EP1883273A1 - Control device and method for wireless transmission of audio signals when programming a hearing aid - Google Patents

Abstract

The method involves transmitting control data of a control device (20) to a hearing aid (10) in order to adjust transfer characteristics of the hearing aid. Audio data of the control device is transmitted to the hearing aid in order to test actual transfer characteristics of the hearing aid. The audio data and the control data are transmitted together as data packets to the hearing aid over same channel by a digital radio link (30) of the control device, where the data packets comprise a user data block and a packet head that is prefixed to the block. Independent claims are also included for the following: (1) a control device for controlling a hearing aid (2) a hearing aid comprising a signal processing device.

Description

The invention relates to a method for controlling a hearing device, wherein as part of a programming control data and audio data are transmitted from a control unit together via a wireless connection to the hearing aid. The data transmission is preferably carried out as data packets using an inductive short-range radio method.

In the early days of hearing aid technology, hearing aids served merely as simple sound amplifiers. Since hearing impairment typically does not affect all frequencies equally, so that some frequencies can be perceived better than others, the frequency-dependent amplification is necessary for optimal compensation of the hearing impairment. Only through the use of filter circuits could the transmission characteristics of the hearing aids, ie the manner in which an audio signal is changed by the components of the hearing aid, be adapted to the extent that a realistic hearing impression became possible. The filter circuits initially implemented using analog technology became more and more sophisticated as the design progressed, with the increasing complexity of these circuits also providing a variety of adjustment and control options. In hearing aids of a newer design, the signal processing of the audio signals received by the hearing aid microphone can therefore be adapted so that it corresponds to the individual needs of the respective hearing aid wearer. The optimal adjustment of the hearing aid parameters is the goal of the hearing aid fitting, which is usually performed by a hearing care professional.

An important advantage of analog technology is that the signals are processed in real time. However, settings can be made limited to analog signal processing circuits due to the small size of the hearing aids. The typical noise for analog signal processing is also a significant problem. The disadvantages of analog technology could only be avoided by introducing digital signal processing circuits in hearing aid technology. Programmable hearing aids, in principle, open up new degrees of freedom in determining the functionality of a hearing device. The type of signal processing is completely freely definable and executable in the form of programs in the hearing aid. Only the development of digitally programmable hearing aids therefore made it possible to provide a number of alternative hearing programs, which are provided, for example, for the optimal perception of speech in front of different soundscapes.

The hearing aids on the market have essentially the same basic components. In addition to a microphone, a signal processing device and an electroacoustic transducer, usually a loudspeaker, modern hearing aids also have a programmable control device which controls the signal processing device in order to set the transmission characteristic of the hearing device individually. The control device is preferably programmed by means of audiometrically obtained data.

Since the hearing aid itself usually has no complex actuators due to the small size of its housing, it must be programmed in a programming session using an external controller. During programming, real everyday situations are simulated. For this purpose, various audio examples can be recorded in the hearing aid via the control unit, which are qualitatively assessed by the hearing aid wearer after signal processing in the hearing aid. This feedback allows the hearing care professional to manually adjust individual parameters during fine tuning. Typically, the control unit or an external matching computer connected to the control unit has corresponding input devices for this purpose on. The adaptation of the hearing aid is preferably carried out in several stages. Thus, first of all, pre-programming and, subsequently, the manual fine-tuning of the hearing device can be carried out on the basis of parameters determined by means of audiometry.

During the fine-tuning, it is necessary to transmit audio signals with the best possible quality to the hearing aid. Therefore, the hearing aid for programming is conventionally connected to the programmer via a special audio cable. Since sometimes very complex tone sequences and noises have to be generated or analyzed, the programming of the hearing device requires comparatively much computing power. It is therefore advantageous to use an external matching computer for programming, which is connected to the control unit. As a rule, such an adaptation computer has an operator keyboard via which the hearing device acoustician can make the appropriate settings. The control unit does not need its own computing power in this case. Rather, it can then be designed as a simple remote control, which only forwards the data of the matching computer to the hearing aid. However, such a remote control may also include controls for certain settings of the hearing aid, such as e.g. the absolute volume, included. Furthermore, the remote control can also have its own tone generator that generates audio signals from data calculated by the matching computer and transmitted to the control unit. These audio signals then only need to be transmitted to the hearing aid. Such simple control devices generally have a correspondingly small size, so that they can also be worn directly on the body. In order to achieve a better freedom of movement of the hearing aid wearer during a programming session, the control unit can be connected wirelessly to the adaptation computer instead of via cable.

