EP1239543A1 - Flat antenna for the mobil satellite communication - Google Patents

Abstract

The invention relates to an antenna for mobile satellite communication on a substantially horizontally oriented conductive base area (1), consisting of essentially linear conductor parts (4) and an antenna connection point (5). It consists of conductor parts with a substantial vertical extension (4a) and conductor parts with a substantial horizontal extension (4b), which together with the conductive base area (1) form a high-frequency conductive ring structure (2). The conductor parts are guided essentially in a plane (0) perpendicular to the conductive base area (1), one of the conductor parts with a substantial vertical extension (4a) or one of the conductor parts with a substantial horizontal extension (4b) to form the antenna connection point (5). is interrupted and by interrupting one of the conductor parts at least one impedance connection point (6) connected with an impedance (7) is present and the positions of the impedance connection point (6) and the antenna connection point (5) and the impedance (7) are selected such that for the In the plane (0) standing perpendicular to the conductive base surface (1) with waves polarized in this plane, the predetermined antenna gain values are set for predetermined elevation angles (81) of the wave incidence (80) (FIG. 1). <IMAGE>

Description

The invention relates to an antenna for mobile satellite communication on an in essentially horizontally oriented conductive base consisting essentially of linear conductor parts and an antenna connection point. Antennas of this type are known from DE 40 08 505.8. This antenna consists of crossed horizontal dipoles with a V-shape Dipole halves inclined at the bottom, consisting of linear conductor parts, at an angle mechanically fixed at 90 degrees to each other and at the top one on a horizontal Oriented conductive base fixed linear vertical conductor are attached.

To generate the circular polarization usually required for satellite communication the horizontal dipoles that are inclined downwards in a V-shape become electrical interconnected over a 90 degree phase network. For satellite antennas depending on Satellite communication system is in the elevation angle range between 25 and 30 degrees and 90 degrees an antenna gain of constant 3dBi for circular polarization strictly required. Antennas of this type can be used to meet the requirements in the area of the zenith angle Realize antenna gain in general without problems. In contrast, the required antenna gain in the range of low elevation angles of 20 to 30 degrees only heavy and due to the V-shaped horizontal dipoles, which are inclined downwards Function naturally a sufficiently large distance from the conductive base demand, in no case - as required for mobile use - with a very small height of the Antennas can be realized.

It is also known to meet the winning requirements both in the angular range low elevation as well as antennas bent from linear conductors with steep radiation use. The antenna form that is frequently used today is the quadrifilar helix antenna Kilgus (IEEE Transactions on Antennas and Propagation, 1976, pp.238-241). Such Antennas are often several wavelengths long and are not flat antennas known with low height. Also with an antenna specified in EP 0 952 625 A2 With a low overall height, the above-mentioned gain values can be used in the angular range not meet lower elevation.

The invention is therefore based on the object of first specifying an antenna which it allows the ratio of antenna gain in the low elevation range to antenna gain in the zenith angle range in an azimuthal main plane as required and which enables a directional diagram by combining several such antennas according to the gain requirements for circular polarized satellite communications Realize waves with a small electrical height of the antenna.

This task is performed by an antenna according to the preamble of the main claim characterizing features of the main claim and those proposed in the further claims Measures solved.

Antennas according to the invention can in particular in their training form for satellite communication can be produced particularly easily and therefore inexpensively. Also suitable due to their structure over a conductive base and their small size Height especially for use on vehicles. Another advantage is that they can be extended to the combination antenna for terrestrial communication, what with the saving of installation space in motor vehicles goes hand in hand. Another advantage is there that measures can be taken to ensure that in the presence of Discontinuities in the conductive base surface or in its skew, such as roof pitch or roof edge, the disturbance of the directional diagram resulting therefrom can be largely offset.

Fig. 1: Prinzip einer Antenne nach der Erfindung mit einer hochfrequent leitenden Ringstruktur 2, gebildet aus im wesentlichen vertikalen Leiterteilen 4a und im wesentlichen horizontalen Leiterteilen 4b und der leitenden Grundebene 1.

Fig. 2: Prinzip einer Antenne nach der Erfindung mit einseitiger Auskopplung an der Antennenanschlußstelle 5.

Fig. 3a: Symmetrische Antenne einer Antenne nach der Erfindung mit den Antennenanschlußstellen 5 und 5' und einem Umsymmetriernetzwerk 9, gebildet aus unsymmetrischen Leitungen 10a und 10b.

