EP4360335A1 - Method for adapting a hearing device - Google Patents

Abstract

The invention relates to a method for adapting a hearing device (2), wherein at least one test measurement is carried out in which audio and/or video material is played and the hearing device user evaluates an acoustic signal perceived by the user as the test result.

Description

Description

Method for adapting a hearing device

The invention relates to a method for adapting a hearing device, in particular a hearing aid, as well as a hearing device and software on a data carrier.

Hearing aids are portable hearing devices (hearing aid devices) that are used to provide care for people who are hard of hearing or have hearing impairments. In order to meet the numerous individual needs, different designs of hearing devices such as behind-the-ear hearing aids (BTE) and hearing aids with an external receiver (RIC: receiver in the canal) as well as in-the-ear hearing aids (ITE) are used For example, concha hearing aids or canal hearing aids (ITE: In-The-Ear, CIC: Completely-In-Channel, HC: Invisible-In-The-Channel) are also provided. The hearing devices listed as examples are worn on the outer ear or in the ear canal of a hearing device user. In addition, bone conduction hearing aids, implantable or vibrotactile hearing aids are also available on the market. The damaged hearing is stimulated either mechanically or electrically.

In principle, such hearing devices or hearing aids have an input transducer, an amplifier and an output transducer as essential components. The input transducer is typically an acousto-electrical transducer, such as a microphone, and/or an electromagnetic receiver, for example an induction coil or a (radio frequency, RF) antenna. The output transducer is usually implemented as an electro-acoustic transducer, for example as a miniature loudspeaker (listener), or as an electromechanical transducer, such as a bone conduction receiver. The amplifier is usually integrated into a signal processing device. The energy is usually supplied by a battery or a rechargeable accumulator.

The input signals recorded by the input converters are typically multi-channel, which means that the input signals are divided into several individual frequency channels, with each frequency channel covering a frequency band of a certain spectral width. For example, a hearing aid can have 48 (frequency) channels in a frequency range between 0 kHz (kilohertz) and 24 kHz, with the individual signal components of the input signal in the channels being individually processable, in particular individually filterable and/or amplified, by means of the signal processing device.

By cleverly adjusting the time- and frequency-dependent amplification of an acoustic input signal by a hearing device, optimal adaptation to the needs of a hearing device user can be achieved. The problem arises of determining the best possible time- and frequency-dependent amplification for the hearing device user or hearing aid user Z wearer.

The (initial) fitting of a hearing aid is particularly aimed at finding the best amplification and algorithm settings for all individual hearing aid wearers. The most important input is the audiometric data of the hearing aid wearer (bone conduction threshold, level of discomfort). In addition, some fitting procedures also take into account other information about the hearing aid wearer, such as age, gender and experience with hearing aids, to further optimize the initial fitting. However, an approximately normal audiogram does not mean that the hearing aid wearer has normal hearing in real listening situations, especially when the hearing situations become more complex (e.g. speech in noise).

Current first fitting strategies typically use audiometric input data to achieve the required hearing aid fitting targets calculate. However, hearing ability in real life is usually not taken into account. In addition, it is usually necessary for a hearing care professional to carry out the initial fitting and additionally carry out one or more fine adjustments in order to make further individual optimizations, e.g. B. in relation to amplification/compression, but also to directivity and noise suppression. This is comparatively complex and requires both good technical and communication skills.

For cost reasons, people with mild to moderate hearing loss often use over-the-counter or over-the-counter hearing aids, so-called over-the-counter (OTC) hearing aids. The hearing aid wearer is responsible for setting up the hearing aid, including adjusting and adjusting the sound. The hearing aid wearer therefore usually has to carry out an initial fitting without audiometric input data and without professional assistance.

The invention is based on the object of specifying a particularly suitable method for adapting a hearing device. In particular, a method for self-adjustment of an OTC hearing aid that is as easy to carry out as possible should be specified. The invention is also based on the object of providing a particularly suitable hearing device and particularly suitable software on a data carrier.

With regard to the method, the task is solved according to the invention with the features of claim 1 and with regard to the hearing device with the features of claim 7 and with regard to the software with the features of claim 10. The advantages and refinements mentioned with regard to the method can also be transferred to the hearing device and/or the software and vice versa.