In programming systems of a newer design, the control data for the programming of the hearing device can already be transmitted by means of wireless data transmission from the control device to the hearing device become. For this purpose, an already integrated in the hearing aid wireless interface is used. However, the audio transmission continues to be done by means of a special cable connection. With this type of transmission, a cable must be attached directly to the hearing aid. By the cable, however, the freedom of movement of the hearing aid wearer is restricted. Furthermore, a cable tugging on the hearing device can change the seat of the hearing device and thus also the hearing impression, which can have a negative effect on the hearing device adaptation.

Finally, analog modulated radio systems are known with which audio signals from external sources can be wirelessly coupled into the hearing aid. These devices designed as external radio modules are plugged onto an audio shoe of the hearing aid. They use FM frequencies and have their own power supply. However, a special radio module is required for each hearing aid, as hearing aids vary from manufacturer to manufacturer. Furthermore, plugged-in radio modules on the hearing aid also change the fit of the hearing aid, which can also have a negative effect on the hearing aid fitting.

The object of the invention is therefore to provide a method for wireless programming of a hearing aid, in which the hearing aid can be completely wirelessly connected to a control unit. This connection should work without additional devices. It is another object of the invention to provide a control device and a hearing aid for carrying out the method. This object is achieved by a method according to claim 1, a control device according to claim 7 and a hearing aid according to claim 14. Further advantageous embodiments of the invention are specified in the dependent claims.

According to the invention, a method for controlling a hearing device is provided, in which control data is transmitted wirelessly from a control device to the hearing device in order to determine the transmission characteristic between the hearing device microphone and the output transducer of the hearing aid. Furthermore, audio data is transmitted from the control unit to the hearing aid in order to test the current transmission characteristic of the hearing aid. The converted in data packets audio and control data are transmitted together via a digital radio link from the controller to the hearing aid. The common transmission of data over the same radio channel allows a completely wireless connection of the hearing aid to the control unit without additional devices. As a result, the full freedom of movement of the hearing aid wearer can be ensured during programming. At the same time, it can also reduce the risk of the hearing aid slipping during programming. Furthermore, eliminates the need for special Aufsteckmodule for the hearing aid. It is also possible to remove the programming jack. This results in a smaller design of the hearing aids. Furthermore, the analog audio transmission is possible in principle without an audio shoe, directly into the hearing aid.

In an advantageous embodiment of the invention, audio and control data are transmitted in different data packets to the hearing aid. This makes it possible to selectively transfer control data only if the current transmission capacity allows this. As long as the full bandwidth of the radio link is needed for audio data transmission, control data may also be held back until sufficient transmission capacity is available.

A particularly advantageous embodiment of the invention provides that the audio data and the control data are transmitted in common data packets to the hearing aid, wherein each data packet has a payload data block and a payload header preceded by the payload data block. While the audio data are respectively transmitted in the payload data block of a data packet, the transmission of the control data takes place respectively in the packet header of the data packet. Since in practice only a relatively small volume of control data has to be transmitted compared to the amount of audio data accumulated, this type of transmission has the advantage that almost the entire bandwidth of the radio link is available for audio data transmission.

Furthermore, a further embodiment of the invention provides that the transmission of the data takes place by means of an inductive short-range radio link. At short distances, this wireless connection may also provide high quality audio at a higher data rate compared to normal operation. Particularly advantageous is the relatively low energy consumption of this radio link. A suitable, lossy, digital compression method can help to keep the data rate at convincing quality.

As a further advantageous embodiment of the invention provides, the digital radio link used to transmit the data uses frequencies in the RF range. This can ensure a sufficiently high audio quality.

A further advantageous embodiment of the invention provides an external control device for controlling a hearing device, which has a transmitting device in order to transmit control data and audio data to a receiving device of the hearing device. The transmitting device is designed to transmit the control data and the audio data together via a digital radio link to the receiving device of the hearing device. The common transmission of data allows the complete abandonment of a cable connection to the hearing aid. As a result, the freedom of movement of the hearing aid wearer can be increased.

Furthermore, an embodiment of the invention provides a control unit in which an interface is provided in order to connect the control unit wirelessly or by means of a cable to a data processing system. Through the use of an external matching computer even more complex audio signals can be generated and processed by the control unit its typically low processing power can not handle.

A further embodiment of the invention provides that the control unit has an internal power supply device in the form of a battery or a rechargeable battery. As a result, the controller can be operated completely wireless.

Furthermore, an embodiment of the invention provides that the control unit has a tone generator. This can be generated in the control unit desired audio signals and then sent as audio data to the hearing aid. The advantage here is that between the adaptation computer and the control unit no large amounts of audio data must be transmitted, but only necessary for tone generation of the tone generator commands.

