EP1698908A2 - Method for adjusting a hearing aid, hearing aid and mobile control unit for the adjustment of a hearing aid - Google Patents

Abstract

An input signal is converted into an electrical signal and electrical signal is processed by signal processing unit (5). An output signal perceived by an user of hearing aid (1) as an acoustic signal is generated and a parameter is adjustable for adapting the signal processing unit to spatial hearing areas. A satellite-assisted positioning system generating a position signal related to hearing aid is provided. The position signal is generated by positioning system and evaluated. The parameter is adjusted based on the evaluated position signal. Independent claims are also included for the following: (1) hearing aid; (2) mobile activation device; and (3) operating parameter set method.

Description

The invention relates to a hearing aid with an input transducer for receiving an input signal and conversion into an electrical signal, a signal processing unit for signal processing of the electrical signal and an output transducer for generating a perceptible by a user of the hearing aid as an acoustic signal output signal. Furthermore, the invention relates to a method for setting such a hearing aid device and a mobile drive unit for the automatic adjustment of operating parameters of a hearing aid.

In a hearing aid, an input signal is received by means of an input transducer and converted into an electrical input signal. Usually serves as an input transducer at least one microphone which receives an acoustic input signal. Modern hearing aids often comprise a microphone system with a plurality of microphones in order to achieve a direction dependent on the direction of arrival of acoustic signals reception, a directional characteristic. However, the input transducers may also include a telecoil or antenna for receiving electromagnetic input signals. The input signals converted by the input transducer into electrical input signals are fed to a signal processing unit for further processing and amplification. The further processing and amplification takes place to compensate for the individual hearing loss of a Hörhilfsgeräteträgers usually in response to the signal frequency. The signal processing unit outputs an electrical output signal, which is fed via an output transducer to the hearing of the hearing aid wearer, so that the latter perceives the output signal as an acoustic signal. As output transducers usually listeners are used, which generate an acoustic output signal. However, output transducers for generating mechanical vibrations are also known, which directly excite certain parts of the ear, such as the ossicles, to vibrate. Furthermore, output transducers are known which directly stimulate neurons of the ear.

EP 0 064 042 B1 discloses a hearing aid device with a microphone, a signal processing unit and a receiver, in which different parameter inserts can be stored in a memory in order to adapt the signal processing unit to different listening situations. The hearing aid is thereby equipped with different hearing programs for different listening situations, which can be switched manually.

From US Pat. No. 5,604,812 a hearing aid is known, which has a signal analysis unit for automatic conversion between different hearing programs, which recognizes the current hearing situation and selects a suitable hearing program.

From US 5,721,783 a hearing aid with a wirelessly connected remote control is known. The remote control can be connected to a variety of sensors and peripherals to provide requested or unsolicited information. For example, information about the position of a user may be transmitted by specially trained broadcasters at specific points in a retirement home, or a self-contained, user-assisted gyroscope, accelerometer and compass inertial navigation system or GPS (Global Positioning System) receiver may be used.

From DE 100 48 341 C1 a hearing aid is known, which detects the automatic selection of a hearing program, whether it is in the vicinity of an external transmitter. The transmitter generates a transmitter-specific signal, so that an assignment of different transmitters can take place.

P. Engel describes in "Retooling the Global Positioning System," Scientific American, May 2004, the Functioning of GPS and Advanced Satellite Positioning Systems. D-GPS (Differential GPS), for example, allows for accuracy of positioning to 30 to 50 cm and, under certain circumstances, for indoor positioning.

An object of the present invention is to specify a method for setting a hearing aid device and a hearing aid device, in which the adaptation of the signal processing to different hearing ranges is improved.

This object is achieved for the method by claim 1 and for the hearing aid by claim 15.

The adaptation of the signal processing of the hearing aid to different spatial hearing areas is carried out by setting at least one parameter influencing the signal processing of the hearing aid. According to the invention, a satellite-supported position determination system for generating a position signal is provided for this purpose. This is generated and evaluated to automatically adjust the parameter depending on the position signal.

