EP0822609B1 - Device for receiving and/or transmitting an electromagnetic wave - Google Patents

Description

The invention relates to a device for receiving and / or sending a electromagnetic vibration.

EP-0 214 806 A2 is a portable receiving device or transceiver known, which the reception with a plurality of antennas exploits. This portable transceiver has a narrow-band, flat stripline antenna connected to a first receiver is. There is also a broadband rod antenna with an assigned switch connected, and a second receiver and a transmitter are both connected to the broadband antenna connected via the switch ("duplexer"). The flat stripline antenna is formed from a conductive, radiating Plate (layer) and a conductive ground layer or plate. Both are through one conductive connecting plate or layer connected together. A transmitter and The housing surrounding the receiver contains headphones and Microphone and the stripline antenna under its back. The rod antenna is mounted upright on the top of the case.

Due to the plurality of used in this portable transceiver Antennas are said to reduce fading and noise effects on reception. By using two different types of antennas be excluded that the antennas interfere with each other and that the portable transceiver becomes unnecessarily heavy and bulky.

An antenna for a transceiver is known from US Pat. No. 4,721,962. which does not require a transmit / receive switch, typically a cordless one Phone. This antenna is formed by a printed circuit board that through two separating slots, which are on different levels, in three to each other adjacent areas is divided. These areas are a first end area, the abuts a first slot, a second end portion adjoining a second Slot adjoins, and an intermediate or central area between the slots. Electrically conductive surfaces or conductive traces are through the slots High frequency impedance connected elements such as high-resistance resistors or choke coils. A radio frequency unit is preferably below the central area of the printed circuit board arranged and has a transmitter output stage, which with a first of Areas of the printed circuit board connected to form an antenna the intermediate area and the other end area of the printed Form circuit board director and reflector elements. A receiver entrance of the high-frequency module is connected to the other end region, the one Receiving antenna forms, the intermediate region and the first end region Form director or a reflector element. The radio frequency connections to the respective antennas are arranged near the separation slots.

This antenna arrangement is said to be particularly portable for use (Cordless) phones may be suitable and the beneficial properties of a Have rod antenna and no additional space in the housing of the phone and also do not need any parts protruding from this housing. A majority of e.g. Receiving antennas for simultaneous reception to suppress However, this antenna arrangement does not produce noise and fading.

A shortened, ungrounded antenna is preferred from US-A-5,262,792 for a cellular phone, known which has an antenna element, an electrostatic Coupling element, which is electrostatically coupled to the antenna element, a rectangular, first metal part, one end of which is connected to the electrostatic Coupling element is connected and the other end in one direction extends, which is arranged perpendicular to the axis of the antenna element, a second rectangular metal part, which is parallel underneath the first metal part this is spaced and with one end to the second end of the is connected to the first metal part, and comprises a feed line which is connected to the first and the second metal part is connected.

The invention has for its object a device for receiving and / or sending a to create electromagnetic vibration which is a plurality of antennas has, without thereby compared to such a device with a single Antenna element creates a significantly increased effort.

According to the invention, this object is achieved by a device for receiving and / or sending an electromagnetic oscillation with an antenna element and at least two wave-guiding assemblies, each with one Feed device connected to a connection point of the antenna element and otherwise arranged isolated from each other for electromagnetic vibration and each comprise a conductor part which is in each of the waveguiding Assemblies with the associated feed device for transferring the electromagnetic vibration is coupled, the waveguiding Assemblies for receiving and / or releasing the electromagnetic Vibration are set up via the feed device and the conductor parts are designed to pick up and / or radiate the electromagnetic Vibration in a manner comparable to the antenna element.