Finally, in an advantageous embodiment of the invention, it is provided that the receiving device is designed as an inductive receiver which receives the audio data and the control data via a magnetic radio link. For hearing aids that already have an inductive receiver for the reception of control data, the invention can be implemented based on the existing system without additional hardware.

Fig. 1

ein erfindungsgemäßes Programmiersystem für Hörgeräte mit einem Steuergerät, einer Datenverarbeitungsanlage und einem mit dem Steuergerät drahtlos verbundenen programmierbarem Hörgerät;

Fig. 2

ein Steuergerät und ein programmierbares Hörgerät gemäß der Erfindung jeweils mit Einrichtungen zur drahtlosen Übertragung von Steuer- und Audiodaten.

In Figur 1 ist rein schematisch, ohne irgendwelche maßstäblichen Verhältnisse ein Steuersystem für Hörgeräte gezeigt, das zum drahtlosen Programmieren eines Hörgeräts verwendet werden kann. Dieses System umfasst ein programmierbares Hörgerät 10, ein Steuergerät 20 sowie einen externen Anpassrechner 40. Der als eine Datenverarbeitungsanlage ausgebildete Anpassrechner 40 wird dann benötigt, wenn die Programmierung eines digitalen Hörgeräts sehr viel Rechenleistung erfordert und das Steuergerät 20 diese Rechenleistung nicht zur Verfügung stellen kann. In diesem Fall kann das Steuergerät 20 auch lediglich als eine Fernbedienung ausgebildet sein, die die Daten des Anpassrechners 40 an das Hörgerät drahtlos weiterleitet. Dabei können Audiodaten bereits im Anpassrechner digitalisiert und fertig kodiert vorliegen. Die Fernbedienung 10 überträgt sie dann vorzugsweise ohne eine eigene Verarbeitung an das Hörgerät 10. Lediglich die Kanalkodierung für die Datenpakete muss dann bereitgestellt werden. Erst im Hörgerät 10 werden die Audiodaten dann wieder decodiert und als Audiosignale über den Hörgerätelautsprecher 132 ausgegeben. Ferner können Audiosignale einer externen Audioquelle 41 über eine entsprechende Schnittstelle in den Anpassrechner 40 oder in das Steuergerät 20 eingekoppelt werden.The invention will be explained in more detail below with reference to an embodiment in conjunction with the accompanying drawings. In the drawing show:

Fig. 1

an inventive programming system for hearing aids with a control unit, a data processing system and a programmable hearing aid wirelessly connected to the control unit;

Fig. 2

a control device and a programmable hearing aid according to the invention each having means for wireless transmission of control and audio data.

FIG. 1 shows purely schematically, without any scale relationships, a control system for hearing aids that can be used for wireless programming of a hearing device. This system comprises a programmable hearing aid 10, a control unit 20 and an external adaptation computer 40. The adaptation computer 40 designed as a data processing system is required if the programming of a digital hearing aid requires a great deal of computing power and the control unit 20 can not provide this computing power. In this case, the control unit 20 may also be designed only as a remote control, which forwards the data of the matching computer 40 to the hearing aid wirelessly. In this case, audio data can already be digitized in the matching computer and ready encoded. The remote control 10 then transmits it preferably without its own processing to the hearing aid 10. Only the channel coding for the data packets must then be provided. Only in the hearing device 10 are the audio data then decoded again and output as audio signals via the hearing aid loudspeaker 132. Furthermore, audio signals of an external audio source 41 can be coupled into the adaptation computer 40 or into the control unit 20 via a corresponding interface.

Also, the control device 20, which is merely remote-controlled, may include means for controlling certain settings, such as e.g. to control the volume of the hearing aid. Depending on the application, it is also possible to provide a control unit 20 which has sufficient computing power so that audio signals can be processed or recoded in the control unit 20.

The adaptation computer 40 used in the present example for supplying audio data preferably has a device for inputting commands or data and a display device for displaying information. The adaptation computer 40 serves to provide the parameters necessary for programming the hearing device 10.

For this purpose, the adaptation computer 40 is connected to the control unit 20 via a special connection 50. Depending on the application, connection 50 may be a wireless or a wired bidirectional connection. This is indicated in the figure 1 by a dashed or a continuous drawn arrow.

