EP3863305A1 - Hearing aid - Google Patents

Abstract

The invention relates to a hearing aid (2) having a housing (4) with a base plate (6) and with a housing shell (8), having a number of electrical and / or electronic units (12) and having a transmitting and receiving unit (20) for transmitting and receiving electromagnetic waves, the number of electrical and / or electronic units (12) being attached to the base plate (6), the transmitting and receiving unit (20) having an electronic circuit (18) for generating a transmission signal and a having an antenna unit (24) coupled thereto and wherein the antenna unit (24) has a first antenna arm (28) and a shielding element (26) for shielding the first antenna arm (28) from the number of electrical and / or electronic units (12).

Description

The invention relates to a hearing aid which is designed in particular as a classic hearing aid.

Hearing aids are typically classic hearing aids that are used to care for the hard of hearing. In a broader sense, however, this term also refers to devices that are designed to support people with normal hearing. Such hearing aids are also referred to as "Personal Sound Amplification Products" or "Personal Sound Amplification Devices" ("PSAD" for short). These are not intended to compensate for hearing loss, but are used specifically to support and improve normal human hearing in specific hearing situations, e.g. to support hunters on the hunt or to support animal observation in order to better perceive animal sounds and other noises made by animals can, for sports reporters, to enable improved speaking and / or speech understanding in complex background noise, for musicians, to reduce the burden on hearing, etc.

Regardless of the intended use, hearing aids typically have an input transducer, a data and / or signal processing device, which usually includes an amplifier, and an output transducer as essential components. The input transducer is usually formed by an acousto-electrical transducer, that is to say for example by a microphone, and / or by an electromagnetic receiver, for example an induction coil. An electro-acoustic converter is usually used as the output converter, for example a miniature loudspeaker (also referred to as a "listener"), or an electromechanical transducer, for example a bone conduction receiver, and the data and / or signal processing device is usually implemented by an electronic circuit implemented on a printed circuit board.

Such hearing aids also typically have an antenna unit or an antenna element as a so-called RF antenna, by means of which the hearing aid can be coupled in terms of signaling, for example, to an operating element (remote control) and / or to another hearing aid. As a rule, for reasons of space, the same antenna unit or the same antenna element is used for sending and receiving data.

In a so-called binaural hearing device, two such hearing aids or hearing aids are worn by a user, with a wireless signal connection between the antenna units or antenna elements of the hearing aids during operation. During operation, data, possibly also large amounts of data, are exchanged or transmitted wirelessly between the hearing aids on the right and left ears. The exchanged data and information enable a particularly effective adaptation of the hearing aids to a particular acoustic situation. In particular, this enables a particularly authentic surround sound for the user and improves speech understanding, even in noisy environments.

Hearing aids are preferably designed to be particularly space-saving and compact, so that they can be worn as inconspicuously as possible by a hearing aid user. For this reason, ever smaller hearing aids are being produced which are increasingly comfortable to wear and are therefore hardly perceived by a user when they are worn on or in one ear. Due to the resulting reduced installation space, however, it is increasingly difficult to accommodate and / or install conventional antenna units or antenna elements for wireless signal transmission in hearing aids of this type.

This problem occurs in particular with ITE hearing aids, which are usually custom-made and deep in an auditory canal or ear canal of the The hearing aid user. Such hearing aids are preferably designed to be compact in terms of installation space that they are arranged essentially optically invisible in the ear canal when they are worn.

Based on this, the invention is based on the object of specifying an advantageously designed hearing aid.

According to the invention, this object is achieved by a hearing aid with the features of claim 1. Preferred developments are contained in the claims that refer back.

The hearing aid according to the invention is preferably designed as a hearing aid of the type mentioned at the beginning and is typically designed as an in-the-ear hearing aid (ITE hearing aid), for example as a canal hearing aid (ITE: In-The-Ear, CIC: Completely-In -Channel, IIC: Invisible-In-The-Channel).