In the device according to the invention, a reception or transmission of the achieved electromagnetic vibration without using a plurality of antennas that added another antenna element over the prior art must become. This allows the device according to the invention in its outer design exactly the same as that of the prior art; in particular a Modification of the outer size and size known from the prior art Form avoided. For the user of such a device, this results in its handling does not differ from the state of the art. For the production there is the advantage that the device according to the invention is very simple, there is no for sending or receiving with a plurality of antennas additional, separate antenna element is required, as in the EP 0 214 806 A2. This favors a simple and inexpensive construction of the device for receiving or sending the electromagnetic vibration, as it is particularly preferred, for example is when the device according to the invention in the consumer goods sector, for example, as mobile communication device, in particular mobile phone or the like, use should find. The invention makes it possible in a simple manner in particular the interference from the operation of the device itself effectively reduce the immediate vicinity of the user's body parts. In particular, this ensures that when the Device according to the invention as a cell phone, for example, always at least one the conductor parts or the antenna element send electromagnetic vibrations or can receive them without the user's hand in particular be impaired in their function.

The device according to the invention achieves these advantages by moving away from that Principle as in the prior art according to EP 0 214 806 A2 Antenna element always radiating or emitting electromagnetic vibrations receiving component compared to one (housed in the device housing) operate electrically conductive ground plane. Rather, the rigid assignment certain electrical functions to individual components of the device are canceled; According to the invention, in addition to the antenna element, each of them basically also functions Conductor parts of the wave-guiding assemblies as a component for blasting or Picking up the electromagnetic vibrations. This can be done through the associated feed devices from the wave-guiding assemblies to the Configuration of antenna element and conductor parts delivered or added and then processed in at least two different ways and be evaluated. As a result, even in the event of malfunctions or unfavorable transmission or in particular reception conditions always at least one of the waveguiding An electromagnetic vibration in the assemblies for operation send or receive as required.

Preferably, the wave-guiding assemblies each include one Circuit arrangement for receiving and / or releasing the electromagnetic Vibration. These circuit arrangements can in particular transmit or Reception arrangements for the intended use of the device according to the invention, i.e. such components that this device anyway has to show. The shaft-guiding assemblies are therefore not components that are used for Reaching the function of the invention would have to be added. So can the wave-guiding assemblies after this development of the invention also in the prior art according to EP 0 214 806 A2 existing receiver and Stations included. Advantageously form the for receiving or delivering the electromagnetic vibration next to the antenna element, mentioned conductor parts of the individual wave-guiding assemblies each one common electrical conductor for that of the respective waveguiding Assembly included circuit arrangement. Preferred as these conductor parts Shields or ground surfaces of the wave-guiding assemblies are formed. There such shields and ground surfaces are always present, this results Formation of the device according to the invention without additional components.

In another embodiment of the device according to the invention, the conductor parts are of the individual wave-guiding assemblies and / or the associated Feeding devices for spreading linearly independent portions the electromagnetic vibration. Preferred are those in the individual wave-guiding assemblies spreading portions of the electromagnetic vibration substantially orthogonal to each other. Thereby can be achieved in the simplest way that when receiving a electromagnetic vibration regardless of the spatial position of the Device according to the invention always in at least one of the wave-guiding assemblies a portion of the received electromagnetic vibration occurs, so that a Reliable reception, especially in the example of a mobile phone, even with that freedom of movement is always guaranteed. Conversely, the Share of individual wave-guiding assemblies depending on their weighting to electromagnetic vibrations of different waveforms, in particular different polarizations, about merging the Feeding devices are superimposed in the connection point of the antenna element. Even if the operation with a plurality of antennas is preferred for the Reception of electromagnetic vibrations is provided, the majority of However, antennas in the device according to the invention are also used to for example, differently weighted depending on the spatial position of the device Parts of an electromagnetic vibration to a resulting one electromagnetic vibration to assemble one with respect to a spatially fixed coordinate system at least almost fixed waveform or Has polarization. This could make the design one of the The device emitted electromagnetic vibrations according to the invention receiving arrangement can be simplified.

