WO2004082072A1

WO2004082072A1 - Multirange antenna with terminal capacitance

Info

Publication number: WO2004082072A1
Application number: PCT/EP2004/002205
Authority: WO
Inventors: Siegfried Mathiae; Peter Karl Prassmayer; Frank Mierke
Original assignee: Kathrein-Werke Kg
Priority date: 2003-03-13
Filing date: 2004-03-04
Publication date: 2004-09-23
Also published as: DE10311040A1

Abstract

The invention relates to an improved antenna assembly which is characterised by the following properties. At least three antenna elements (7; 7a, 7b, 7c) are shifted with respect to each other and arranged on a plate-shaped substrate, Said antenna elements (7; 7a, 7b, 7c) are embodied in the form of striplines, fingers and/or line sections or the similar. The antenna elements (7; 7a, 7b, 7c) are electrically connected to at least one connection point by means of a junction (11). The antenna element (7b) is used for a superior frequency range. At least one other antenna element (7a, 7c) is used for an inferior frequency range and is arranged by the end thereof on the right-hand and left-hand sides of the antenna element (7b) for a superior frequency range. The two other antenna elements (7a, 7c) which are arranged on the right-hand side and/or left-hand sides of said antenna element (7b) are electrically connected to each other at the level of the sides or ends (107a, 107b) thereof in front of the junction (11).

Description

MULTI-BAND ANTEC WITH END CAPACITY

The invention relates to an antenna arrangement according to the preamble of claim 1.

Given the large number of different mobile radio frequencies used, it is known to provide at least two-band antennas for mobile radio antennas, in particular for the motor vehicle sector.

A dual-band antenna for the mobile area has become known, for example, from WO 99/04452. It u holds two rod-shaped radiator elements, which are offset from one another in the axial direction and are connected to one another by an inductance (coil) located between them. The ends of the rod-shaped radiator elements to be pointed towards one another, including the coil arranged between them, are fixed on the one hand by an inductance and on the other hand by an outer, surrounding conductive sheath. This results in an LC resonant circuit between the lower and upper radiator elements. By Corresponding tuning of the resonant circuit can ensure that in a low frequency range the entire radiator device with two radiator elements arranged offset in the axial direction serves as an antenna, whereas due to the blocking effect of the LC resonant circuit in a higher frequency band only the lower radiator element with its corresponding one Length is effective. In a higher frequency band range, reception or transmission is only carried out via the radiator element located below.

However, the antenna nevertheless has a comparatively large overall height, which is why it appears less suitable, in particular, as a low-profile mobile radio antenna that can be attached to the outside of motor vehicles. In addition, this antenna principle is limited to a dual-band antenna and cannot be expanded in the sense of a multi-band antenna, by means of which three or four different band ranges can be received, for example. In general, the bandwidth of this antenna must therefore be in many. Cases are not adequately assessed.

An antenna arrangement has also become known, for example, from DE 201 11 229 U1. In this prior publication, an antenna arrangement for motor vehicles is described, which has a chassis, above which a printed circuit board is arranged, to accommodate circuit components. One or more vertically projecting and at least partially flat antenna elements are provided vertically to the essentially horizontally oriented line board, specifically for receiving different services or for the mobile radio range in different frequency bands. The entire antenna arrangement is covered by a hood, which can have a fin-like shape. Such antennas are usually attached to the motor vehicle body sheet, for example at the transition from the motor vehicle roof to the rear window.

In addition, antenna arrangements have also become known in which, based on a more or less horizontal chassis, the aforementioned printed circuit board with the circuit-electronic components, filter assemblies etc. is initially provided, and the antenna elements are in turn positioned perpendicularly to it in the vertical direction. For example, these may not only consist of metallically conductive self-supporting emitter devices, but also again, for example, of a printed circuit board element, i.e. generally made of a dielectric material on which metallized surfaces are formed to form the radiators.

If only one frequency band is to be received, a radiator element is sufficient. If several services are to be implemented, or if, for example, communication is to be made possible in different frequency bands in the mobile radio range, then a plurality of radiators or planar antenna elements which are offset from one another are naturally provided.