The hearing aid has a housing with a base plate, also called a faceplate, and with a housing shell. Here, the housing is preferably designed in two parts and in this case the base plate and the housing shell then form the two parts of the housing. In addition, the base plate and the housing shell are expediently connected to one another or fastened to one another, at least in an assembled state. In this case in particular, the base plate and the housing shell also preferably close off the hearing aid towards the outside.

The hearing aid also has a number of electrical and / or electronic units, that is to say one or more electrical and / or electronic units, hereinafter also referred to as E units for short, this number of electrical and / or electronic units being attached to the base plate. An input transducer, for example a microphone, forms such an E-unit. Alternatively or additionally, a battery or an accumulator forms such an electrical unit and / or a data and / or signal processing device mentioned at the beginning, also simply referred to below as Data processing unit referred to, forms a corresponding E-unit. A corresponding data processing unit typically has an amplifier or an amplifier function.

In addition, the hearing aid has a transmitting and receiving unit for transmitting and receiving electromagnetic waves, this having an electronic circuit for generating a transmission signal and an antenna unit coupled to it or an antenna element coupled to it. This antenna unit typically has or forms an RF antenna of the type mentioned at the beginning. Therefore, in the context of this application, electromagnetic waves are to be understood in particular as radio signals, which are also referred to as RF signals.

The transmitting and / or receiving unit is now functionally suitable and set up for generating and / or evaluating RF signals that can be sent or received by means of the antenna unit. The transmission range in this case is typically less than 20 m and, for example, 10 m. A range is to be understood here in particular as the signal range, i.e. a distance of the respective communication or signal connection that may exist at most between a transmitter and a receiver, so that another Communication between these is possible.

Independently of this, the transmitting and / or receiving unit and in particular the antenna unit are preferably designed for what is known as far-field radiation. This means that so-called far-field radiation is achieved in transmission mode, in which electromagnetic waves emitted by the antenna unit propagate into the far field, also known as the Fraunhofer region. The transmission of information is therefore preferably not implemented by an inductive and / or capacitive coupling between transmitter and receiver. An electric field or predominantly electric field is typically generated on the antenna unit itself or with the antenna unit. At least the electrical component of the field is dominant in the immediate vicinity of the antenna unit. The antenna unit is therefore particularly suitable and set up to receive or record and send or emit electromagnetic radio waves.

The antenna unit is also preferably designed as a radio frequency antenna (RF antenna) or as an RF resonator, for example for 2.4 GHz Bluetooth transmission using an ISM frequency band (ISM: Industrial, Scientific and Medical). In any case, however, the transmitting and / or receiving unit and in particular the antenna unit is designed in such a way that wireless communication is enabled, in particular with other electronic devices, for example with other hearing aids (e.g. to form a binaural hearing aid system or hearing aid system), with remote controls Programming devices or with cell phones. The wireless communication takes place here typically by means of electromagnetic waves in the radio frequency range from 500 kHz to 5 GHz and preferably in the frequency range from 500 MHz to 5 GHz.

In the worn state, the hearing aid is preferably arranged essentially completely, but at least partially, in an ear canal or auditory canal of the user. The antenna element and / or the transmitting and / or receiving unit are preferably suitable and set up for correcting attenuations and / or detunings of the RF signals due to the user's head.

In the hearing aid according to the invention, the antenna unit now has a first antenna arm and a shielding element for shielding the first antenna arm from the number of E units. In the context of this application, an antenna arm is typically to be understood as an elongated conductor element, in particular an elongated conductor / conductor wire or an elongated conductor track, and the shielding element usually has an electrical conductor element, in other words in particular a conductor / conductor wire or a conductor track, or is formed by an electrical conductor element, so in particular by a conductor / conductor wire or a conductor track. In addition, the antenna arm and the shielding element are preferably formed from the same material, typically from the same metal or the same metal alloy.