Fig. 3b: Symmetrische Antenne nach der Erfindung mit einem Umsymmetriernetzwerk 9, gebildet aus unsymmetrischen Leitungen 10a und 10b, deren Länge sich um ein ungeradzahliges Vielfaches der halben Betriebswellenlänge unterscheidet.

Fig. 3c: Symmetrische Antenne nach der Erfindung mit einem Umsymmetriernetzwerk 9 nach dem transormatorischen Prinzip zur getrennten unsymmetrischen Auskopplung der symmetrischen und der unsymmetrischen Spannungen

Fig. 4a: Symmetrische Antenne nach der Erfindung, bei der die Antennenanschlußstelle 5 im Bereich der Symmetrieachse 8 der Antenne angeordnet ist und bei der die Signale mittels einer symmetrischen Zweidrahtleitung nach unten geführt sind.

Fig. 4b: Detail aus Fig. 4a.

Fig. 4c: Detail aus Fig. 4a, aber mit einer geschirmten Zweidrahtleitung.

Fig. 4d: Antenne nach der Erfindung ähnlich Fig. 4a, jedoch mit zwei Koaxialleitungen an Stelle der Zweidrahtleitung und mit einem Umsymmetriernetzwerk 9 nach dem transformatorischen Prinzip zur getrennten unsymmetrischen Auskopplung der symmetrischen und der unsymmetrischen Spannungen.

Fig. 5: Antenne nach der Erfindung mit Bemassungsangaben und mit einem Anpaßnetzwerk 17.

Fig. 6a: Antenne für Zirkularpolarisation, gebildet aus zwei Antennen nach der Erfindung in aufeinander senkrecht stehenden Ebenen, deren Ausgangssignale über ein 90-Grad Phasendrehglied 18 in einer Summationsschaltung 19 zusammengefaßt sind.

Fig. 6b: Beispiel für ein Streifenleitungslayout für die Antenne nach Fig. 6a.

Fig. 6c: Räumliche Darstellung der Antenne für Zirkularpolarisation.

Fig. 7: Antenne für Zirkularpolarisation, gebildet aus drei Antennen nach der Erfindung in drei Ebenen, die azimutal in 120°-Winkeln angeordnet sind, deren Ausgangssignale über 120-Grad Phasendrehglieder 18 in einer Summationsschaltung 19 zusammengefaßt sind.

Fig. 8: Antenne für Zirkularpolarisation nach Fig. 7, bei der der vertikale Leiter 4a' im Symmetriepunkt der Anordnung entfällt.

Fig. 9a: Antenne nach der Erfindung mit einem weiteren Anschlußtor Tu zur Auskopplung einer unsymmetrischen Spannung.

Fig. 9b: Prinzip der Signalauskopplung bei einer erfindungsgemäßen Antenne nach Fig. 9a.

Fig. 10a: Antenne für Zirkularpolarisation, gebildet aus zwei Antennen nach der Erfindung in aufeinander senkrecht stehenden Ebenen, deren Ausgangssignale über ein 90-Grad Phasendrehglied 18 in einer Summationsschaltung 19 zusammengefaßt sind mit einem weiteren Anschlußtor Tu zur Auskopplung einer unsymmetrischen Spannung.

Fig. 10b: Prinzip der Signalauskopplung bei einer erfindungsgemäßen Antenne nach Fig. 10a.

Fig. 11: Variation der Richtdiagramme bei Änderung des Werts und des Charakters (induktiv oder kapazitiv) der Impedanz 7 bei einem Beispiel einer erfindungsgemäßen Antennen.

Fig. 12a: Elevationsdiagramm eines Beispiels einer erfindungsgemäßen Antenne

Fig. 12b: Dreidimensional dargestelltes Diagramm einer erfindungsgemäßen Antenne.

Fig. 13: Elevationsdiagramm eines Beispiels einer schielenden erfindungsgemäßen Antenne.