Finally, a car radio antenna has also become known, which can be accommodated in a fin-like housing which, in addition to a horizontal base with a printed circuit board with corresponding electrical assemblies, has a vertical board seated thereon on which an antenna monopole is comparable in electrical terms conductive surface elements are formed. An inductance is provided between an upper and a lower radiator element. This is a two-band antenna, which, however, again does not have the desired bandwidth and does not have the desired antenna gain in the entire bandwidth and, if this is a requirement, also allows a comparatively very low overall height.

A generic antenna is known for example from DE 102 08 210 AI.

An antenna arrangement has also become known from DE 44 23 191 AI. It shows, for example, three antenna antenna elements which are arranged next to one another and which are galvanically connected via a junction for transmitting the received and / or transmitted signals.

The object of the present invention is to provide an improved mobile radio antenna, at least in the form of a two-band or preferably in the form of a multi-band antenna, which basically has a high antenna gain and, above all, an improved omnidirectional characteristic and / or should show improved broadband. The antenna arrangement should preferably be constructed as space-saving as possible.

The object is achieved according to the features specified in claims 1 and 8, respectively. Advantageous embodiments of the invention are specified in the subclaims. The present invention proposes a multi-band antenna for mobile use, in particular as a motor vehicle antenna, which has a high antenna gain and, above all, a high omnidirectional characteristic and a high bandwidth. With the antenna according to the invention, it is easily possible to design or adapt it in such a way that virtually any or almost any desired bandwidth or multi-band capability can be implemented.

According to the invention, this can be realized in particular in that a central antenna element is provided for an upper frequency band in the case of an antenna arrangement having at least three antenna radiating elements, and that, viewed in side view, a further antenna element for a lower frequency band is provided on the left and on the right of it , All three antenna elements are preferably electrically connected at the bottom with a junction. The peculiarity of improving the omnidirectional properties in particular is that the two outer antenna radiating elements are also electrically connected to one another on their upper side (ie opposite to the common electrical junction) without contacting the central antenna radiating element (which is preferably of shortened design). It is more than surprising that this enables an improved omnidirectional property to be achieved.

The aforementioned electrical connection between the upper ends of the outer antenna radiating elements is preferably designed in the form of a roof capacitance, which preferably has a greater width in the transverse direction than the width of the individual antenna radiating elements. An improved multi-band antenna can, however, also be realized according to a secondary solution according to claim 8 in that the multi-band antenna has at least two antenna elements, the one antenna antenna element being connected to the electrical junction with a parallel or LC resonant circuit is, the at least second antenna antenna element can also be connected inductively via a coil or electrically-galvanically to the junction.

In a preferred embodiment, however, at least three antenna radiating elements are also provided in this case, which are not all connected in the same way to the electrical junction.

The antenna according to the invention can thus generally be constructed in such a way that strip or monopole-like conductor structures are used on an at least approximately vertically oriented substrate, preferably in the form of a printed circuit board, which serve as radiator elements. These are connected to a connection via a junction. The two, three or more radiator elements, which are approximately preferably finger-shaped in side view, can be adapted to the desired broadband or to the desired frequencies or frequency bands to be transmitted such that, for example, at least one finger-shaped radiator element is galvanically connected to the junction and that at least one further radiator element consists of an inductively extended stub. By using the inductance, it is known that the corresponding radiator element can be lengthened, so that a lower one Frequency band can be received.

A plurality of radiator elements in the form of fingers, strips or stubs are therefore preferably provided, which preferably sit next to one another in a parallel orientation and can preferably also be provided with a whip-shaped or oblique or roof-shaped angled shape in their upper region in order to reduce the overall height.

The already mentioned preferably provided roof capacitance can be used additionally or alternatively for the electrical connection of a radiator element via an inductor or an LC resonant circuit at its base point. By using the roof capacity, the mechanical dimensions of the antenna can be further reduced.

In a preferred embodiment, the inductor for achieving an inductively elongated stub line is likewise designed as a printed coil on the substrate, preferably in the form of the printed circuit board.

In a further development of the invention it is provided that the parallel resonant circuit is likewise formed from a printed capacitance and a printed coil. However, discrete components for the capacitance and the coil can also be used here (even if the printed embodiment is preferred).

Finally, a further fine-tuning and adjustment can take place in that the stripline-shaped, ie the finger- or stub-line-shaped radiator elements are not only on one side of the substrate, ie the plate-shaped, preferably in the manner of a printed circuit board trained substrate are provided, but are formed in side view preferably congruent or overlapping one behind the other on both sides, ie on both surfaces of the substrate.