The shielding effect of the shielding element advantageously results in freedom in the design of the hearing aid and, in particular, in the design of the antenna unit to the effect that when choosing the resonance frequencies or the resonance frequency for the antenna unit, possible interference frequencies from the E-units do not have to be taken into account, so that quasi Antenna unit and E-units can be optimized independently of one another.

This creates the possibility, for example, of using a simpler amplifier or a simpler amplifier function and thus a simpler data processing unit for amplifying transmit signals and / or receive signals. In at least one application, the hearing aid then also has such a simpler amplifier or a simpler data processing unit. In addition, a corresponding amplifier can be positioned more freely, i.e. less has to be taken into account when selecting a suitable position for the amplifier. In such cases, it is usually referred to as a "floating amplifier".

Due to the additional freedom when specifying the resonance frequency or the resonance frequencies, it is also possible in some cases to dispense with adaptation elements such as an ohmic resistor, a coil, a capacitor and / or a so-called balun, and in the case of at least one design the antenna unit also does not have such an adaptation element. This means that the hearing aid according to the invention does not have an adaptation element of the type mentioned above in at least one application.

Furthermore, an embodiment is advantageous in which the first antenna arm is designed as a free arm. In the context of this application, a cantilever arm is to be understood as meaning, in particular, an elongated conductor element, such as an elongated conductor / conductor wire or an elongated conductor track, with at least one free end or free end. The antenna unit is independent of this preferably designed or configured only for one resonance frequency. More preferably, the antenna unit only has the one previously mentioned free arm.

Apart from this, the shielding element is expediently positioned between the first antenna arm and the number of E-units. In addition, the shielding element is preferably positioned between the first antenna arm and the electronic circuit of the transmitting and receiving unit.

It is also advantageous if the shielding element has or forms a curved conductor, a conductor loop or a conductor loop. A geometry of the shielding element in which the shielding element is at least approximately ring-shaped, that is to say has a ring shape, is typical here. In this case, however, the geometry does not necessarily correspond to a geometric circle. In addition, the ring shape is not necessarily closed. However, the arched conductor, the conductor loop or the conductor loop preferably spans at least one arched area or angular area of at least 120 °, more preferably of at least 180 ° and in particular of at least 300 °. If the shielding element has a conductor loop or conductor loop, the number of E-units is expediently positioned within the conductor loop or the conductor loop and / or the electronic circuit of the transmitting and receiving unit is positioned within the conductor loop or the conductor loop. If the shielding element has an arched conductor, this typically at least partially encompasses the number of E units and / or the electronic circuit of the transmitting and receiving unit.

Regardless of this, an embodiment of the shielding element in which it has an auxiliary module is advantageous. If the shielding element then also has an arched conductor, a conductor loop or a conductor loop, the auxiliary module is preferably integrated in the arched conductor, in the conductor loop or in the conductor loop, so that the auxiliary module is, as it were, a part or a segment of the arched conductor that Conductor loop or the conductor loop forms or so that the auxiliary module quasi a conductor path or a The conductor segment of the curved conductor, the conductor loop or the conductor loop is replaced. The auxiliary module is typically an electrical module with an ohmic resistance, with a capacitance and / or with an inductance, for example a capacitor, a coil, a resistor or simply a conductor interruption kind of a gap.

In particular if the shielding element has a type of conductor loop, it is also advantageous if the first antenna arm at least partially encompasses the shielding element and spans or covers, for example, an arcuate area or angled area of at least 90 °. The course of the first antenna arm then preferably follows the course of the shielding element in at least one section in good approximation, the first antenna arm also preferably running at approximately the same distance from the shielding element in this area.

Another embodiment variant is favorable in which the first antenna arm is connected to the shielding element via a second antenna arm. Here, the second antenna arm is preferably connected to the first antenna arm at a first end of the first antenna arm. Depending on the embodiment variant, the second antenna arm also has an auxiliary module of the aforementioned type or is formed by such an auxiliary module.