Fig. 14a: Ausbildung einer flächenhaften Dachkapazität 31 in Form eines durch die Impedanz 7 unterbrochenen Halbellipsoids parallel zur Ebene 1

Fig. 14b: Wie Fig. 14a, jedoch mit leiterförmiger Ausbildung des Halbellipsoids

Fig. 15a: Draht- oder streifenförmige Leiterteile 32 mit wesentlicher horizontaler Ausdehnung 4b in der Ebene 30 parallel zur Ebene 1

Fig. 15b: Wie Fig. 15a, jedoch mit flächenhaft gestalteten Leiterteilen 4b vorzugsweise in gedruckter Leitertechnik

Fig. 16: Ähnliche Ausführungsform wie Fig. 15b, ebenfalls in gedruckter Leitertechnik

Fig. 17a-c: Erklärung der prinzipiellen Wirkungsweise erfindungsgemäßer Antennen mit streng symmetrischem Aufbau im Hinblick auf die kapazitiven Koppeleffekte

Fig. 18a: Erfindungsgemäße Antenne für Zirkularpolarisation und streng symmetrischem Aufbau mit dreiecksförmigen Dachkapazitäten 31 und zur Erläuterung der Strompfade

Fig. 18b: Antenne mit ringförmiger Zentralstruktur 37 und Koppelkapazitäten 34

Fig. 19: Erfindungsgemäße Antenne ähnlich Fig. 18b, jedoch mit zusätzlichem vertikalen Antennenleiter 20 in der vertikalen Symmetrielinie 8

Fig. 20: Kombination aus Dachkapazitäten 31, welche auf einem dielektrischen Körper von der Form eines Pyramidenstumpfs geeignet ausgebildet sind.

Fig. 21a: Ähnlich Fig. 10b, jedoch mit weiteren Anschlusstoren 40a bis 40c zur Auskopplung unsymmetrischer Spannungen für weitere Funkdienste

Fig. 21b: Wie Fig. 21a, jedoch mit frequenzselektiven Entkopplungsnetzwerken 42 in den Anschlusstoren T1a, T1b, T2a und T2b

Fig. 22: Prinzipieller möglicher Aufbau einer erfindungsgemäßen Antenne für Satellitenfunk und mehrere terrestrische Funkdienste

The invention is described below with reference to the figures. Show it:

1: Principle of an antenna according to the invention with a high-frequency conductive ring structure 2, formed from essentially vertical conductor parts 4a and essentially horizontal conductor parts 4b and the conductive base plane 1.

2: Principle of an antenna according to the invention with one-sided coupling at the antenna connection point 5.

3a: Symmetrical antenna of an antenna according to the invention with the antenna connection points 5 and 5 'and a resymmetry network 9, formed from asymmetrical lines 10a and 10b.

3b: Symmetrical antenna according to the invention with a resymmetrical network 9, formed from asymmetrical lines 10a and 10b, the length of which differs by an odd multiple of half the operating wavelength.

3c: Symmetrical antenna according to the invention with a resymmetry network 9 according to the transformer principle for separate asymmetrical coupling of the symmetrical and the asymmetrical voltages

4a: Symmetrical antenna according to the invention, in which the antenna connection point 5 is arranged in the region of the axis of symmetry 8 of the antenna and in which the signals are guided downwards by means of a symmetrical two-wire line.

Fig. 4b: Detail from Fig. 4a.

Fig. 4c: Detail from Fig. 4a, but with a shielded two-wire line.

4d: Antenna according to the invention similar to FIG. 4a, but with two coaxial lines instead of the two-wire line and with a resymmetrical network 9 according to the transformer principle for separate asymmetrical coupling of the symmetrical and the asymmetrical voltages.

5: Antenna according to the invention with dimensions and with a matching network 17th

6a: Antenna for circular polarization, formed from two antennas according to the invention in mutually perpendicular planes, the output signals of which are combined in a summation circuit 19 via a 90-degree phase-rotating element 18.

6b: Example of a strip line layout for the antenna according to FIG. 6a.

Fig. 6c: Spatial representation of the antenna for circular polarization.

7: Antenna for circular polarization, formed from three antennas according to the invention in three planes, which are arranged azimuthally at 120 ° angles, the output signals of which are combined in a summation circuit 19 by means of 120-degree phase rotators 18.

Fig. 8: antenna for circular polarization according to Fig. 7, in which the vertical conductor 4a 'is omitted in the symmetry point of the arrangement.

9a: Antenna according to the invention with a further connection gate Tu for coupling out an asymmetrical voltage.

9b: Principle of signal decoupling in an antenna according to the invention according to FIG. 9a.

10a: Antenna for circular polarization, formed from two antennas according to the invention in mutually perpendicular planes, the output signals of which are summarized via a 90-degree phase-rotating element 18 in a summation circuit 19 with a further connection gate Tu for decoupling an asymmetrical voltage.