In accordance with the invention, the controller 20 is further connected to the hearing aid 10 via a separate wireless connection 30. As shown in FIG. 2, both the hearing device 10 and the control device 20 have corresponding transceivers 21, 11 and corresponding antennas 111, 211 for this purpose. Furthermore, the hearing device 10 may have only one receiving device 11 and the control device 20 only one transmitting device 21, provided that only one unidirectional data transmission is provided. Preferably, the wireless link 30 is configured as a short-range digital radio link. Due to the relatively short distance that is to be overcome in this case, in particular an inductive or magnetic radio link is suitable here. Here, the signal transmission takes place only by means of the magnetic field. Compared to an electromagnetic radio connection, this radio method is significantly more energy efficient for the receiver. This is particularly advantageous if only one internal battery is available to the hearing aid 10 during programming as the energy source. Since, in addition to the control data according to the invention, audio data should also be transmitted wirelessly, the radio link 30 must have a sufficiently high bandwidth. In order to transmit audio signals in sufficiently good quality, a data rate of at least 50 to 100 kbit / s is usually necessary. For purely inductive data transmission carrier frequencies in the range of several megahertz should therefore be used. Preferably, the carrier frequency for the inductive data transmission in the RF range, in particular in the range of 3 to 5 MHz.

The control unit 20 can also bridge the relatively long distance to the adaptation computer 40 by means of a suitable wireless connection 50. As shown in FIG. 2, the control unit 20 has an additional transmitting / receiving device 23 for this purpose. If the data is sent wirelessly from the adaptation computer 40 to the control unit 20, they arrive coded in the control unit 20 for the corresponding radio standard. If the short-distance radio procedure to the hearing aid 10 requires a different coding, the data must be recoded to the corresponding radio standard of the short-distance radio link 30. This is preferably done in a control unit 22 of the controller 20.

For programming the hearing device 10, in the present example, control data is sent from the adaptation computer 40 via the data connection 50 to the control unit 20. This control data usually contain special control commands or parameters for the controller 12 of the hearing aid 10. If necessary, the controller 20 must implement the control data before it forwards it via the digital radio link 30 to the hearing aid 10. Control data may also be input manually via an input device 42, such as a keyboard of the matching computer 40.

In optimizing the transmission characteristic of the hearing device 10, the hearing aid wearer is presented with various audio examples. For this, e.g. in the matching computer 40 already stored or recorded in the matching computer 40 from an external audio source 41 audio data via the radio link 50 are sent to the control unit 20. The audio data, if necessary, must be converted in the control unit 20 before they are transmitted to the hearing aid 10 via the digital radio link 30.

Furthermore, it is also possible to generate audio signals only in the control unit 20. For this purpose, the control unit 20 preferably has a tone generator. In this case, the matching computer 40 provides the data connection 50 for tone generation necessary control commands for the tone generator of the controller 20. The audio signals must then be coded in the control unit 20 and prepared for wireless transmission to the hearing aid 10.

For block-wise data transmission, the audio and control data are typically packaged in data packets. The length of these data packets can be variable. As a rule, however, they must not exceed a fixed upper limit. If a relatively high number of errors is to be expected in the case of a faulty transmission, this upper limit is chosen to be relatively small in order not to have to repeat unnecessarily large amounts of data.

When translated into data packets, the data is packaged in frames, i. with a header at the beginning of the frame and usually also with a trailer at the end of the frame. In addition to address information (address bits), the header block generally also contains further bits, in particular marker bits (Flag) and so-called control bits. The flag allows the receiver to detect the position of the frame in the bitstream. By contrast, the control bits are used for transmission control. In addition, the header block may contain additional bits. In comparison to the payload data block which contains the actual data, the packet header of a typical data packet generally has significantly fewer bits. In the Bluetooth transmission method, these are e.g. 54 bits. On the other hand, an associated user data block of the Bluetooth transmission method typically has up to 2745 bits.

Despite the relatively small number of bits, a few bytes of information can be transferred in the header block of a frame. This information should preferably contain programming data for the respective hearing device 10. The programming data can be protected by means of appropriate coding against faulty transmissions. Furthermore, it can be ensured by multiple transmission, for example, that none Data is lost. In the payload data block, that is to say the actual data areas outside the headers, audio data is preferably transmitted. Since the header data is transmitted in addition to the audio data in the same period of time, the transmission rate must be slightly higher than the actual audio data rate.

In the common transmission of programming data in the header block and audio data in Nutzdatenblock arise in the audio reception branch transmission gaps. These can be compensated again in the audio reception branch by means of buffer memory, so that therefrom results in no or only a relatively small signal delay. Upon receipt of the data blocks in the hearing aid 10, the headers are separated from the audio data and further processed independently.