Depending on the design and adaptation of the corresponding radiator element, the radiator elements provided on both surface sides of the substrate can be plated through using several through-holes in the substrate, so that there is a galvanic connection between the two line sections on the two opposite upper sides of the antenna radiator element. The corresponding radiator elements for lower frequency band ranges can be provided without such plated-through holes. The desired capacitance of using an LC circuit can also be formed, for example, by the fact that the two preferably identical or at least partially overlapping stripe line sections are not plated through on the two opposite surfaces of the substrate of a specific antenna radiator.

The present antenna arrangement has the essential advantage that on the one hand a large bandwidth can be achieved with a good antenna gain at the same time, and this despite the fact that the antenna arrangement is optimized with respect to the installation space and the manufacturing costs compared to conventional solutions.

The invention is explained in more detail below on the basis of exemplary embodiments. The following show in detail: FIG. 1: a partially schematic representation of an antenna arrangement according to the invention with a base and a printed circuit board underneath and a vertically plugged-in substrate with three radiating elements;

FIG. 2: an antenna arrangement simplified compared to FIG. 1;

Figure 3: another schematic embodiment of a multi-band antenna arrangement showing one side of the substrate carrying the radiator elements;

FIG. 4 shows the corresponding rear side to the representation according to FIG. 3 in the correct representation of FIG. 3;

FIG. 5 shows a further modified exemplary embodiment with two separate, jointly fed resonators with a large roof capacity; and

FIG. 6: a design of the antenna device similar to FIG. 5 with longer radiators and a shortened roof capacity.

FIG. 1 shows a first exemplary embodiment of a multi-band antenna according to the invention, ie a three-band antenna, partly in a schematic perspective illustration. In the exemplary embodiment shown, the antenna has an antenna device 1 which comprises a plate-shaped substrate 3, for example in the form of a printed circuit board 3 ', on which the stripline, finger-shaped or stub line-like antenna radiator elements 7 which are at least approximately planar in the exemplary embodiment shown are formed.

These are arranged essentially parallel and with a lateral offset to one another, at least with a lower antenna radiator section 7 ', to which, in contrast, in each case are connected upper antenna radiator sections 7 "which run at an angle or inclination. The overall height can thereby be further reduced.

The antenna radiating elements 7 are connected via a junction 11 located at the bottom to transverse junction sections 11a and / or vertically extending junction sections 11b, which enable an electrical connection to a connection point 15 located below.

The antenna device formed in this way then sits on a base plate 17 which is arranged at the bottom and is generally arranged more horizontally, with a base circuit board 19 on which the further required electronic and / or electrical components and structural components, which are shown in the exemplary embodiment shown in FIG. 1, are usually accommodated and 2 are not reproduced for the sake of better illustration. The underlying base plate 17 is also used to hold a housing cover, not shown, which can be designed like a fin. This fin-like design is given above all by the plate-shaped design of the antenna device 1.

In the exemplary embodiment shown in FIG. 1, the antenna antenna element 7a on the left is designed, for example, as a conductive, clad copper layer on the substrate 3, the antenna antenna element 7a thus formed being continuously conductive, that is to say electrically connected to the junction 11.

In the exemplary embodiment shown, the antenna antenna element 7b lying in the middle is separated from the junction 11 at the bottom by a groove-shaped interruption 21 ', that is to say a slot-shaped interruption. A printed coil 23 for the parallel resonant circuit serves as a bridge for the electrical connection between the antenna radiating element 7b thus formed and the junction 11. The groove-shaped interruption 21 results in a printed capacitance 21, so that a parallel resonant circuit (LC resonant circuit) is generated by the printed capacitance and the printed coil.

Finally, the third antenna radiating element 7c shown on the right in FIG. 1 is connected to the junction 11 by means of a printed coil 24, that is to say inductively.

Both in the antenna radiating element 7b and in the antenna radiating element 7c, discrete components, that is to say both a capacitor and a coil, can be fitted instead of the printed components. However, this requires more installation space, is more expensive and has the disadvantage that, especially in the case of small-sized capacitors Tolerances are larger than in the case of a printed capacity that can be implemented inexpensively.