If method steps are described below, advantageous embodiments result for the hearing device and/or the software in particular in that it is designed to carry out one or more of these method steps.

The method according to the invention is intended for adapting a hearing device, in particular a portable hearing device, and is suitable and set up for this purpose. The hearing device is also referred to below as a hearing aid system or hearing system.

The hearing device is used in particular to provide care for a hearing-impaired user (hearing device user). The hearing device is designed to record sound signals from the environment and output them to the hearing device user. For this purpose, the hearing device has at least one input transducer, in particular an acousto-electrical transducer, such as a microphone.

When the hearing device is in operation, the input transducer picks up sound signals (noises, tones, speech, etc.) from the environment and converts them into an electrical input signal. The input signal is in particular designed to be multi-channel. In other words, the acoustic signals are converted into a multi-channel input signal. The input signal therefore has a plurality of frequency channels, in particular at least two, preferably at least 20, particularly preferably at least 40, for example 48 (frequency) channels, which each cover an assigned frequency band of a frequency range of the hearing device. For example, a frequency range between 0 kHz and 24 kHz is divided into 48 channels, so that input signals with 48 channels are generated.

The hearing device further has an output transducer, in particular an electro-acoustic transducer, such as a listener or miniature loudspeaker. An electrical (multi-channel) output signal is generated from the electrical (multi-channel) input signal by processing and modifying the input signal, or the individual frequency or signal channels, in a signal processing device (e.g. amplified, filtered, attenuated). become. The setting of the signal processing device, in particular with regard to the signal amplification, is carried out in the course of the adaptation according to the invention based on a test result of a test measurement.

According to the method, to adapt a hearing device, at least one test measurement is carried out in which media content, i.e. audio and/or video material, is played. The hearing device user assesses a sound signal he perceives from the output transducer as a test result. The hearing device is preferably adjusted or adjusted based on the test result. This results in a particularly suitable method for adapting the hearing device. In particular, the adjustment can therefore be carried out in a simple manner by the hearing device user himself.

The conjunction “and/or” is to be understood here and below in such a way that the features linked by this conjunction can be formed both together and as alternatives to one another.

The hearing device has, for example, a media playback unit for playing the media content. Media content is understood to mean information content that includes acoustic signals (speech dialogue, music, noises, tones, ...) and optionally also visually displayable signals (images, video, ...). The media playback unit is preferably coupled to a screen and an audio output, so that the optional optical signals can be displayed, for example, using the screen and the acoustic signals can be output to the input converter via the audio output.

An audio material is, for example, an audio clip, i.e. a clip or excerpt of an acoustic signal (speech dialogue, noises, tones, music, ...). Video material means, for example, a video, a video clip, or a film, i.e. moving visual images with an accompanying acoustic sound (acoustic accompanying signal). Here and below, acoustic information refers in particular to parameters or parameters of the acoustic signal that are relevant for the adaptation, such as volume, target noises, frequency design, signal-to-noise ratio (SNR), directivity or to understand the like. This acoustic information can be defined for all frequency channels or specifically, i.e. for a selection of frequency channels or individual frequency channels.

The audio and/or video material or the media content is known or deposited. In other words, the acoustic information of the media content in particular is pre-characterized or known. Through the reaction of the hearing device user to the known acoustic information, it is possible to draw conclusions about their hearing loss or hearing impairment, which enables simple and reliable adjustment.

The present invention relates in particular to a method for automatically adapting hearing aids to the individual needs of the user during or after listening to or viewing an audio/video clip or film. In an exemplary version, the method does not require any audiometric data from the hearing impaired person or any other information in advance. The main input to the method is the listener's (hearing device user's) response to the sound or acoustic signal/information of the audio/video clip being played.

In an advantageous embodiment, the acoustic information of the media content is changed during the test measurement. This causes sections of the media content to play differently. Alternatively, it is also possible, for example, to carry out several successive or consecutive test measurements with different or changed acoustic information.

In one conceivable embodiment, the hearing device user is asked, for example, to react whenever it is difficult for him to hear a sound or follow the film. By playing excerpts with different scene characteristics or different acoustic information (different target sounds, different volume, different frequency design, different SNR, ...) and the analysis of the listener's reactions depending on these characteristics (test result), the method can determine the degree of hearing loss, hearing profiles and preferences as well as the required Determine hearing aid fitting or fitting profiles.