The method according to the invention has the advantage that the adjustment of the parameter does not occur manually. Furthermore, it has the advantage that the setting does not depend on the particular hearing situation that is recorded by the input transducer. This is particularly advantageous when the automatic detection of a hearing situation is not clear and thus the hearing aid is operated with a wrong parameter. Another advantage is that no external, specially adapted to the hearing aid transmitter are used, but that the worldwide accessible network of satellites for satellite positioning is used. This has a particularly advantageous effect on the structure of the hearing aid, since the Hearing aid either with an integrated satellite positioning system can be formed in a component or operated with an additional external hearing aid module with a satellite positioning system and can exchange information. Depending on the form of training, the position determination system transmits information about the position of the integrated unit or the hearing aid module.

Preferably, the position signal is transmitted continuously or at intervals pulsed. The former has the advantage that position changes can immediately affect the setting of the parameter, the latter procedure consumes less energy.

In a particularly advantageous embodiment, the information about the position from the position signal in the position determination system itself is determined and transmitted, for example in the form of global coordinates to the signal processing unit. This has the advantage that a conventional positioning system can be used. Alternatively, there is the possibility that a kind of raw information is transmitted to the signal processing unit and there the information about the position is extracted. In this case, the requirements for the position determining system are lower, so that e.g. a more energy-efficient implementation is possible. One advantage is that the essential calculations are performed with only one signal processing unit, namely that of the hearing aid, so that the calculation is efficiently controlled and e.g. can only be done if necessary.

In one embodiment of the method, the adjustment of the parameter causes a signal processing that is adapted to an acoustic situation in the listening area. The acoustic situation can be determined, for example, by acoustic signals which are to be processed optimally. For example, in a TV room on the TV adapted output signal to be generated in a conference room especially input signals from interlocutors are optimally processed or on a sports field to different hearing programs are set at different locations.

In a particular embodiment of the method, the adjustment of the parameter is part of a hearing program setting of a hearing program, which is stored in particular in the signal processing unit of the hearing aid. Accordingly, the method may set a set of parameters that together define the listening program. A hearing program is to be understood as meaning both a permanently set amplification profile and a functional signal processing which continuously adapts to further environmental parameters.

Preferably, at least one of the auditory regions is defined in its two- or three-dimensional extent. That is, a spatial area, such as the living room, or an area, such as a soccer field, is e.g. defined with its boundary coordinates or via a geometry with respect to a reference point. The listening area will then be given an adjustment of the parameter, i. e.g. a value or function.

The extent of the hearing range can be entered using global coordinates, for example, by means of a hearing aid programming unit. Alternatively or additionally, at least one position of the satellite-supported position-determining system can be stored in order to hold, for example, the corner coordinates of the soccer field. In buildings, it is advantageous to extend the listening area in three dimensions in order to effect different parameter settings in different floors.

In one embodiment of the method, when evaluating the position signal, that one of the hearing areas is identified, in which there is a position transmitted with the position signal, in which case a value of the parameter assigned to the entire hearing range is automatically set.

In one embodiment of the method, the parameter setting is maintained until the position signal indicates a position outside the listening area. For example, when leaving the listening area, "TV room" can be automatically switched back to a previously used parameter setting. Alternatively, it is possible to switch to a parameter setting based on an automatic analysis of the hearing situation. Alternatively, furthermore, a parameter setting can be maintained so long after leaving a first audible range until a position signal indicates a position within a second audible range, so that when changing into this second audible range, the operation of the hearing aid with at least one new parameter setting.

In particularly advantageous embodiments of the method, the position determination with the satellite-based positioning system is differential, i. using a reference unit that reports runtime errors in the satellite signal. Alternatively to the use of a reference receiver, a delay compensation can be calculated due to different influence of different frequency bands. Furthermore, a higher accuracy can be achieved via a so-called assisted position determination, for example by using signals from the mobile network.