Independently of this, an embodiment is expedient in which the first antenna arm is connected to the shielding element via an auxiliary module of the type mentioned above. This auxiliary module is preferably connected to the first antenna arm by a second end of the first antenna arm.

It is also useful if the first antenna arm is connected to the electrical circuit of the transmitting and receiving unit via a feed arm. A corresponding feed arm is further preferably positioned at a predetermined distance from a previously mentioned second antenna arm.

In an advantageous development, the antenna unit is designed in the manner of a so-called PIF antenna (Planar Inverted F-Shaped Antenna). In this case, a ground potential or reference potential is then typically specified for the shielding element when the hearing aid is in operation. A previously mentioned second antenna arm, a previously mentioned feed arm and the first antenna arm then usually form an F-shaped basic pattern made of a conductive material, for example copper.

Another embodiment is preferred in which the antenna unit or at least one subunit with the first antenna arm and the shielding element has only a very small extent in one spatial direction, typically less than or equal to 1 mm, and in which at least the first antenna arm and the shielding element are essentially lie in a plane whose normal is aligned parallel to this spatial direction.

Independently of this, the antenna unit is typically not formed by a film structure. In particular, the shielding element is preferably not formed by a film. Instead, the antenna unit or at least one sub-unit with the first antenna arm and with the shielding element is preferably formed by conductor tracks and / or by conductor wires.

In addition, the antenna unit or at least the aforementioned subunit is preferably formed by a number of conductor tracks that are applied in particular to a substrate or to the base plate. Here, the conductor tracks are, for example, printed on or applied using a coating process. A film or a flexible printed circuit board (flexible PCB), for example, serves as the substrate, if used.

Alternatively, the antenna unit has a significant expansion in three orthogonal spatial directions. In such a case, the antenna unit is further preferably at least partially and in particular completely cast in a plastic which, for example, forms the base plate.

According to an advantageous embodiment, the antenna unit also has an electrically conductive additional arm which is connected to the first antenna arm. If the first antenna arm and the shielding element then also lie essentially in one plane, the additional arm is preferably led out or tilted out of this plane. Depending on the application, the additional arm is also followed by a further conductor or a further conductor structure, which is more preferably outside the plane and / or is held / carried by the additional arm and / or connected to the first antenna arm via the additional arm is.

In accordance with a further embodiment variant, the antenna unit also has a connection element, with the aid of which in particular the aforementioned feed arm of the antenna unit is connected to the electronic circuit of the transmitting and receiving unit. Such a connection element is preferably designed as a type of waveguide. Depending on the application, such a waveguide is designed as a strip conductor, for example as a so-called "slot waveguide", "slot-line waveguide" or "microstrip-line waveguide", and / or as a coplanar waveguide. According to one embodiment variant, the waveguide has, for example, three parallel conductor strips lying in one plane, for example two outer conductor strips being at a ground potential or reference potential when the hearing aid is in operation and a central conductor strip being used for signal transmission during operation. A connection element which is designed as a coaxial cable is also advantageous.

It is also expedient if a ground potential or reference potential is specified when the hearing aid is in operation and if the shielding element is connected to the electronic circuit of the transmitting and receiving unit in order to specify the ground potential or reference potential. Depending on the embodiment variant, the ground potential or reference potential for the shielding element or for the electronic circuit is then specified in this way.

As an alternative or in addition to this, a ground potential or reference potential or the aforementioned ground potential or reference potential is specified the shielding element is connected to at least one of the E-units from the number of E-units, for example to a battery or an accumulator of the hearing aid.