10b: Principle of signal decoupling in an antenna according to the invention according to FIG. 10a.

11: Variation of the directional diagrams when the value and the character (inductive or capacitive) of the impedance 7 change in an example of an antenna according to the invention.

12a: Elevation diagram of an example of an antenna according to the invention

12b: Three-dimensional diagram of an antenna according to the invention.

13: Elevation diagram of an example of a cross-eyed antenna according to the invention.

14a: Formation of a flat roof capacitance 31 in the form of a semi-ellipsoid interrupted by the impedance 7 parallel to level 1

14b: Like FIG. 14a, but with a ladder-shaped design of the semi-ellipsoid

15a: wire or strip-shaped conductor parts 32 with a substantial horizontal extent 4b in the plane 30 parallel to the plane 1

15b: Like FIG. 15a, but with flat conductor parts 4b, preferably in printed conductor technology

Fig. 16: Similar embodiment as Fig. 15b, also in printed conductor technology

17a-c: Explanation of the principle of operation of antennas according to the invention with a strictly symmetrical structure with regard to the capacitive coupling effects

18a: Antenna according to the invention for circular polarization and strictly symmetrical structure with triangular roof capacitances 31 and to explain the current paths

18b: Antenna with an annular central structure 37 and coupling capacitances 34

19: Antenna according to the invention similar to FIG. 18b, but with an additional vertical antenna conductor 20 in the vertical line of symmetry 8

20: Combination of roof capacitors 31, which are suitably formed on a dielectric body in the shape of a truncated pyramid.

21a: Similar to FIG. 10b, but with further connection gates 40a to 40c for coupling out asymmetrical voltages for further radio services

21b: Like FIG. 21a, but with frequency-selective decoupling networks 42 in the connection ports T1a, T1b, T2a and T2b

Fig. 22: Possible basic structure of an antenna according to the invention for satellite radio and several terrestrial radio services

Fig. 1 shows the basic shape of an antenna according to the invention consisting of one with the conductive base 1 formed high-frequency conductive ring structure 2 with Ladder parts with a substantial horizontal extent 4b and ladder parts with a substantial one vertical extension 4a within a plane 0, which is on the conductive base surface 1 is vertical. An essential function according to the present invention takes on here the impedance 7, which is in an interruption point of the high-frequency conductive Ring structure 2 in the impedance connection point 6 with the first impedance connection point 6a and the second impedance connection point 6b is introduced. When an incident occurs in level 0 polarized electromagnetic wave occurs at a certain elevation angle 81 the inclusion of horizontal electrical field components mainly through the Conductor parts with a substantial horizontal extent 4b and - corresponding to this - the vertical electrical field components mainly through the conductor parts substantial vertical extent 4a. With a suitable position of the antenna connection point 5 in an interruption of the ring structure 2 and with a suitable positioning of the Impedance 7 within the ring structure 2 can be a vertical diagram with a desired superimposition of the inclusion of vertical and horizontal electrical Set field components.

The design of the predetermined ratio of antenna gain in the zenith angle range The basic requirement is to gain antennas in the area of low elevation angles Antennas for satellite communication. Consequently, the adjustability is vertical and horizontal shot the basis of the present invention. In an advantageous The embodiment of the invention is the antenna connection point 5 on the conductive base area 1 formed and the antenna signals are between a first antenna connection point 5a and a second antenna connection point 5b are coupled out of the ring structure 2. To one Antenna connection point 5 formed in this way can be coupled to asymmetrical lines, as shown in Fig.2.

In an advantageous embodiment of the invention, the ring structure 2, as in FIG. 3a shown, formed symmetrically to a vertical line of symmetry 8. The antenna contains thus two identical impedances 7, which are also symmetrical to the vertical line of symmetry 8 are positioned, and a mirrored to the first antenna connection point 5 is introduced Has antenna connection point 5 'on the conductive base 1. The coupling of the Ring structure 2 on the conductive base 1 enables, as shown in Fig. 3b, the advantageous embodiment of a resymmetry network 9, which e.g. with the help of a λ / 2 detour line the signals can be realized. The decoupling is symmetrical conductive base area 1 forming asymmetrical receive voltages Uu, the Direction indicated by arrows in the figures is done by simple Parallel connection of the unbalanced lines in Fig. 3b, the lengths of which are Distinguish λ / 2. The summarized symmetrical receive voltage ~ Us is at Collection point 11 in Fig. 3b available.