In a particularly advantageous embodiment of the method, information about an orientation of the hearing aid in two or three dimensions is taken into account as additional information when setting the parameter. This can be done for example by a compass and / or a tilt sensor. This has the advantage that, for example, in a localized acoustic source, such as in a TV, the parameter setting is made dependent on whether eye contact exists to the acoustic source (for example, high / low gain) or whether the user looks away from the sound source (eg low / high gain).

The embodiment of the hearing aid, in which the satellite-based position determination system is housed in a hearing aid module, further has, for example, the advantage that the hearing aid module can be stored in a listening area in order to provide the user with the appropriate parameter setting during signal processing despite leaving the listening area , For example, if an audio signal from a TV is used directly as an input signal, then the audio signal can be processed with a parameter adapted to the television also outside the listening area.

Further advantageous embodiments of the invention are characterized by the features of the subclaims.

FIG 1

schematisch den Aufbau und die Wirkungsweise eines erfindungsgemäßen Hörhilfsgeräts,

FIG 2

eine Skizze zur Verdeutlichung von Hörbereichen,

FIG 3

Hörbereiche am Beispiel eines Fußballfeldes,

FIG 4

Hörbereich innerhalb eines Gebäudes,

FIG 5

eine Skizze zur Verdeutlichung der Verwendung von Sensoren zur Bestimmung der Ausrichtung eines Hörhilfsgerätes bei der Einstellung eines Parameters,

FIG 6

eine Skizze zur Verdeutlichung der Verwendung eines bewegten bzw. in einem Handy integrierten satellitengestützten Positionsbestimmungssystems und

FIG 7

ein vereinfachtes Blockschaltbild einer Ansteuervorrichtung gemäß der Erfindung.

The following is the explanation of several embodiments of the invention with reference to Figures 1 to 6. It shows:

FIG. 1

1 schematically the construction and mode of operation of a hearing aid according to the invention,

FIG. 2

a sketch to clarify listening areas,

FIG. 3

Listening areas on the example of a soccer field,

FIG. 4

Listening area within a building,

FIG. 5

a sketch to illustrate the use of sensors for determining the orientation of a hearing aid when setting a parameter,

FIG. 6

a sketch to illustrate the use of a moving or integrated in a mobile phone satellite-based positioning system and

FIG. 7

a simplified block diagram of a drive device according to the invention.

1 shows schematically a hearing aid 1 with an input transducer (microphone) 3 for receiving an input signal and conversion into an electrical signal, a signal processing unit 5 for signal processing of the electrical signal and an output transducer (earphone) 7 for generating a user of the hearing aid 1 as acoustic signal perceptible output signal. The signal processing is adapted with at least one parameter P to different spatial listening areas. For this purpose, a satellite-supported position determination system 9 is provided which generates a position signal S (X, Y, Z) and transmits it to the signal processing unit 5. The signal processing unit 5 evaluates the position signal S (X, Y, Z) and automatically sets the parameter as a function of the position signal S (X, Y, Z).

For this purpose, the signal processing, for example, a memory in which different listening areas H _i , ... are defined in their geometric dimensions and their global locations. The memory unit 11 can also be arranged within the satellite-supported position determination system 9. The positioning system 9 can be integrated as a structural unit 1A in the hearing aid 1 or it can be designed as independently designed Hörhilfsgerätmodul, wherein the hearing aid 1 via a cable or wirelessly transmitted the position signal S (X, Y, Z) and / or with the Hearing aid 1 exchanges information.

The positioning system 9 receives radio frequency signals from a plurality of satellites 19 and determines from these signals his current position. The information about the position is transmitted as a position signal S (X, Y, Z) to the signal processing 5. Additional information which may influence the setting of the parameter is, for example, the orientation of the head-mounted component of the hearing aid 1. This is measured for example via a compass 13. Additionally or alternatively, the orientation may be determined via a tilt sensor 15 in a vertical plane. Such sensors can be integrated into a hearing aid 1 without much effort. Together with the location information of the satellite-based position determination system, the orientation of the hearing aid and thus, for example, the viewing direction of a user of the hearing aid 1 can now be determined and thus set in relation to a sound source whose spatial position is also known. The thus recognized acoustic situation can be evaluated in such a way that optimum adjustment of the signal processing is ensured by setting the parameter.