In an advantageous development of the device according to the invention, I extend the conductor parts of the individual wave-guiding assemblies in their the waveform of the parts of the electromagnetic vibration spreading on them essentially defining sections orthogonal to each other. This will make the Orthogonality of the components of the electromagnetic vibration in the individual shaft-guiding assemblies reached.

To their function for sending and / or receiving the electromagnetic To be able to fulfill vibration in an advantageous manner, the conductor parts are in their Main dimensions on the wavelength of the electromagnetic vibration Voted. This coordination is also advantageous present tuning of the antenna element to the wavelength of the electromagnetic vibration. This will simplify the provision the dimensions of the conductor parts achieved in that their preference is preferred only on the wavelength of the electromagnetic vibration to be received he follows. Operation with a plurality of antennas is based on the more significant operation of receiving the electromagnetic Vibration limited.

Further advantageous embodiments of the device according to the invention are the See subclaims.

Fig. 1 ein erstes Ausführungsbeispiel eines erfindungsgemäßen Gerätes,

Figuren 2 bis 4 unterschiedliche Betriebsfälle des Gerätes nach Fig. 1 und

Figuren 5 und 6 zwei weitere Ausführungsbeispiele des erfindungsgemäßen Gerätes.

Some embodiments of the device according to the invention are shown in the drawing, in which corresponding elements are provided with the same reference numerals. Show

1 shows a first embodiment of a device according to the invention,

Figures 2 to 4 different operating cases of the device of FIG. 1 and

Figures 5 and 6 two further embodiments of the device according to the invention.

1 shows a first exemplary embodiment of the device according to the invention simplified arrangement in which in a substantially cuboid housing 1 of a preferably electrically insulating material, a first and a second wave-guiding assembly 2 and 3 are arranged. Each of the waveguiding For the sake of clarity, assemblies 2, 3 are only shown with one each Section of a coaxial cable with one outer conductor 4 or 5 and one each Inner conductor 6 or 7 shown and each with a coaxial high-frequency choke 8 and 9. The coaxial cables 4, 6 and 5, 7, in particular their inner conductors 6 and 7, form the feed devices of the wave-guiding assemblies 2 and 3 and are with each other and with an antenna element 10 at its connection point 11 connected. Except for this connection, the shaft-guiding assemblies 2, 3 are for the electromagnetic vibration to be picked up or emitted by them arranged isolated from each other. The outer conductor 43 or 5 of the coaxial cable form the conductor parts of the first and the second wave-guiding assembly 2 and 3, which conductor parts for picking up and / or emitting the electromagnetic Vibration in a manner that acts in a manner comparable to antenna element 10 are trained. The outer conductors 4, 5 can thus be compared to the Antenna element 10 emit an electromagnetic oscillation or take up. In the example in FIG. 1, they form rod-shaped antenna devices, whereas the antenna element 10 is helical (also referred to as a helix) is trained.

In Figure 1, the antenna element 10 and the first coaxial cable 4, 6 are the first arranged wave-guiding assembly 2 in a common direction, whereas the second coaxial cable 5, 7 of the second wave-guiding assembly 3 in one first section 12 perpendicular to the direction of the common axis of the Antenna element 10 and the first coaxial cable 4, 6 is guided. This first one Section 12 is one-sided with the connection point 11 via the inner conductor 7 connected and opens after an at least largely rectangular Line bend 13 in a second section 14, which is at least largely extends parallel to the axis of the first coaxial cable 4, 6. The sections of the Coaxial cables 4, 6 and 5, 7, which are for radiating or picking up used conductor parts of the wave-guiding assemblies 2 and 3 form limited by the coaxial high frequency chokes, which further spread the electromagnetic vibration on the outer conductors 4, 5 of the coaxial cable prevent. At the ends of the coaxial ends facing away from the antenna element 10 High-frequency chokes 8 and 9 open the coaxial cables 4, 6 and 5, 7 in Connection devices 15 and 16, for example coaxial connectors, for forwarding the electromagnetic vibration via the inner conductor 6 or 7 for Further processing or for supplying electromagnetic vibrations in Direction to junction 11.