With the so formed. The left antenna antenna element 7a serves, for example, for an upper frequency band, the antenna antenna element 7c for transmission in a lower frequency band and the central antenna antenna element 7b connected via the LC resonant circuit 21, 23 for transmission both in the upper and in the lower frequency band.

By using the above-mentioned inductors, the entire antenna arrangement can be shortened, so an electrically effective extension for reception in a lower frequency band is realized with antenna antenna elements that are relatively short in length.

Finally, FIG. 1 also shows that the printed circuit board does not have to be rectangular, but can be adapted to the antenna device 1, i.e. can be adapted in particular to the antenna radiating elements 7a to 7c. In addition, the substrate can be provided with openings 25. Crosspieces 25 'serve to increase the stability if such openings 25 are provided.

Regarding FIG. 1, it is also noted that the resonant frequency of the resonant circuit. For example, it is set to 1300 MHz. This electrically lengthens the middle radiator in the lower frequency band and shortens it in the upper frequency band. A double resonator is thus obtained. The bandwidth is increased again by the two auxiliary resonators on the side. The embodiment according to FIG. 2 is a broadband antenna, preferably for a dual band range. Two antenna radiating elements 7b and 7c are provided here, in each of which the radiating elements 7b and 7c are connected to the junction 11 by means of an LC resonant circuit, for which purpose both the coil 23 and the capacitance 21 in printed form in this exemplary embodiment is formed on the substrate, ie in the printed circuit board. The resonance frequency of the resonant circuits is set to 1300 MHz, for example. This electrically lengthens the radiator in the lower frequency band and shortens it in the upper. This results in two double resonators, ^• which are offset in frequency due to different mechanical dimensions, which can increase the bandwidth. In this exemplary embodiment, the webs 25 'serve to improve the mechanical stability and the joint merging 11, 11a, 11b serves to achieve an improved return loss. Otherwise the structure is comparable.

A further exemplary embodiment is finally explained on the basis of FIGS. 3 and 4, which is basically of a similar construction. For the sake of better representation, the base plate or the chassis 17 with a base printed circuit board 19 usually provided thereon for receiving the required electrical and / or electronic assemblies and components is not shown in FIG.

FIG. 3 shows the antenna device 1 with the vertically arranged substrate 3 in one side view, the rear design of the antenna radiating elements and the merging 11 being shown in FIG. is shown, and that in a representation that results quasi with a transparent design of the substrate 3 with omission of the antenna antenna elements on the upper level.

It can be seen from this that the galvanically connected antenna radiating element 7a is designed to be on the right for the upper frequency band range, that the middle antenna radiating element 7b is again electrically connected to the junction 11, forming an LC resonant circuit (capacitance 21, inductance 23), and that the one on the left Antenna radiator element 7c is in turn connected to the junction via a printed inductor for the lower band.

The junction 11 is formed on the one side 3 'of the substrate 3 in the form of a junction section 11' which is reduced in area so that the printed components in the form of the inductors 23, 24 can be accommodated.

On the opposite, ie rear side 3 'of the substrate 3, the merging 11 is in the form of a merging section 11 "with a larger area extension, but essentially congruent with the merging 11' at the top of the front.

The junction 11 ', 11' 'on both sides of the substrate is electrically connected to one another by a large number of bores 27 which are electrically contacted.

Congruent with the antenna antenna elements 7a-7c visible in FIG. 3 are at least partially With the antenna antenna elements 7a-7c formed on the front side, further antenna antenna elements 7a ', 7b', 7c 'are provided, with the antenna element 7a and 7c likewise having a large number of bores 29 drilled through the substrate in order to to make contact. Therefore, the antenna radiating element 7a and 7a 'and the antenna radiating element 7c and 7c' are electrically connected to each other through the through-hole via the holes 29.

