer function obtained with the first in-situ measurement with previously determined reference values or Reference curves determined. Subsequently, in step 204, the active occlusion suppression is switched on and there is a second in-situ measurement in step 205. In this case, a second transfer function between the earpiece and the auditory canal microphone is determined. In step 206, a second effective vent diameter EV2 is determined from the result of the second in-situ measurement. The determination also takes place via a comparison of the second measured transfer function with previously determined reference values or reference curves. In step 207, the first effective vent diameter EV1 and the second effective vent diameter EV2 are compared with each other. From the comparison, a quality factor GF is determined in step 208 with the aid of a calculation algorithm, which represents a measure of the effect of the active occlusion suppression.

LIST OF REFERENCE NUMBERS

1

Ear canal microphone

2

Handset / speaker

3

microphone

4

Control and memory unit with signal processor

5

battery

6

Vent / ventilation duct

7

hearing aid housing

8th

faceplate

9

external auditory canal

10

In-the-ear hearing aid

11

microphone channel

12

receiver channel

100

Switching on the measuring mode

101

Insertion of the hearing aid 10 in the ear canal 9

102

In-situ measurement

103

Reference transfer function curves / reference measurements

104

comparison

105

Determining an Effective Vent Diameter

200

Switching on the measuring mode

201

Insertion of the hearing aid 10 in the ear canal 9

202

first in-situ measurement

203

Determining a first effective vent diameter

204

Turn on active occlusion suppression

205

second in-situ measurement

206

Determining a second effective vent diameter

207

comparison

208

Determination of a quality factor

EV

effective vent diameter

EV1

first effective vent diameter

EV2

second effective vent diameter

GF

quality factor

Claims (11)

Method for determining a degree of closure in a hearing device having at least one auditory canal microphone (1) and at least one earpiece (2),
marked by an in situ measurement (102) of a transfer function between the earpiece (2) and the auditory canal microphone (1), a comparison (104) of the measured transfer function with previously determined reference values and / or curves (103), and a determination (105) of an effective vent diameter (EV) from the comparison, wherein the effective vent diameter (EV) indicates the degree of closure. Method according to claim 1,
characterized,
that the hearing aid comprises an active occlusion suppression,
that a transfer function is measured with the active occlusion suppression switched off,
that the measured transfer function is compared with a maximum effect of the active occlusion suppression, and
that a theoretical, maximum effective vent diameter is determined from the comparison. Method according to claim 1,
characterized,
that the hearing aid comprises an active occlusion suppression,
that a first transfer function can be measured with switched active occlusion and a second transfer function with activated active occlusion (202, 205),
that a first and second effective vent diameter (EV1, EV2) are determined (203, 206),
that the first to the second effective vent diameter (EV1, EV2) is compared (207), and
that from the comparison a quality factor (GF) of the active occlusion suppression is determined (208). Method according to claims 2 and 3,
characterized,
that a quality measure of the active occlusion suppression is determined from a comparison of the theoretical maximum effective vent diameter with the second effective vent diameter. Method according to one of the preceding claims,
characterized,
in that the hearing device is switched to a measurement mode for performing the in-situ measurement (102) and the determination (105) of an effective vent diameter (EV) (100). Method according to one of the preceding claims,
characterized,
that the effective vent diameter (EV) is output to the information and / or documentation of a hearing aid interface. Method according to one of the preceding claims,
characterized,
that the method is carried out exclusively with means of the hearing aid. A computer program product comprising a computer program comprising software means for performing a method according to any one of claims 1 to 7 when the computer program is executed in a control unit of a hearing aid. Hearing aid for determining a degree of closure with at least one auditory canal microphone (1) and at least one earpiece (2),
marked by
a control and storage unit (4) for performing the method according to one of claims 1 to 7, wherein the auditory canal microphone (1) and the receiver (2) with the control and storage unit (4) are electrically connected. Hearing aid according to claim 9,
characterized,
that acoustic signals can be emitted by the handset (2). Hearing aid according to one of claims 9 or 10,
characterized,
the acoustic measurement signals emitted by the earpiece (2) and / or acoustic measurement signals reflected in the auditory canal can be received by the ear canal microphone (1).

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