The dependence of the parameter on the position signal, ie its value at the location (X, Y, Z), can for example be entered with a programming unit 17. The programming can be carried out, for example, via the normal hearing device programming interface, eg also wirelessly according to the Bluetooth standard. The dependence can also be stored as a functional assignment, so that, for example, with increasing distance from a location, the amplification of the signal processing 5 is increased. This corresponds to a parameter setting due to a relative change in the position of the positioning system to a predetermined coordinate. Alternatively, for example, listening areas can be defined, ie areas or volumes can be defined in which a specific value is to be taken by the parameter. If all parameters of a hearing program are defined for a listening area, then this hearing area is as it were assigned a hearing program. Once the user or the positioning system stops in this listening area, then takes place signal processing according to the hearing program.

FIG. 2 illustrates the arrangement of areal auditory regions in a coordinate system of latitudes and longitudes 21. For example, a rectangular area is determined by the coordinates of the corners X1, X2, X3 and X4. The corner coordinates X3 and X4 are also corner coordinates of a second listening area B. A listening area C is defined by a circle around the point (X _R , Y _{R) of} radius R, where all points within the circle are not simultaneously in one of the listening areas A or B, are defined as listening area C.

Furthermore, FIG 2 illustrates a differential position determination using the satellites 19 and a transmitter 23. The transmitter 23 transmits a hearing aid 25 (carrier not shown) according to the invention within the listening area A in addition an error signal 27, wherein the error signal 27 runtime error of the satellite signals of the satellite 19 includes. For example, the error signal 27 is generated using a satellite-based reference positioning system 29. Due to the fixed position of the external transmitter 23, erroneous transit times can be calculated by matching the known position of the transmitter 23 with the received signals from the satellites 19. The improvement of the accuracy with the aid of a ground station is also referred to as differential position determination. However, the calculation of such runtime errors can also be achieved by the use of different frequency bands. Alternatively, you can also call a moving receiver as an auxiliary signal. One then speaks of a kinematic satellite position determination.

3 illustrates the invention by way of example on a soccer field D. The soccer field D itself is expired at the beginning of the game, wherein the position determination system operates in a mode in which the coordinates of the travel path are stored. Alternatively, the area D could be through the four coordinates the corner posts are entered. If the player (hearing device user) is on football field D, his hearing aid is in football mode. In addition, a second area E is defined around the exchange banks 31. For listening area E, two sub-listening programs are additionally defined as a function of the orientation of the hearing aid in the room: on the one hand a football observation mode and on the other a conversation mode. Using a compass in the hearing aid on the ear, the user's angle of vision to the football field (head 33) or to a conversation partner (head 35) can be determined. Depending on the orientation of the hearing aid on the head thus different hearing programs (or settings of parameters) are made.

FIG. 4 clarifies the use of three-dimensional hearing ranges F, G and H. This is particularly advantageous if, within a building 41, hearing areas located spatially one above the other are to be defined. For example, the listening area F corresponds to the parameter setting in a canteen, the listening area G to the parameter setting in an office, etc.

5 illustrates the additional use of a tilt sensor in the hearing aid, which can determine the inclination angle α of the head. The angle of inclination affects the setting of a television listening program which extends around a television 51 within a radius of a few meters. The television listening program is set within the listening area only when the user, such as user 51, watches the TV sitting upright with a head tilt angle α. User 53, on the other hand, lies on a sofa, so that his inclination of the head (head angle α ') does not lead to the television listening program. The tilt sensor can interact with an electric compass so that an operator lying on the sofa and watching the television also listens in the television listening program. Preferably, there are minimum time intervals for taking certain positions / locations before setting.