FIG 1

in einer vereinfachten und teilweise transparenten Darstellung ein Hörgerät mit einer Antenneneinheit in einer ersten Ausführung,

FIG 2

in einer perspektivischen Ansicht die Antenneneinheit in der ersten Ausführung,

FIG 3

in einer zweiten perspektivischen Ansicht die Antenneneinheit in der ersten Ausführung zusammen mit weiteren Komponenten des Hörgeräts,

FIG 4

in einer dritten perspektivischen Ansicht ein Teil der Antenneneinheit in einer zweiten Ausführung,

FIG 5

in einer vierten perspektivischen Ansicht ein Teil der Antenneneinheit in einer dritten Ausführung mit einem Zusatzarm und einer damit verbundenen weiteren Leiterstruktur,

FIG 6

in einer fünften perspektivischen Ansicht der Zusatzarm und die damit verbundene weitere Leiterstruktur sowie

FIG 7

in einer sechsten perspektivischen Ansicht die Antenneneinheit in einer vierten Ausführung.

Embodiments of the invention are explained in more detail below with reference to a schematic drawing. Show in it:

FIG 1

in a simplified and partially transparent illustration, a hearing aid with an antenna unit in a first embodiment,

FIG 2

in a perspective view the antenna unit in the first embodiment,

FIG 3

in a second perspective view the antenna unit in the first embodiment together with further components of the hearing aid,

FIG 4

in a third perspective view a part of the antenna unit in a second embodiment,

FIG 5

in a fourth perspective view a part of the antenna unit in a third embodiment with an additional arm and a further conductor structure connected to it,

FIG 6

in a fifth perspective view of the additional arm and the associated further conductor structure as well

FIG 7

in a sixth perspective view the antenna unit in a fourth embodiment.

Corresponding parts are provided with the same reference symbols in each of the figures.

A hearing aid 2 described below by way of example is shown in FIG Fig. 1 reproduced in a simplified and partially transparent illustration and has a housing 4 with a base plate 6 and with a housing shell 8. The housing 4 is designed in such a way that the base plate 6 is reversibly detachably connected to the housing shell 8 when the housing 4 is formed and the base plate 6 can be detached from the housing shell 8 by actuating a push button 10 on the base plate 6.

Furthermore, in the exemplary embodiment, a plurality of electrical and / or electronic units, hereinafter referred to as E units 12 for short, are attached to the base plate 6. In the embodiment according to FIG Fig. 3 two microphones 14 each one of these E-units 12 from. Furthermore, a data processing unit 16 forms an E-unit 12 and two further E-units 12 are formed by an electronic circuit 18 of a transmitting and receiving unit 20 and by a battery 22.

In this case, the transmitting and receiving unit 20 is designed to transmit and receive electromagnetic waves when the hearing aid 2 is in operation, in particular for communication with a second hearing aid, not shown. Part of the transmitting and receiving unit 20 is the electronic circuit 18 and an antenna unit 24, as shown in FIG Fig. 2 is reproduced. In the exemplary embodiment, that antenna unit 24 is designed as a so-called PIF antenna and has a shielding element 26 for which a ground potential or reference potential is specified when the hearing aid 2 is in operation.

That shielding element 26 is in accordance with the exemplary embodiment Fig. 2 formed by a conductor loop, which in a rough approximation has a ring shape. Here, the shielding element 26 surrounds or engages around the aforementioned electrical units 12 and thereby shields a first antenna arm 28 of the antenna unit 24 from these electrical units 12. The first antenna arm 28 in the exemplary embodiment according to FIG Fig. 2 designed as a free arm.

The shielding element 26 and the first antenna arm 28 lie in one plane and both are each designed as conductor tracks, for example made of copper. Depending on the embodiment variant, the conductor tracks are applied, for example, printed onto a substrate 30, which is shown in FIG Fig. 2 is also shown and is typically part of the antenna unit 24. In the exemplary embodiment, a film forms the substrate 30 and, in order to form the hearing aid 2, this film, together with the already applied conductor tracks, is preferably slipped over the electrical units 12, applied to the base plate 6 of the housing 4 and glued to the base plate 6. In this state, the E-units 12 penetrate a breakthrough in the substrate 30.