This brings various advantages. Firstly, the listener can carry out this fitting method themselves, even without a hearing aid professional, which is particularly advantageous for OTC hearing aids. Secondly, the hearing profile is determined using real signals that are more relevant to real hearing than audiometric test tones. Third, the method can do much more than just determine hearing thresholds, so there is much more input to individualize the adjustment, for example in terms of noise reduction or directionality. Finally, it is more fun to watch a movie than to perform an audiometric test, which means that the hearing aid user's attention is higher during the test measurement, allowing for a more reliable adjustment.

In a suitable further development, the acoustic information or settings of the media content, i.e. the audio and/or video material played, are changed based on the test results. This feedback makes it possible to determine or record several settings or parameters for adjustment while playing the audio and/or video material.

This means that the adaptation process can be carried out in a particularly time-efficient manner.

In a suitable form of further training, the hearing aid user's answers (test results), for example, influence/change the sound of the video clip in such a way that the method at the end of the video clip approximates the best hearing aid configuration (adjustment and functional settings) for the individual listener.

An additional or further aspect of the invention provides that the acoustic information of the media content is provided by the hearing device user can be changed continuously, with a continuous test result being recorded. In an advantageous embodiment, the acoustic information has a foreground signal and a background signal, with only the foreground signal being changed when the acoustic information is changed.

The acoustic information thus has an adjustable or adjustable signal component (e.g. volume of a speech dialog) and an unchangeable signal component (e.g. background noise). The different signal components can be output via different loudspeakers, for example. The hearing device user can thus, for example, use a special volume control for the main/target speaker (while the background scene remains untouched), e.g. B. increase the volume if he has trouble understanding and decrease the volume if it is too loud. By analyzing the continuous responses (test results) for different scene features, the method can derive an individual target SNR.

In one possible embodiment, the method can use continuously measured sensor data or combinations thereof (measured by the hearing aid or by an external adjustment device) to estimate hearing difficulties or listening effort.

In a conceivable embodiment, the hearing device user is offered a number of selection options, i.e. several or at least two selection options, in order to change the acoustic information of the media content, between which the hearing device user can switch. The selection options differ in terms of the change caused to the acoustic information, with the selection options or the resulting changes in the acoustic information being set or changed based on the test result.

In a possible embodiment, a preference of the hearing device user is determined by his selection of continuously offered hearing options, e.g. two hearing options A, B via the user control on a hearing aid or on an external adjustment device of the hearing device. The A/B listening options may differ in terms of overall gain, level-dependent gain/compression, frequency shaping, maximum output power, directionality, noise cancellation settings, feedback cancellation settings or other functions/system settings, with the (selection) options being different during can further develop the term of the media content according to the options already selected.

The hearing device according to the invention has at least one input converter for receiving an acoustic signal and converting it into an input signal, a signal processing device for signal processing of the input signal and generating an output signal, an output converter for converting the output signal into a sound signal, a media playback unit for playing media content with acoustic information, and a controller.

The controller is generally set up - in terms of program and/or circuitry - to carry out the method according to the invention described above. The controller is thus specifically set up to play media content via the media playback unit in the course of a test measurement, to record a test result from the hearing device user, and to set the signal processing of the signal processing device depending on the test result.

In a preferred embodiment, the controller is at least essentially formed by a microcontroller with a processor and a data memory, in which the functionality for carrying out the method according to the invention is implemented programmatically in the form of operating software (firmware), so that the method - if necessary in interaction with a device user - is carried out automatically when the operating software is executed in the microcontroller. Within the scope of the invention, the controller can alternatively also be a non-programmable electronic component, such as an application-specific integrated circuit (ASIC) or by an FPGA (Field Programmable Gate Array), in which the functionality for carrying out the method according to the invention is implemented using circuit technology means.

The hearing device according to the invention has, for example, a hearing aid, in particular an OTC hearing aid. Preferably, the hearing device comprises a hearing system with an (OTC) hearing aid and an adjustment device coupled to it in terms of signal technology for changing the acoustic information of the media content.