In FIG. 5, it is additionally clarified that, for example, user 51 has deposited his satellite-supported position determination system 55 designed as a hearing aid module on a television table. As long as the positioning system 55 remains there, the user's hearing aid 51 is set to the television mode even when the user 51 leaves the room.

6 illustrates two further embodiments of the invention. Thus, a bus driver 61 with the position determination system 63 can make the setting of hearing parameters as a function of the speed. The determination of the speed by means of satellite-based positioning systems 63 takes place via the frequency shift of the satellite signals. With increasing speed, for example, the gain of the hearing aid to compensate for the wind noise can be increased.

In addition, FIG. 6 shows a user 65 whose satellite-based positioning system is integrated in a portable mobile telephone 67. The position determination in the mobile phone is preferably supported by the telephone network (supported satellite positioning). Depending on the position of the hearing aid is preferably controlled by wireless signal transmission from the mobile phone.

7 shows, in a simplified block diagram, a driver device 101 that can be carried by a user according to the invention. As a user interface, a display 102 and a keyboard 103 are provided. As a result, data can be input and displayed to the drive device 101 in conjunction with suitable software. Additionally or alternatively, the drive device 101 may also have other input or output means. In the exemplary embodiment, the Control device 101 additionally a microphone 107 and a speaker 108 for voice input and voice output, whereby a voice control of the drive device is possible. For example, this is automatically available anyway when integrated into a mobile telephone. The drive device 101 may also be integrated in a remote control of the hearing aid.

To determine the instantaneous position of the drive device 101, this is advantageously equipped with an AGPS receiver 104 (Assisted Global Position System). This allows the current position to be determined to within one meter. The position determination takes place in real time or at least very promptly, so that the current position of the drive device 101 is always present and also movements of a person carrying the drive device 101 can be detected. Storage device 105 is also present in drive device 101, in which the spatial coordinates of preferred user areas of the user can be stored. For example, in the memory 105, the coordinates of various rooms of a building may be stored in which the user preferably resides. In addition, data for controlling a hearing aid can be stored in the memory 105, wherein different, stored in the memory 105 spatial areas different data can be assigned. The drive device 101 also has an interface 106 for wireless data exchange with the device in question. The data transmission preferably satisfies the Bluetooth standard.

All essential components of the drive device 101 are connected to a signal processing and control unit 109. This controls the signal transmission between the individual components of the drive device 101 and ensures the signal processing of all relevant data. In particular, in the signal processing and control unit 109 the data received from the AGPS receiver 104 processed and evaluated.

The control device 101 is generally used to control a controllable hearing aid device 110. In this case, the controllable hearing aid device 110 is carried by the user of the drive device 101. The drive device 101 may additionally be configured to control a plurality of different controllable devices. For this purpose, it can be programmed to control the different devices in a suitable manner.

In the case of the signal transmitted by the control device 101 to the controllable hearing aid device 110, it is provided that this comprises at least one control command for the controllable hearing aid device 110. For example, the control command may cause the controllable hearing aid device 110 to change from a first sequence program to a second sequence program. The transmitted signal may, however, also directly contain parameter settings which are stored in the controllable hearing aid device 110 after the transmission and influence the signal processing in the controllable device 110 from this point in time. In addition, it is also possible for a plurality of different sequence programs of the controllable hearing aid device 110 to be stored in the control device 101 and for a specific sequence program to be selected and transmitted to the controllable hearing aid device 110 as a function of the instantaneous spatial position of the control device 101 and subsequently the program sequence in FIG controllable hearing aid 110 determined.

In one embodiment of the invention, it is provided that the drive device 101 only influences the signal processing of the controllable hearing aid device 110 as long as a signal transmission from the drive device 101 to the controllable hearing aid device 110 takes place continuously or within a certain period of time. This embodiment has the advantage that the controllable hearing aid 110 is operated in a predefined state when the connection between the drive device 101 and the controllable hearing aid 110 is interrupted.