Although the orientation of the device shown in Figure 1 in one The coordinate system fixed to the surroundings of this device can basically be any can, the orientation of the central axes of the antenna element 10, the first Coaxial cable 4, 6 of the second section 14 of the second coaxial cable 5, 7 as "vertical" and the orientation of the first section 12 of the second coaxial cable 5.7 referred to as "horizontal". This serves to simplify the following Description, however, means a limitation in the position of the device according to the invention in its environment.

Figure 2 shows a first operating case for the device of Figure 1 with one of this electromagnetic vibration to be received, its electrical Field vector E is aligned horizontally. The electromagnetic to be received Vibration is thus horizontally polarized. Through the electric field with the horizontal electric field vector E is on the outer conductor 5 of the second Coaxial cable 5, 7 induces a current I in its horizontal first section 12. The current I on the outer conductor 5 also calls a current on the inner conductor 7 of the second coaxial cable 5, 7. As a result, the second coaxial cable 5, 7 second wave-guiding assembly 3 generates an electromagnetic vibration. This is on the one hand by the second coaxial cable 5, 7 (on the inner conductor 7) supplied to the second connection device 15 and on the other hand calls currents I both on the antenna element 10 as well as on the first coaxial cable 4, 6, in particular on its inner conductor 6. So the first leads wave-guiding assembly 2 in this operating case an electromagnetic Vibration, which is on the inner conductor 6 in the direction of the first Connection device 16 and on the outer conductor 4 to the coaxial High-frequency choke 8 spreads. In Figure 2, however, is the better one For the sake of clarity, only the section from FIG. 1 is shown, which shows the directly surrounding the connection point 11 surrounding elements.

FIG. 3 shows a second representation corresponding to FIG. 2 Operating case with a vertically aligned electric field vector E, i.e. with a vertically polarized electromagnetic vibration to be received. This excites a current I in the antenna element 10 and on the outer conductor 4 of the first Coaxial cable 4, 6. Here again, a current from the outer conductor 4 is also on the Inner conductor 6 caused. With appropriate dimensioning of the Antenna element 10 and the first coaxial cable 4, 6 occurs in the case that as shown in Figure 3, the currents I on the inner conductor 6 and Antenna element 10 coincide with each other in amount and phase. It flows then, as indicated in Figure 3, no current in the inner conductor 7 of the second Coaxial cable 5, 7 in this mode with vertically polarized electromagnetic This vibration is then performed only in the first wave-guiding assembly 2.

The comparison of Figures 2 and 3 shows that in the illustrated Dimensioning and polarization of the electric field vector E the currents I flow in opposite directions in the first coaxial cable 4, 6. By an appropriate Linear combination of parts of the electromagnetic vibration with horizontal and vertical polarization, an operating case can be achieved that in Figure 4 is shown and in which the currents on the first coaxial cable 4, 6th cancel each other out. Then only one current I flows on the second Coaxial cable 5, 7 and the antenna element 10. The electric field vector E then takes a direction of polarization, as sketched in FIG. 4, between those of the operating cases of Figures 2 and 3, i.e. between the horizontal and vertical polarization.

The polarization in the operating case according to FIG. 4 is orthogonal to in the electrical sense the polarization in the operating case according to FIG. 3. For the definition of this Orthogonality is not the spatial orientation of the electric field vector E in decisive two spatially perpendicular directions, but rather the fact that in the operating case according to FIG. 3 the second coaxial cable 5, 7 and thus the second shaft-guiding assembly 3 and in the operating case according to FIG. 4 the first coaxial cable 4, 6 and thus the first wave-guiding assembly 2 without current are.

In general, it is not necessary, as in FIG. 3, for vertical Polarization of the currents on the first coaxial cable 4, 6 and on the Antenna element 10 are identical to each other to two operating cases with "orthogonal" Get alignment of induced currents. For creating two Operating cases in which only one of the shaft-guiding assemblies 2 or 3 receives a current induced by the electromagnetic vibration, it is only required that the vectors that flow into the the Represent feeders forming inner conductors 6 and 7, linear are independent of each other. This is also for a larger number of Feeding devices and thus shaft-guiding assemblies possible.