The setting device is preferably a separate mobile operating and display device, for example a mobile phone, in particular a mobile phone with a computer function or a smartphone or even a tablet computer. The setting device preferably has the media playback unit for playing back the media content.

The setting device has, for example, stored application software (operating software) by means of which the audio and/or video material is played and by means of which the test results of the hearing device user are recorded. Based on the test results, the application software then adjusts the settings or amplification of the hearing aid. For this purpose, the application software can preferably be installed as a so-called app or mobile app (mobile application, smartphone app) on the operating and display device.

This further training is based on the idea that modern operating and display devices, such as smartphones or tablet computers, are widespread in today's society and are generally available and accessible to a user at any time. In particular, the user of the hearing aid device is very likely to essentially have such an operating and display device in his household. The surfaces of smartphones or tablet computers, which are typically designed as touchscreens (display, display), continue to allow particularly simple and intuitive operation of the application software of the operating and display device formed thereby. This means that a smartphone or tablet computer can be retrofitted particularly cost-effectively for monitoring the hearing aid device.

The operating and display device comprises an internal controller, which is formed at least in the core by a microcontroller with a processor and a data memory, in which the functionality for carrying out the method is implemented programmatically in the form of the application software, so that the method or the determination of the Operating state of the hearing aids - if necessary in interaction with the user - is carried out automatically when the application software is executed in the microcontroller.

An additional or further aspect of the invention provides software on a medium or data carrier for carrying out or executing the method described above. This means that the software is stored on a data carrier and is intended to carry out the method described above and is suitable and designed for this purpose. This results in particularly suitable software for adapting a hearing device, with which the functionality for carrying out the method according to the invention is implemented using program technology. The software is therefore in particular operating software (firmware), with the data carrier being, for example, a data memory of the controller.

An exemplary embodiment of the invention is explained in more detail below with reference to a drawing. The only figure shows the basic structure of a hearing device 2 in a simplified and schematic representation.

The hearing device 2 is designed in particular as a hearing aid device in the form of a hearing system with a hearing aid 4 and with an external adjustment device 6. The hearing aid 4 is an example of a behind-the-ear hearing aid (BTE). The hearing aid 4 is in particular an OTC hearing aid. The hearing aid 4 and the adjustment device 6 are coupled to one another in terms of signals by means of a wireless communication connection 10. The communication connection 10 is preferably designed as a radio connection, for example as a Bluetooth or RFID connection.

The hearing aid 4 comprises, as shown schematically in the figure, a device housing 10 in which one or more microphones 12, also referred to as acousto-electric transducers (input transducers), are installed. The microphones 12 record the sound or acoustic signals in the environment and convert them into an electrical audio signal.

The audio signal is processed by a signal processing device 14, which is also arranged in the device housing 10. Based on the audio signal, the signal processing device 14 generates an output signal which is directed to a loudspeaker or listener 16. The listener 16 is designed as an electro-acoustic transducer (output transducer), which converts the electrical output signal into an acoustic signal and outputs it. In the case of the BTE hearing aid 4, the acoustic signal is optionally transmitted to the eardrum of a hearing aid device user via a sound tube (not shown) or an external listener, which has an otoplastic fitted in the ear canal. But it is also conceivable, for example, an electro-mechanical transducer as a listener 16, such as a bone conduction listener.

The hearing aid 4 and in particular the signal processing device 14 are supplied with energy by means of a battery 18 accommodated in the device housing 10.

The signal processing device 14 is also routed to a transceiver 20 of the hearing aid 4 for signaling purposes. The transceiver 20 is used to send and receive wireless signals via the communication link 8. The transceiver 20 can be designed, for example, as an induction coil.

In the exemplary embodiment of the figure, a separate, mobile operating and display device as a setting device 6 is coupled to the hearing aid 4 for signaling purposes by means of the communication connection 8. The setting device 6 shown schematically is in particular a smartphone. The smartphone 6 has a touch-sensitive display unit (display) 22, which is also referred to below as a touchscreen. The smartphone 6 also has at least one loudspeaker 24 for emitting acoustic signals.

The signaling coupling between the smartphone 6 and the transceiver 20 of the hearing aid 4 takes place via a corresponding - unspecified - integrated transceiver, for example a radio or radio antenna, of the smartphone 6.