Such a resymmetry network 9 can be very advantageous and inexpensive in printed form Microstripline technology can be carried out. With this arrangement, different Design of impedance 7 the vertical diagrams shown in FIG level 0. The impedance 7 can be positioned within the ring structure 2 can be freely selected within wide limits, with an extended conductor length for the in the Figures 3a and 3b marked section 16 of λ / 4 proves to be particularly favorable. This applies in particular with regard to the antenna impedances effective at the antenna connection points 5, which is particularly important with regard to an easily realizable balancing network 9 should be suitable through line circuits. Setting the right one Vertical diagram, on the other hand, can be used within wide limits for different lengths of section 16 by appropriate choice of impedance 7. With a preferred transverse dimension 15 of a little less than half a wavelength can be shown in FIG Achieve directional diagrams at a height 14 of less than a quarter wavelength. To the disadvantage of prior art satellite communication antennas overcome, it is necessary to reduce the radiation in the area of low elevation angles To raise compared to the radiation in the zenith angle range. This is done according to the invention by Design the impedance 7 as a capacitance. This causes the radiation to rise in the area of low elevation angles with increasing reactance, that is, decreasing Capacity value is done. This expresses the diagrams D3, D2 and D1 in Fig. 11 for smaller capacity values. If the impedance is 7 instead of a capacitance than one If the inductance is implemented, the elevation diagrams denoted D4 and D5 result in Fig. 11. These have the property of an angular range at medium elevation largely hide. The inductance value of the directional diagram D5 is larger chosen as for the directional diagram D4. For satellite communication, therefore, come from Apart from special cases for special applications, due to the requirement described above in an antenna according to the invention capacitances as an impedance 7 for use. For the Combination of several such antennas to form a circularly polarized satellite communication antenna this property of the antenna is essential.

The additional availability of the asymmetrical voltages Uu proves to be advantageous at the antenna connection points 5, which is used in Fig. 3c in that in a Summation circuit 19 in addition to a resymmetry network 9 for decoupling the unbalanced receive voltages Uu a power divider 21 for decoupling the symmetrical receive voltages Us is present. At the assembly point for symmetrical Voltages 11a and at the collection point for asymmetrical voltages 11b in FIG. 3c thus both asymmetrical receive voltages Uu and symmetrical Receiving voltages Us are decoupled separately.

A further advantageous decoupling of the symmetrical voltage Us can, as in FIG. at an antenna connection point 5 arranged in the vertical line of symmetry 8. For this purpose, in FIG. 4b (detail from FIG. 4a) there is a two-wire line 24 to the first antenna connection point 5a and the second antenna connection point 5b connected and in the vertical Line of symmetry 8 led to the conductive base 1, in the vicinity of a line connection point 25 is designed. There are formed between the end points of the two-wire line 24 the voltage ~ Us and proportional to the symmetrical received voltages Us each between an end point of the two-wire line 24 and the conductive base 1 voltage ~ Uu off to the unbalanced receive voltages Uu.

In a further advantageous embodiment of the invention, as in FIG. 4c, the Two-wire line 24 to be replaced by a shielded two-wire line 23, the Shield conductor is connected to the conductive base 1. This will make it cheaper Decoupling the voltage ~ Uu on the conductive base 1 enables. In another favorable embodiment can the shielded two-wire line 23 in a simple manner two coaxial lines 22 run in parallel, as shown in Fig. 4d, their shields are connected to the conductive base 1. With the help of the power divider 21, the Voltages ~ Us and ~ Uu, as described above, with the arrangements of Figures 4b, 4c and 4d can be coupled out separately.

In the case of an antenna according to the invention which is particularly easy to produce, as shown in FIG. the ring structure 2 is configured essentially rectangular. Realized antenna shapes with a section 16 of approximately ¼ λ, a transverse dimension 15 of approximately 1/3 λ and one Overall height 14 of about 1/6 λ are sufficiently small for the required directional diagrams Result in losses. A realized antenna according to the invention for frequencies around 2.3 GHz e.g. only a construction height 14 of 2 cm with a transverse dimension 15 of 4.5 cm. at Smaller heights can be chosen by choosing an appropriate capacitance value for the impedance 7 meet the requirements for the directional diagram, but it is increasing To count losses. The losses occurring in the downstream matching network 17 thus increase with a smaller antenna height.