Figure 5 shows a second embodiment of the device according to the invention in schematic representation of the housing 1, the wave-guiding assemblies 2, 3 and of the antenna element 10. This becomes the radiation or for recording Conductor part of the first wave-guiding formed by electromagnetic vibrations Module 2 is formed by a conductive ground plane 40, which acts as a ground connection for a circuit arrangement 18 encompassed by the first wave-guiding assembly 2 serves. This circuit arrangement 18 and the conductive ground plane are corresponding 40 connected to each other by a connection 20. The circuit arrangement 18 is for picking up and / or emitting an electromagnetic vibration educated.

Correspondingly, this becomes the recording or radiation of an electromagnetic Vibration trained conductor part of the second wave-guiding assembly 3 through a conductive ground surface 50 is formed, which as a common ground line or Shielding for a circuit arrangement 17 for receiving and / or dispensing an electromagnetic vibration is provided. The circuit arrangement 17 is also part of the second wave-guiding assembly 3. The Circuit arrangement 17 and the conductive ground plane 50 are via the connection 19 conductively connected to each other.

Of the wave-guiding assemblies 2, 3 and there in particular of the Circuit arrangements 17, 18 each lead a feed device 60 or 70 to the Connection point 11 of the antenna element 10.

The conductive ground plane 40 of the first wave-guiding assembly 2 is in the example 5 aligned essentially vertically, whereas the conductive Ground surface 50 of the second wave-guiding assembly 3 is essentially horizontal is aligned. Correspondingly, 40 and 50 of these conductive ground surfaces essentially vertical (ground surface 40) or horizontal (ground surface 50) polarized electromagnetic vibrations recorded or radiated. Becomes uses the device of Figure 5 for example as a mobile phone, in which the Antenna element 10 in the usual position of use on the top of the housing 1 is arranged, the conductor part 50 of the second wave-guiding assembly is located 3 essentially in the upper part of the housing 1, whereas the conductor part 40 of the first wave-guiding assembly 2 essentially in the lower part of the Housing 1 is located. While these conductive ground surfaces 40, 50 as Stripline antennas act, the antenna element 10 is again in Figure 5 helical (as "helix"). The in the conductive ground plane 40 the first wave-guiding assembly 2 caused current when sending or Receiving an electromagnetic oscillation flows preferentially in the vertical Current in the ground surface 50 of the second wave-guiding assembly 3 preferably in horizontal direction. It becomes at least largely orthogonal parts of the electromagnetic vibration aligned with one another are sent or receive. Otherwise, the conductor parts 40 and 50 are just like that Coaxial cables 4, 6 and 5, 7 in Figure 1 spatially sufficiently far apart spaced so that currents in one of the conductor parts 40 and 50 are not in the other Head part are interspersed.

Both the conductor parts 40, 50 and also the coaxial cables 4, 6 preferably have or 5, 7 in Figure 1 and the antenna element 10 have an electrical length that at least largely a quarter of the wavelength of the to be transmitted or to receiving electromagnetic vibration. That’s why Main dimensions of the conductor parts 40, 50 largely predetermined.

Figure 6 shows a modification of the embodiment of Figure 5, in which the Conductor parts 40, 50 have a changed shape. In particular, the senior includes Ground surface 500, which replaces the conductive ground surface 50 in FIG. 5, one first section 120 in a horizontal orientation and a second section 140 in vertical orientation. The portions 120, 140 of the conductive ground plane 500 are corresponding to the line bend 13 from the embodiment of Figure 1 a bend 130 conductively connected to each other. The conductive ground plane 40 of the first wave-guiding assembly 2 corresponds to the second section 140 the conductive ground surface 50 recessed, so that their vertical orientation in essentially remains, but a horizontally aligned component accesses that in the "lower" part - facing away from the antenna element 10 - des Housing 1 can be found. The vertically oriented section of the conductor part 40 and the also vertically aligned second portion 140 of the conductive ground plane 50 are again appropriate to avoid mutual interference spaced.