In the exemplary embodiment, the aforementioned first antenna arm 28 at least partially surrounds the shielding element 26 and is connected at a first end to the shielding element 26 via a second antenna arm 32. At a distance from the second antenna arm 32, a feed arm 34 branches off from the first antenna arm 28 in the exemplary embodiment, via which the antenna unit 24 is galvanically connected to the electronic circuit 18 of the transmitting and receiving unit 20.

In the exemplary embodiment, part of the antenna unit 24 is also a connection element 36, which is shown in FIG Fig. 2 is designed as a coplanar waveguide and connects the feed arm 34 on the one hand and the shielding element 26 on the other hand to the electronic circuit 18 of the transmitting and receiving unit 20. Here, the connection element 36 has three coplanar, parallel conductor strips, of which the two outer conductor strips are each connected to one end of the loop shape of the shielding element 26. The central conductor strip positioned between the outer conductor strips is additionally connected to the feed arm 34 and a sensor signal can then be fed into the antenna unit 24 and / or a received signal can be read out via this. Depending on the embodiment variant, the connection element 36 is tilted out of the plane in which the shielding element 26 and the first antenna arm 28 extend and protrudes perpendicularly from the substrate 30, for example.

As shown in the illustration Fig. 3 it can be seen that the push button 10 is positioned outside of the shielding element 26 in the exemplary embodiment. More precisely, the push button 10 is arranged between the first antenna arm 28 and the shielding element 26. Alternatively, the push button 10 is arranged inside the shielding element 26 or outside the first antenna arm 28, that is to say outside the shielding element 26 and outside a space between the shielding element 26 and the first antenna arm 28.

A modified embodiment of the antenna unit 24 is shown in FIG Fig. 4 reproduced or at least indicated. Here, the shielding element 26 and the first antenna arm 28 have significant expansions in three orthogonal spatial directions, so that, if at all, it is only possible to speak of an arrangement in one plane to a limited extent. Here, strip-like conductor structures form the first antenna arm 28 and the shielding element 26. In such a configuration, the shielding element 26 and the first antenna arm 28 are preferably embedded in a plastic compound, in particular a plastic compound that forms the base plate 6.

The schematic representation in Fig. 5 shows a third embodiment of the antenna unit 24. The main difference to the embodiment according to FIG Fig. 3 is an additional conductor structure 38 with an additional arm 40, which, in contrast to the shielding element 26, the first antenna arm 28, the second antenna arm 32 and the feed arm 34, does not lie in the aforementioned plane, but is led out or tilted out of this plane. The additional arm 40 is therefore in particular not designed as a conductor track on the substrate 30, but rather as a conductor wire that protrudes from the substrate 30.

The additional arm 40 is connected in the exemplary embodiment according to FIG Fig. 5 a transverse conductor 42, which together with the additional arm 40 forms a T-shape. A transition arm 44, in turn, adjoins the transverse conductor 42 at both ends, a kink being formed between each transition arm 44 and the transverse conductor 42. Finally, each transition arm 44 is followed by a U-shaped conductor element 46, the opening of the U-shape preferably being the first Antenna arm 28 is facing. The additional conductor structure 38 formed from additional arm 40, transverse conductor 42, transition arms 44 and U-shaped conductor elements 46 is shown in FIG Fig. 6 reproduced from a second perspective and enlarged.

A fourth variant embodiment of the antenna unit 24 is shown in FIG Fig. 7 reproduced. Based on the execution according to Fig. 3 The fourth embodiment variant differs through three auxiliary modules 48, 50, 52, which are part of the antenna unit 24. Two of these auxiliary modules 48, 52 are quasi integrated into the conductor tracks of the antenna unit 24 and, based on the embodiment according to FIG Fig. 3 a section of a conductor track on the substrate 30 in each case. The auxiliary module 48 is part of the shielding element 26 and is accordingly integrated into the conductor track of the shielding element 26. The auxiliary module 52 is integrated into the conductor track of the second antenna arm 32. The third auxiliary module 50 connects the second end of the first antenna arm 28 to the shielding element 26.