Since a simultaneous transmission of audio data and programming data in a single radio channel can be realized with the described method, it is possible to program a hearing device 10 with appropriate coding of the data and use of header information in parallel with the audio transmission. Only the programming data rate is reduced by the simultaneous audio transmission. Since it is not possible to read out the data in half-duplex systems in the event of a transmission without interrupting the transmission process and thus the audio transmission, the programming data can be sufficiently reliably protected by means of suitable error correction methods.

In principle, a return channel can also be realized in this way. This can be done for example by means of a time division multiplex method. For this purpose, small data packets are preferably sent back to the control unit 20 between the individual frames. The transmission of the small data packets takes place on the same radio channel and on the same carrier wave as the transmission of the audio and programming data. However, due to the use of the time-division multiplex method, the user data rate decreases even further. To be in such a In case of ensuring interference-free and uninterrupted audio transmission, a sufficiently large reserve is necessary. The data transmission method used must therefore have a sufficiently high data rate.

Claims (17)

A method for controlling a hearing aid (10), wherein control data from a control device (20) to the hearing aid (10) are transmitted to set a transmission characteristic of the hearing aid (10), and
wherein audio data is transmitted from the control unit (20) to the hearing aid (10) in order to test the current transmission characteristic of the hearing aid (10),
characterized,
that the audio data and the control data are transmitted as data packets together through a digital radio link (30) by the control unit (20) to the hearing aid (10). Method according to claim 1,
characterized,
that the audio data and the control data are transmitted in different data packets to the hearing aid (10). Method according to claim 1,
characterized,
that the audio data and the control data are transmitted in shared data packets to the hearing aid (10),
wherein the data packets each comprise a payload data block and a payload header preceding the payload data block, and
wherein in the payload data block of a data packet audio data and in the packet header of the data packet control data are transmitted. Method according to one of the preceding claims,
characterized,
in that a short-range inductive radio link is used to transmit the data. Method according to one of the preceding claims,
characterized,
that the digital radio connection used to transmit the data uses frequencies in the RF range. Method according to one of the preceding claims,
characterized,
in that the data are transmitted in the context of a hearing device programming, wherein the control data serve for programming a control device (12) of the hearing device (10) which controls the transmission characteristic of the hearing device (10). Control device (20) for controlling a hearing aid (10),
with a transmitting device (21) in order to transmit control data to a receiving device (11) of the hearing device (10),
wherein the control device (20) is designed to transmit audio data to the hearing aid (10),
characterized,
in that the transmitting device (21) is designed to transmit the control data and the audio data together via a digital radio link to the receiving device (11) of the hearing device (10). Control device (20) according to claim 7,
characterized,
in that the control unit (20) is designed to transmit the control data and the audio data in various data packets to the hearing aid (10). Control device (20) according to claim 7,
characterized,
in that the control unit (20) is designed to transmit the control data and the audio data in common data packets to the hearing aid (10),
wherein the data packets each comprise a payload data block and a payload header preceding the payload data block, and
wherein in the packet header of a data packet control data and in the payload data block of this data packet audio data are transmitted. Control device (20) according to one of claims 7 to 9,
characterized,
in that the transmitting device (21) is designed as an inductive transmitter, which transmits the control data and the audio data to the hearing aid (10) by means of a magnetic radio link. Control device (20) according to claim 10,
characterized,
that an interface (23) is provided to connect the control unit (20) wirelessly or via a cable to a data processing system (40). Control device according to claim 11,
characterized,
that an internal energy supply device is provided in the form of a battery or batteries. Control device according to one of claims 7 to 12,
characterized,
in that a tone generator is provided in order to generate audio signals in the control unit (20) which are then sent as audio data to the hearing aid (10). Hearing aid (10) having signal processing means (13) for processing audio signals received from an internal microphone (131) and then output via an output transducer (132),
with a control device (12) for controlling the signal processing device (13), and
a receiving device (11) for wirelessly receiving control data from an external control device (20),
wherein the hearing aid (10) is designed to receive audio data,
characterized,
in that the receiving device (11) is designed to receive audio data and control data which are transmitted jointly via a digital radio link. Hearing aid (10) according to claim 14,
characterized,
in that the receiving device (11) is designed to receive control data and audio data which are transmitted in different data packets of the digital radio link. Hearing aid (10) according to claim 14,
characterized,
in that the receiving device (11) is designed to receive control data and audio data which are transmitted jointly in data packets, the data packets each having a payload data block and a packet header preceding the payload data block, and
wherein in the payload data block of a data packet audio data and in the packet header of the data packet control data are transmitted. Hearing aid (10) according to one of claims 14 to 16,
characterized,
in that the receiving device (11) is designed as an inductive receiver which receives the audio data and the control data via a magnetic radio link.

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