The arrangement of the conductive ground surfaces 40, 500 sketched in FIG. 6 results in of the electromagnetic vibration to be transmitted or received so-called oblique polarization, which deviates from the "vertical" polarization.

When dimensioning the conductor parts of the shaft-guiding assemblies 2, 3, especially their vertically aligned sections, shows that their Size does not have a very critical influence on the function of the invention Device exercises.

Compared to a device according to the prior art, the Device according to the invention a training of the wave-guiding assemblies 2, 3 and the circuit arrangements 17, 18 included by them to provide the the electromagnetic vibration except for the connection via the Connection point 11 an electrical separation with respect to the to be sent or receiving electromagnetic vibration. any Circuit connections between the shaft-guiding assemblies 2, 3 must thus - except for the connection point 11 - for the electromagnetic vibration be impermeable. In practice, however, this means at most a minor one constructive additional effort.

For example, when using the device according to the invention as a mobile phone the electromagnetic oscillation is a useful signal, for example a speech signal. The wave-guiding assemblies 2, 3 and in particular those included by them Circuit arrangements 17, 18 are then used to obtain this useful signal formed when the wave-guiding assemblies 2, 3 for receiving the electromagnetic vibration via the associated feed devices 60, 70 are set up. As in Figure 6 through connections 170 (on 17) and 180 (on 18) is indicated schematically, the useful signal from the circuit arrangements 17 and 18 are provided for joint further processing in an assembly 190 become. In Figure 6, this assembly is in the area of space Ground surface 40 shown, it can be modified from the example Figure 6 can also be connected to the circuit arrangement 18 or spatially and with regard to the electromagnetic vibration also electrically from the shaft-guiding assemblies 2, 3 can be accommodated separately in the housing 1. At the Receiving the electromagnetic vibration via the antenna element 10 and the wave-guiding assemblies 2, 3, the circuit arrangements 17, 18 depending on spatial orientation of the device the useful signal in different Transmission quality, i.e. especially with different amplitudes provide. A preferably automatic selection can then be made in the assembly 190 take place in such a way that a useful signal of sufficient amplitude and also always sufficient signal-to-noise ratio is available. This is also called "antenna diversity" designated.

Conversely, in a device according to the invention in which the wave-guiding Modules 2, 3 for emitting one electromagnetic vibration each associated feed devices 60 and 70 are set up, at least a part of the wave-guiding assemblies for introducing a useful signal into the associated one be set up electromagnetic vibration. In the embodiment according to Figure 6, these are preferably both wave-guiding assemblies 2, 3, in which the Useful signal - preferably a voice signal - in an electromagnetic oscillation introduced, i.e. is modulated onto them. The so formed, the useful signal containing electromagnetic vibrations are from the wave-guiding Modules 2, 3 via the associated feed devices 60, 70 together Connection point 11 of the antenna element 10 is supplied. By controlling the Amplitudes and / or the phases of those containing the useful signal electromagnetic vibrations using the assembly 190 on the Connections 170 and 180 can then the polarization of the device of FIG. 6 transmitted electromagnetic vibration can be influenced.

In a modification of the exemplary embodiments according to FIGS. 1, 5 and 6, in the feed devices 60, 70 or inner conductors 6, 7 each have a switch inserted, through which the wave-guiding assemblies 2, 3 optionally from the connection point 11 can be electrically separated. For example, only one can thereby the wave-guiding assemblies 2, 3 optionally to the antenna element 10 be connected. Such switches can preferably be used as PIN diodes be carried out in the "longitudinal direction" into the feed devices 60, 70 or 6, 7 are inserted. In particular, these PIN diodes from the Circuit arrangements 17, 18 may be included. These circuit arrangements 17, 18th can then also contain control circuits with which the PIN diodes in Dependence on the amplitude of one of the associated waveguiding Module 2, 3 received electromagnetic vibration conductive or blocked can be switched. This control can optionally be done by the Assembly 190 are made.