The smartphone 6 has an integrated controller, which is essentially formed by a microcontroller with implemented application software 26. The application software 26 is preferably a mobile app or a smartphone app that is stored in a data memory of the controller. During operation, the controller displays the application software 26 on the touchscreen 22, wherein the application software 26 can be operated by a hearing device user using the touch-sensitive surface of the touchscreen 22.

A method according to the invention for adapting the hearing aid device 2 to the hearing needs of the hearing device user is explained below.

When executing the application software 26, media content 28, in particular audio and/or video material, is played using an unspecified media playback unit of the smartphone 6. Here, a corresponding sound signal is generated by the loudspeaker 24. The hearing device user judges the sound signal he perceives as Test result. As a test result, the hearing device user presses, for example, a button 30 on the touch display 22 to increase the volume of the media content 28 or a button 32 to reduce the volume of the media content 28.

Preferably, the hearing device 2 or the hearing aid 4 is adjusted or adjusted based on the test result. For this purpose, the application software 26, for example, evaluates the test results and generates an adaptation signal, which is transmitted to the signal processing device 14 via the communication connection 8. The signal processing device 14 is subsequently adapted or adjusted based on the adaptation signal.

The method thus enables automatic adaptation of the hearing aid 4 to the individual needs of the hearing aid user during or after listening to or viewing the media content 28.

Following the procedure, it is possible, for example, to use the application software 26 for simple audio-visual exercises. For example, media content can be played that shows the head of a speaker who pronounces target phonemes clearly and distinctly, for example to practice lip reading. This allows the user, for example, to better get used to the new hearing aid settings after the procedure.

The claimed invention is not limited to the exemplary embodiments described above. Rather, other variants of the invention can also be derived by the person skilled in the art within the scope of the disclosed claims without departing from the subject matter of the claimed invention. In particular, all of the individual features described in connection with the various exemplary embodiments can also be combined in other ways within the scope of the disclosed claims without departing from the subject matter of the claimed invention. Reference symbol list

2 hearing aid

4 hearing aid

6 setting device/smartphone

8 communication link

10 device housings

12 microphone, input converter

14 signal processing device

16 listeners, output converter

18 battery

20 transceivers

22 display/touch screen

24 speakers

26 application software

28 Media Content

30 button

32 button

Claims

Claims method for adapting a hearing device (2),

- wherein the hearing device (2) has at least one input converter (12) for receiving an acoustic signal and converting it into an input signal, a signal processing device (14) for signal processing the input signal and generating an output signal, and an output converter (16) for converting the output signal into an has a sound signal,

- wherein at least one test measurement is carried out, in which media content (28) with acoustic information is played, and in which the hearing device user assesses a sound signal from the output transducer perceived by him as the test result, and

- wherein the signal processing of the signal processing device (14) is set or adjusted depending on the test result. Method according to claim 1, characterized in that the acoustic information of the media content (28) is changed during the test measurement. Method according to claim 1 or 2, characterized in that the acoustic information of the media content (28) is changed based on the test results. Method according to one of claims 1 to 3, characterized in that the acoustic information can be changed continuously by the hearing device user, with a continuous test result being recorded. Method according to one of claims 2 to 4, characterized in that the acoustic information has a foreground signal and a background signal, with only the foreground signal being changed in the course of a change in the acoustic information. Method according to one of claims 2 to 5, characterized in that the hearing device user is offered a number of selection options for changing the acoustic information, between which the hearing device user can switch, the selection options differing in terms of the change caused to the acoustic information, and wherein the Selection options or the resulting changes in the acoustic information can be set or changed based on the test result. Hearing device (2) having at least one input transducer (12) for receiving an acoustic signal and converting it into an input signal, a signal processing device (14) for signal processing the input signal and generating an output signal, an output converter (16) for converting the output signal into a sound signal, a Media playback unit for playing media content (28) with acoustic information, and

- a controller for carrying out a method according to one of claims 1 to 6. Hearing device (2) according to claim 7, wherein the hearing device (2) has a setting device (6) for changing the acoustic information of the media content (28). Hearing device (2) according to claim 8, characterized in that the setting device (6) is designed as a mobile operating and display device. Software on a data carrier for carrying out a method according to one of claims 1 to 6, if the software runs on a computer.