The capacitive coupling of the LC resonant circuit for the central antenna radiating element 7b, 7b 'is in turn formed in that on one side 3' of the substrate 3 the antenna radiating element 7b via the inductance 23 and via a plated-through hole 30 with that on the rear Side 3 "of the junction 11" located on the substrate 3 is electrically connected, the parts of the junction 11 ', 11 "located on the front and the back of the substrate 3 being electrically galvanically connected by the plurality of bores 27 provided there. From FIG 3 and FIG. 4 it can also be seen that the end of the radiator element 7b located on the front 3 'of the substrate, which is adjacent to the inductance 23, is only separated from the antenna radiator element 7b' by the substrate, as a result of which the capacitance is separated by the entire length of the radiator sections 7b and 7b 'formed on both sides of the substrate 3. Dadurc h, a capacitance 21 is additionally generated, which together with the inductor 23 forms the LC resonant circuit. The front and the rear antenna radiating element 7b and 7b 'have no bore and are therefore not designed to be electrically-galvanically connected due to the lack of a through-connection, so that the coupling of the Radiator element 7b located on the front 3 'of the substrate 3 is only connected to the junction 11 via the LC resonant circuit, whereas the radiator element 7b' located on the rear is electrically-galvanically connected to the junction 11, 11 ".

From the consideration of the front and back of the antenna device according to FIG. 3 and FIG. 4 it can also be seen that the radiator element 7c 'on the rear side 3 "of the substrate 3 is electrically conductively separated from the junction 11. On the front 3' of the Substrate 3 is the associated part 7c of this antenna radiating element via • the aforementioned inductance 24 in the form of a printed coil and a plated-through hole 30 directly electrically connected to the junction 11, 11 "provided on the rear side 3" in an electrically conductive (galvanic) manner The part of the antenna element 7c, 7c 'located on the front and the back of the substrate 3 are electrically conductively connected to one another by a large number of plated-through holes 29, so that this element 7c is only electrically connected to the junction 11 via the coil 24 mentioned communicates.

A further fine adjustment and adaptation can be ensured, for example, by designing the antenna antenna elements 7b and 7b 'in different lengths in the middle antenna antenna element 7b and 7b'. For this purpose, it can be seen from FIG. 3 that the middle finger-shaped emitter or resonance element 7b still has an upper-lying, right-angled bend 7 ″ b, whereas on the opposite side the middle emitter element 7b ′ does not have this angled extension , With reference to the exemplary embodiment according to FIGS. 3 and 4, it is also shown that here the substrate is designed in a side view in the manner of an inverted U with the formation of a large central recess 35 '. A monopole-like stripline section 7d of suitable length is also formed on the section on the right, for example for the DAB-L band or for receiving the terrestrial SDARS band. This results in a second connection point 15 'for connecting this radiator 7d.

On the basis of the further FIGS. 5 and 6, it should be shown that, with regard to the antennas explained with reference to FIGS. 1 to 4, an additional or alternative implementation of so-called roof capacities connecting the outer antenna radiating elements still improves the antenna gain and in some cases also the roundness of the antenna Radiation diagram.It is possible.

The exemplary embodiments 5 and 6 relate to an antenna with three antenna radiating elements 7a-7c plus a roof capacitance 37. The central antenna radiating element 7b is somewhat shortened in vertical extension compared to the other two external radiating elements 7a and 7c. All radiator elements 7a-7c are electrically connected to one another via the junction 11. The upper ends 107c and 107a of the outside radiator elements 7a, 7c are electrically connected to a roof capacitance 37 which also projects laterally beyond the entire radiator arrangement and which has a significantly greater transverse extent 37 'than the transverse width of the individual radiator elements 7.

The exemplary embodiment according to FIG. 6 differs from that according to FIG. 5 only by a different geometrical dimension, in which the roof capacity 37 has a shorter transverse extension length and the vertical height of the outside radiator elements 7a, 7c is greater and the central radiator element 7b is significantly higher than in the exemplary embodiment according to Figure 5.

The antenna explained creates two separate resonators which are fed together. The resonator for the lower frequency band is symmetrical and designed as a monopoly for the upper frequency band. The roof capacity again serves to extend the monopoly for the lower frequency band. This means that there is practically no out-of-roundness in the radiation diagram. In addition, the overall antenna arrangement is very broadband in the lower frequency band range. Finally, a high antenna gain can also be achieved here. This is bought by the monopole's somewhat higher space requirements for the lower frequency band.

The exemplary embodiments of the additionally provided roof capacity explain the possibility of electrically extending the antenna or the antenna elements. It is basically known that the resonance frequency of a monopoly is indirectly proportional to its length. An electrical extension of the antenna means that the length of the antenna is shorter than the desired resonance frequency would require. A special arrangement then ensures that the antenna is still resonating at the desired frequency. This is understood as an "electrical extension" on an antenna.