The invention has the advantage that between the control device 101 and the controlled hearing aid 110 no further intermediate devices are required. The data transmission takes place directly between the drive device 101 and the controlled hearing aid 110.

The function of the hearing aid 110 may be dependent on other parameters in addition to the location of the user. These include e.g. Parameters deriving from an evaluation of the signal received by the AGPS receiver of the driver 101. These include e.g. the determination of a movement of the user, the direction of movement or speed of the user. In addition, the control of the controllable hearing aid 110 may also depend on parameters that are independent of the current location of the user. Such parameters are e.g. the time of day, the day of the week, the angle of inclination or the ambient temperature. In addition, a drive device 101 can also be used by a plurality of users, wherein advantageously different user profiles can be stored. The control of the controllable hearing aid 110 then also takes place depending on which user is currently wearing the driver 101, that is, which user profile is activated.

As a further control parameter in addition to the current location of the user can also serve the orientation of the drive device 101 in space. For example, a vertical carrying position of a drive device 101 fastened to a belt clip can be recognized, wherein in this carrying position the control of the controllable hearing aid device 110 is activated by the drive device 101. On the other hand, if the drive device 101 is in a horizontal orientation, this indicates a lying position the user or a set aside control device 101, in which the control of the controllable hearing aid device 110 is deactivated by the drive device 101.

Which position-dependent settings for the hearing aid are set by means of the drive device 101, is determined by a corresponding programming of the drive 101. Corresponding inputs to the control device 101 are carried out by means of existing interfaces (keyboard 103, Bluetooth interface 106, etc.). In particular, by means of the Bluetooth interface 106, the control operations to be carried out can also be carried out conveniently via an external unit (not shown), e.g. a PC, are input to the driving device 101. Furthermore, the drive device 101 may also comprise wired interfaces for connection to an external device for programming.

By programming the control device 101 via an interface, different spatial position data can be assigned different settings for the hearing aid device 110. The signal processing and control unit 109 constantly checks whether operating parameters of the controllable hearing aid device 110 should change as a result of a change of location of the user and thus of the activation device 101. This results in particular by a permanent comparison of the different areas associated with settings with the current position. If a change in at least one operating parameter of the controllable hearing aid device 110 is provided due to a change of location of the drive device 101, a corresponding signal is generated by the drive device 101 and transmitted to the controllable hearing aid device 110 via the Bluetooth interface. This has for this purpose a suitable for wireless reception of the control signal interface, in particular a Bluetooth transmitting and receiving unit 111. The signal processing in the signal processing and control unit 15 can be set via certain parameters, for example are stored in a program memory 113 and determine, for example, the program selection and the volume setting.

The figures illustrate the extremely flexible assignment of spatial areas to settings of parameters. New areas can be defined at any time without any additional aids. Preferably, the hearing aid comprises a button which stores the current coordinate, orientation and / or inclination. These coordinates can be used to offer the user different geometries, which he can then assign to the various coordinates in order to define the listening area. So he can specify a listening area by several coordinates, and assign him a speed interval, a minimum speed and / or a direction in a place.

Claims (38)