In a modification of the galvanic connections shown in the figures wave-guiding assemblies 2, 3 with the antenna element 10 can also Connections via (small) impedances are used, for example about inductors or capacitors.

Claims (9)

1. A device for receiving and/or transmitting an electromagnetic wave,
   characterized by an antenna element (10) and at least two wave-guiding assemblies (2; 3) which are each connected to a connection point (11) of the antenna element (10) via a respective supply device (6, 60; 7, 70, respectively) and are in other respects arranged mutually insulated with respect to the electromagnetic wave, and which each comprise a conductor part (4, 40; 5, 50, 500, respectively) which in each of the wave-guiding assemblies (2; 3) is coupled to the associated supply device (6, 60; 7, 70, respectively) for transferring the electromagnetic wave, while the wave-guiding assemblies (2; 3) are designed for taking up and/or giving off the electromagnetic wave via the supply device (6, 60; 7, 70, respectively), and the conductor parts (4, 40; 5, 50, 500, respectively) are designed for taking up and/or radiating the electromagnetic wave in a manner similar to the manner in which the antenna element (10) operates.
2. A device as claimed in claim 1,
   characterized in that the wave-guiding assemblies (2; 3) each comprise a circuit arrangement (18; 17) for taking up and/or giving off the electromagnetic wave.
3. A device as claimed in claim 2,
   characterized in that said conductor parts (4, 40; 5, 50, 500, respectively) of the individual wave-guiding assemblies (2; 3) each constitute a common electrical conductor for the circuit arrangement forming part of the relevant wave-guiding assembly (2; 3).
4. A device as claimed in any one of the preceding claims,
   characterized in that the conductor parts (4, 40; 5, 50, 500, respectively) of the individual wave-guiding assemblies (2; 3) and/or the associated supply devices (6, 60; 7, 70, respectively) are designed for propagating portions of the electromagnetic wave which are linearly independent of one another.
5. A device as claimed in claim 4,
   characterized in that the portions of the electromagnetic wave propagated in the individual wave-guiding assemblies (2; 3) are substantially perpendicular to one another.
6. A device as claimed in claim 4 or 5,
   characterized in that the conductor parts (4, 40; 5, 50, 500, respectively) of the individual wave-guiding assemblies (2; 3) extend in mutually perpendicular directions with their portions which substantially define the waveform of the portions of the electromagnetic wave propagated therein.
7. A device as claimed in any one of the preceding claims,
   characterized in that the conductor parts (4, 40; 5, 50, 500, respectively) have main dimensions which are attuned to the wavelength of the electromagnetic wave.
8. A device as claimed in any one of the preceding claims, in which the wave-guiding assemblies (2; 3) are designed for receiving the electromagnetic wave through the associated supply devices (6, 60; 7, 70, respectively),
   characterized in that the electromagnetic wave contains a useful signal, the wave-guiding assemblies (2; 3) are constructed for capturing this useful signal, and at least a portion (190) of the wave-guiding assemblies (2; 3) is designed for making available the useful signal for a joint further processing thereof.
9. A device as claimed in any one of the claims 1 to 7, in which the wave-guiding assemblies (2; 3) are designed for each supplying an electromagnetic wave through the associated supply devices (6, 60; 7, 70, respectively),
   characterized in that at least part of the wave-guiding assemblies (2; 3) is designed for introducing a useful signal into the relevant electromagnetic wave, and the clectromagnetic waves thus formed and containing the useful signal are jointly supplied to the connection point (11) of the antenna element (10) by the wave-guiding assemblies (2; 3) via the associated supply devices (6, 60; 7, 70, respectively).

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