Possibilities of electrically extending an antenna are possible through the following measures:

a) A coil is provided at the base of the antenna (If an antenna is shortened, its input impedance is capacitive. To compensate for this reactive component, an inductive component, ie coil, must be installed in series with the antenna).

b) A capacity is provided at the end of the antenna, for example in the form of the roof capacities explained (the roof capacity stores additional charge carriers at the upper end of the monopoly, so that a fourth of a sinusoid fits the monopoly in the current distribution. In the case of capacitive extension, the antenna is somewhat broader than with inductive).

c) A dielectric is provided around the antenna (the wavelength in a dielectric is smaller than in free space. If a dielectric is now placed around the antenna, its resonance frequency is lower than in air. The antenna can thus be made mechanically shorter, to get to the same resonance frequency).

Claims

Claims:

1. Antenna arrangement, in particular for motor vehicles, preferably for attachment to a body surface, with the following features:

- with a mounting base (17),

with a printed circuit board (19) for accommodating electrical assemblies and structural components, in particular a possibly provided high-frequency circuit for the antenna antenna elements (7; 7a, 7b, 7c) provided,

with a preferably plate-shaped substrate (3), which is preferably aligned lying in a vertical plane,

- On the plate-shaped substrate (3) at least three staggered antenna antenna elements (7; 7a, 7b, 7c) are provided, - The antenna antenna elements (7; 7a, 7b, 7c) are stripline, finger and / or branch line-shaped or similarly trained,

- The two antenna radiator elements (7; 7a, 7b, 7c) are electrically connected to at least one connection point (15) via a junction (11; 11 ', 11''), characterized by the following further features: it is an antenna radiator element ( 7b) provided for an upper frequency band, at least one further antenna radiating element (7a, 7c) for a lower frequency band is arranged to the left and one to the right of the antenna radiating element (7b) for the upper frequency band, and the two to the left and right of the antenna radiating element (7b ) arranged further antenna radiating elements (7a, 7c) are electrically connected to each other on their opposite side or ends (107a, 107c) for merging (11; 11 ', 11 ").

2. Antenna arrangement according to claim 1, characterized in that the central antenna radiating element (7b) is shortened compared to the two outer antenna radiating elements (7a, 7c).

3. Antenna arrangement according to claim 1 or 2, characterized in that the two outer antenna radiating elements (7a, 7c) electrically via a straight line on their opposite side for merging (11; 11 ', 11 ") or ends (107a, 107c) are interconnected.

4. Antenna arrangement according to one of claims 1 to 3, characterized in that the upper ends (107a, 107c) of the external antenna radiator elements (7a, 7c) are electrically connected to a roof capacity (37) which also projects laterally from the entire antenna array.

5. Antenna arrangement according to claim 4, characterized in that the roof capacity (37) has a significantly greater transverse extent (37 ') from the transverse width of the individual radiator elements (7).

6. Antenna arrangement according to one of claims 1 to 5, characterized in that the two outer antenna antenna elements (7a, 7c) are arranged symmetrically left and right to the antenna antenna element (7b) provided in the middle.

7. Antenna arrangement according to claim 5 or 6, characterized in that the roof capacitance (37) is arranged symmetrically to a plane of symmetry running through the central antenna radiating element (7b).

8. Antenna arrangement, in particular for motor vehicles, preferably for attachment to a body surface, with the following features: with a mounting base (17),

at least two antenna radiating elements (7; 7a, 7b, 7c) are provided on the plate-shaped substrate (3),

- The antenna radiator elements (7; 7a, 7b, 7c) are strip-line, finger and / or branch line-shaped or similar, - The two antenna radiator elements (7; 7a, 7b, 7c) are merged (11; 11 ', 11'') electrically connected to at least one connection point (15), characterized by the following further features at least one antenna radiating element (7; 7b, 7c) is provided which is electrically connected to the at least one connection point (15) by means of a parallel or LC resonant circuit via the junction (11; 11 ', 11 ") is connected, and at least one second antenna radiating element (7a, 7b, 7c) is provided, which either (a) electrically-galvanically, or (b) inductively via a coil (24), or

(c) is electrically connected to the at least one connection point (15) via a parallel or LC resonant circuit via the junction (11; 11 ', 11 ").