The three auxiliary modules 48, 50, 52 are designed in the same way or differently depending on the application. Regardless of this, a corresponding element is typically an electrical component with an ohmic resistance, with a capacitance and / or with an inductance, for example a capacitor, a coil, a resistor or simply a conductor interruption , so basically a gap.

List of reference symbols

2

Hearing aid

4th

casing

6th

Faceplate

8th

Housing shell

10

Push button

12th

E unit

14th

microphone

16

Data processing unit

18th

electronic switch

20th

Transmitter and receiver unit

22nd

battery

24

Antenna unit

26th

Shielding element

28

first antenna arm

30th

Substrate

32

second antenna arm

34

Dining arm

36

Connection element

38

additional ladder structure

40

Additional arm

42

Cross conductor

44

Transition arm

46

Ladder element

48

Auxiliary module

50

Auxiliary module

52

Auxiliary module

Claims (15)

Hearing aid (2) having a housing (4) with a base plate (6) and with a housing shell (8), having a number of electrical and / or electronic units (12) and having a transmitting and receiving unit (20) for transmitting and receiving of electromagnetic waves, where - the number of electrical and / or electronic units (12) are attached to the base plate (6), - The transmitting and receiving unit (20) has an electronic circuit (18) for generating a transmission signal and an antenna unit (24) coupled to it, and - The antenna unit (24) has a first antenna arm (28) and a shielding element (26) for shielding the first antenna arm (28) from the number of electrical and / or electronic units (12) and in particular from the electronic circuit (18) of the transmitter - and receiving unit (20). Hearing aid (2) according to claim 1,
wherein the first antenna arm (28) is designed as a free arm and wherein in particular the first antenna arm (28) at least partially surrounds the shielding element (26). Hearing aid (2) according to claim 1 or 2,
wherein the shielding element (26) has a conductor loop. Hearing aid (2) according to one of Claims 1 to 3,
wherein the shielding element (26) has an auxiliary module (48). Hearing aid (2) according to one of Claims 1 to 4,
wherein the first antenna arm (28) is connected to the shielding element (26) via a second antenna arm (32). Hearing aid (2) according to claim 5,
wherein the second antenna arm (32) is connected to a first end of the first antenna arm (28). Hearing aid (2) according to claim 5 or 6,
wherein the second antenna arm (32) has an auxiliary module (52). Hearing aid (2) according to one of claims 1 to 7,
wherein the first antenna arm (28) is connected to the shielding element (26) via an auxiliary module (50). Hearing aid (2) according to claim 8,
wherein the auxiliary module (50) is connected to a second end of the first antenna arm (28). Hearing aid (2) according to one of claims 1 to 9,
the first antenna arm (28) being connected to the electronic circuit (18) of the transmitting and receiving unit (20) via a feed arm (34) and the antenna unit (24) being designed in particular in the manner of a PIF antenna. Hearing aid (2) according to one of claims 1 to 10,
wherein the first antenna arm (28) and the shielding element (26) lie in one plane. Hearing aid (2) according to one of claims 1 to 11,
wherein the antenna unit (24) has a number of conductor tracks which are applied to a substrate (30) or to the base plate (6). Hearing aid (2) according to one of claims 1 to 12,
wherein the antenna unit (24) has an electrically conductive additional arm (40) which is connected to the first antenna arm (28), and wherein in particular the first antenna arm (28) and the shielding element (26) in lie on a plane and the additional arm (40) is led out of this plane. Hearing aid (2) according to one of claims 1 to 13,
wherein the electronic circuit (18) of the transmitting and receiving unit (20) is connected to the antenna unit (24) via a waveguide (36) or via a coaxial cable. Hearing aid (2) according to one of claims 1 to 14,
wherein the shielding element (26) is connected to the electronic circuit (18) of the transmitting and receiving unit (20) or to at least one electrical and / or electronic unit (12) from the number of electrical and / or electronic units to specify a ground potential.

Images