A method for setting a hearing aid (1, 110) with an input transducer (3) for receiving an input signal and conversion to an electrical signal, a signal processing unit (5) for signal processing the electrical signal and an output transducer (7) for generating a user of the Hearing aid (1, 110) perceptible as an acoustic signal output signal, wherein at least one parameter for adapting the signal processing to different spatial listening areas (AG) is adjustable, with the following procedural features: Providing a satellite-based position determination system (9) for generating a position signal, Generation and evaluation of the position signal, - Automatic setting of the parameter depending on the position signal. Method according to claim 1,
in that the satellite-supported position determination system (9) is integrated in the hearing aid device (1, 110) or as an external hearing aid device module (55, 67, 101) and transmits a position signal containing information about the position of the hearing aid device (1, 110) or of the hearing aid device module (55, 67, 101). Method according to one of the preceding claims,
characterized in that the position signal is transmitted continuously or at intervals. Method according to one of the preceding claims,
characterized in that the information about the position from the position signal in the satellite Positioning system (9) or in the signal processing unit (5) is obtained. Method according to one of the preceding claims,
characterized in that the adjustment of the parameter causes a signal processing, which is adapted to an acoustic situation in the listening area (AG). Method according to one of the preceding claims,
characterized in that the setting of the parameter is part of a hearing program setting of a hearing program, which is stored in particular in the signal processing unit (5) of the hearing aid device (1, 110). Method according to one of the preceding claims,
characterized in that at least one of the listening areas (AG) is defined in its two- or three-dimensional extent and that at least one of the listening areas is assigned an adjustment of the parameter. Method according to claim 7,
characterized in that the extent of at least one of the listening areas is defined by means of coordinates by means of a programming unit (17) of the hearing aid device (1, 110). Method according to claim 7 or 8,
characterized in that when defining the extent of at least one of the listening areas (AG), coordinates of the position of the satellite-based positioning system (9) are stored at different locations. Method according to one of the preceding claims,
characterized in that at Evaluation of the position signal of one of the listening areas (AG) is identified, in which there is a transmitted with the position signal position, and that the hearing that this area (AG) associated value of the parameter is set. Method according to one of the preceding claims,
characterized in that the parameter setting is maintained until the position signal indicates a position outside the audible range (AG). Method according to one of the preceding claims,
characterized in that the satellite-based position determining system (9) receives signals for differential position determination or assisted position determination. Method according to one of the preceding claims,
characterized in that as additional information in the setting of the parameter information about an orientation of the hearing aid (1, 110) in two or three dimensions is taken into account. Method according to claim 13,
characterized in that the orientation of the hearing aid (1, 110) by a compass (13) and / or a tilt sensor (15) is measured. Hearing aid (1, 110) with an input transducer (3) for receiving an input signal and conversion into an electrical signal, a signal processing unit (5) for signal processing of the electrical signal and an output transducer (7) for generating a by a user of the hearing aid (1, 110) as an audible signal perceptible output signal, wherein at least one parameter for adapting the signal processing to different spatial listening areas (AG) is adjustable, and with a satellite-based position determining system (9), wherein the satellite-based Positioning system (9) either in the hearing aid (1, 110) integrated or as an external hearing aid device (55, 67, 101) is formed, which is particularly integrated with its functionality in a mobile phone or a hearing aid remote control, and wherein the satellite-based position determining system (9) is connected to the signal processing for the transmission of position information, in particular wirelessly, and wherein automatically a parameter setting is adjustable in dependence of the position information. Hearing aid (1, 110) according to claim 15, wherein in the hearing aid (1, 110) in addition a compass (13) and / or an inclination sensor (17) for determining the head alignment is integrated. Mobile control device (55, 67, 101) for automatically setting operating parameters of a hearing aid (1, 110) in the vicinity of the drive device (55, 67, 101) and in dependence on the spatial position of the drive device (55, 67) comprising a memory device (5) for storing spatial position data, a memory device (5) for storing hearing aid setting data, Means for allocating the spatial position data to the hearing aid