9. Antenna arrangement according to claim 8, characterized in that the antenna arrangement comprises two antenna radiating elements (7; 7b, 7c), both of which are connected to the junction (11; 11 ', 11 ") via a parallel or LC resonant circuit.

10. Antenna arrangement according to claim 8, characterized in that at least three antenna radiating elements (7; 7a, 7b, 7c) are connected, of which at least one antenna radiating element (7a) differs from the remaining radiating elements (7b, 7c) with the merging ( 11; 11 ', 11 ") is electrically-galvanically connected.

11. Antenna arrangement according to claim 8 or 10, characterized in that in the case of a plurality of antenna radiating elements (7; 7a, 7b, 7c) each of the antenna radiating elements (7; 7a, 7b, 7c) is electrically connected differently to the junction (11).

12. Antenna arrangement according to one of claims 1 to 11, characterized in that the inductor (23) is designed as a printed component from the substrate (3).

13. Antenna arrangement according to one of claims 1 to 12, characterized in that the capacitance (21) of the LC resonant circuit is formed in printed form.

14. Antenna arrangement according to one of claims 1 to 11, characterized in that the inductance and / or

Capacity is provided as a discrete component.

15. Antenna arrangement according to one of claims 1 to 14, characterized gekennseichnet that at least one antenna radiating element (7c) is electrically extended using a base inductance for receiving lower frequency bands.

16. Antenna arrangement according to one of claims 1 to 15, characterized in that the antenna radiating elements

(7; 7a, 7b, 7c) have a first antenna radiator section on one side of the substrate (3) and an antenna radiator section (7a ', 7b', 7c ') on the opposite rear side of the antenna radiator element.

17. Antenna arrangement according to claim 16, characterized in that at least one antenna radiating element (7a, 7c) with another on the opposite side of the substrate (3) formed second part of the antenna radiating element (7a ', 7c') is electrically connected, each of which Associated antenna antenna elements arranged on both sides of the substrate (3) elements (7a, 7a '; 7c, 7c') are electrically galvanically connected through at least one and preferably a plurality of plated-through holes (29) through the substrate (3).

18. Antenna arrangement according to one of claims 1 to 17, characterized in that the antenna radiating element

(7b), which is connected to the. Via an LC resonant circuit (21, 23)

Junction (11) is electrically connected, an associated second part of an antenna radiating element

(7b ') is assigned, which is electrically, preferably electrically-galvanically, connected to the junction (11') located on the rear.

19. Antenna arrangement according to claim 18, characterized in that the parts of the antenna radiating element (7b, 7b ') provided on the front and back of the substrate (3) are not electrically connected.

20. Antenna arrangement according to one of claims 1 to 19, characterized in that at least one further antenna radiating element (7d) in the form of a preferably straight or monopole-extending finger, strip line and / or stub line-shaped radiator with a bottom one Connection point (15 ') is provided.

21. Antenna arrangement according to one of claims 1 to 20, characterized in that the axial length of the roof capacitance (37) is greater than the maximum lateral distance of the outermost antenna radiating elements (7; 7a, 7c).

22. Antenna arrangement according to one of claims 1 to 21, characterized in that the roof capacitance (37) is shortened and is connected via an intermediate section (107b) to the end (107a) of an antenna radiating element (7a).

23. Antenna arrangement according to one of claims 1 to 22, characterized in that the roof capacitance (37) is formed on both sides of a substrate (3) and is preferably electrically connected to one another via plated-through holes.

24. Antenna arrangement according to one of claims 1 to 23, characterized in that the roof capacity (37) has a transverse dimension that is significantly larger than the width dimension of the antenna radiating elements (7; 7a, 7b, 7c).

25. Antenna arrangement according to one of claims 1 to 24, characterized in that the roof capacity (37)

Has cross-sectional dimension, which has in the order of magnitude of the cross-sectional dimension for the individual antenna radiating elements (7; 7a, 7b, 7c).

26. Antenna arrangement according to one of claims 1 to 25, characterized in that an antenna radiating element (7b) is provided for the upper frequency band, and that for this purpose symmetrically left and right two separate antenna radiators (7a, 7c) are arranged, which are for the lower frequency band are provided, which are connected together with the merging (11).