setting data, a localization unit for detecting whether the drive device (55, 67, 101) is located within a spatial area (AG) defined by the spatial position data, - Means for direct wireless transmission of a signal from the drive device (55, 67, 101) to the hearing aid (1, 110) in dependence of the spatial position associated data for hearing aid adjustment. Mobile control device (1, 22) according to claim 17 with input means (17) for inputting the spatial position data (X1, X2, X3, X4, X _R , Y _R , R) and / or for inputting the hearing aid setting data and / or for assigning the spatial position data to the hearing aid setting data. A mobile driving device (55, 67, 101) according to claim 18, wherein said input means (17) comprises a keyboard. Mobile control device (55, 67, 101) according to claim 18 or 19, wherein the input means (17) comprise means for voice input. Mobile control device (55, 67, 101) according to one of claims 17 to 20, wherein the input means (17) comprise an interface to another device. Mobile control device (55, 67, 101) according to any one of claims 17 to 21, wherein for the storage of the spatial position data of the mobile driving device (55, 67, 101) occupied positions are automatically detected and stored. The mobile control device (55, 67, 101) of any one of claims 17 to 23, wherein the location unit comprises a satellite-based positioning system. The mobile control device (55, 67, 101) of claim 23, wherein the location unit comprises a GPS receiver. The mobile control device (55, 67, 101) of claim 24, wherein the location unit comprises an AGPS receiver. Mobile control device (55, 67, 101) according to any one of claims 17 to 25 with a Bluetooth interface for wireless signal transmission. Mobile control device (55, 67, 101) according to one of claims 1 to 26, which is designed to be carried by a user. Mobile control device (55, 67, 101) according to claim 27, which is integrated in a mobile telephone (67) or a PDA. Mobile control device (55, 67, 101) according to one of claims 17 to 28, wherein the signal transmitted by the control device (55, 67, 101) to the hearing aid (1, 110) comprises control commands and / or hearing aid settings and / or hearing aid programs. Mobile control device (55, 67, 101) according to any one of claims 17 to 29, wherein the wirelessly transmitted signal is emitted continuously or repeatedly within a certain period of time. Mobile control device (55, 67, 101) according to any one of claims 17 to 30, wherein the spatial position of the drive device (55, 67, 101) is locatable in a two- or three-dimensional space. Mobile control device (55, 67, 101) according to any one of claims 17 to 31, wherein in the moving with the user drive device (55, 67, 101) in addition to the spatial position and the direction of movement and / or speed is detected and that of the drive device (55, 67, 101) to the hearing aid (1, 110) transmitted signal in addition to the spatial position and the direction of movement or speed of the mobile control device (55, 67, 101) depends. Mobile control device (55, 67, 101) according to any one of claims 17 to 32, wherein the of the drive device (55, 67, 101) to the hearing aid (1, 110) transmitted signal in addition to the spatial position of the time of day and / or the ambient temperature and / or the ambient brightness and / or a set user profile. Mobile control device (55, 67, 101) according to any one of claims 17 to 33, which is designed to be able to learn with respect to the transferable to the device setting signal. Mobile control device (55, 67, 101) according to any one of claims 17 to 34, wherein the drive device (55, 67, 101) in a wirelessly with the hearing aid (1, 110) communicating mobile phone is integrated. Mobile control device (55, 67, 101) according to any one of claims 17 to 34, wherein the drive device (55, 67, 101) in a wirelessly with the hearing aid (1, 110) communicating remote control of the hearing aid (1, 110) is integrated. Method for the automatic setting of operating parameters of a hearing aid device (1, 110) in the vicinity of a mobile drive device (55, 67, 101) and in dependence on the spatial position of the drive device (55, 67): Storing spatial position data in the drive device (55, 67), Storing data for device setting in the drive device (55, 67), Assignment of the spatial position data to the device setting data, automatic detection of whether the drive device (55, 67, 101) is located within a spatial area defined by the spatial position data, - Sending a wirelessly transferable signal directly from the drive device (55, 67, 101) to the hearing aid (1, 110) in dependence of the spatial position associated data for device adjustment when the drive device (55, 67, 101) within a by the spatial position data is fixed spatial area, Receiving the transmitted signal from the hearing aid device (1, 110) in the vicinity of the drive device (55, 67), - Setting operating parameters of the hearing aid (1, 110) in dependence of the transmitted signal. A method for automatically setting operating parameters of a hearing aid (1, 110) according to claim 37, wherein the drive device (55, 67, 101) is placed at a certain place at least for a longer period of time and the hearing aid (1, 110) relative to the Room moves.

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