An essential advantageous embodiment of the invention consists in the combination of several 5 to a satellite communication antenna for circular polarization. In a particularly advantageous embodiment, two antennas are used for this purpose Levels 0 are perpendicular to one another, combined, each antenna as in FIGS. 6a and 6. 6c has a resymmetry network 9 and a matching circuit 17. At the exit of the Matching circuit 17 is the voltage for circular polarization Uz using a phase shifter 18 and a summation circuit 19 are formed. The latter are in Fig. 6c with the help a parallel connection of lines whose length differs by λ / 4. The Matching circuit 17 can advantageously be shown by printed dummy elements as shown in Fig. 6b will be realized. The lines for resymmetrization are the lines 10a, b, the network as adaptation as series or stub lines 17 and for interconnection and 90 degree phase rotation executed as line 18 each printed.

With antennas of this embodiment, a suitable elevation diagram is shown in FIG. 11 of the character of the diagrams D2 and D3 for the individual antenna according to FIG. 5. To the interconnection according to FIG. 6c results in what is required for circular polarization Overall diagram according to Fig. 12a (section azimuth angle = const.) And Fig. 12b (spatial Diagram).

If the conductive base is skewed, e.g. with a curved vehicle roof in Edge area of a window can be the asymmetry of the conductive base 1 and the Inclination compensated for by different capacitance values in the individual antenna branches become. This corresponds to squinting the diagram. One with the invention Antenna-adjustable squinting diagram with a squint angle of approx. 15 degrees opposite FIG. 13 shows the zenith angle by way of example.

In a further advantageous embodiment of the invention, N antennas can be rotationally symmetrical at an angular distance of 360 / N degrees to a vertical line of symmetry 8 be arranged as in FIG. Accordingly, phase shifters 18 with a respective one Phase rotation angle of 360 / N degrees provided, the output signals in the summation circuit 19 are merged and are available at collection point 11. With regard to the design of the impedance 7, the rules mentioned above apply. The roundness of the azimuthal directional diagram can continue by choosing sufficiently large values of N. be improved. The rotational symmetry of such an arrangement means that the vertical conductor 4a ', as in Fig. 8, too.

In a further advantageous embodiment of the invention, the satellite communication antenna is expanded to a combination antenna for which the additional terrestrial communication with vertical polarization is extended to a frequency that deviates from the satellite frequency. This is very advantageously accompanied by a saving in installation space in motor vehicles.
In the case of a symmetrical antenna designed from two antennas in accordance with the basic form of this invention, as in FIG. 9 a, along the symmetry line 8 there is a vertical antenna conductor 20 which is connected at one end to a horizontal part of the ring structure 2 and between its lower end and the conductive base area 1 a connection gate Tu is formed to form an asymmetrical voltage Uu. Here, the conductor parts with horizontal extension 4b act as roof capacitance for the vertical antenna conductor 20. The symmetrical voltages are tapped from the ring structure 2 at the corresponding gates T1a and T1b. The matching network 29 in FIG. 9b serves for frequency-selective adaptation of the impedance present at the connection gate Tu for the frequency of the terrestrial radio service to the characteristic impedance of conventional coaxial lines. The voltage Uu proportional to Uu is present at the output of this matching network 29.

In order not to impair the satellite radio service, the adaptation network 29 is advantageously so to design that the connection gate Tu at the satellite radio frequency with a reactance or is particularly advantageously loaded with a short circuit or idling. The symmetry of the Arrangement can be advantageous for decoupling the connection gates Tu from the connection gates T1a, T1b are used when they are connected to the unbalance network 9. This is to protect the satellite radio service particularly important when the terrestrial Communication is bidirectional. If there is residual asymmetry, it is Improving the decoupling of the satellite radio service advantageous, the unbalance network 9 to be designed such that the connection gates T1a and T1b at the frequency of terrestrial radio service with a short circuit.

In Fig. 10a the complete satellite communication antenna for circular polarization is with the vertical antenna conductor 20 shown. At the connection gates T2a and T2b the 90 Degrees relative to the antenna with the gates T1a, T1b rotated accordingly the antenna in Fig. 6c a resymmetry network 9 with subsequent matching circuit 17 as shown in Fig. 10b connected. Regarding the loading of the gates T2a and T2b at Frequency of the terrestrial communication service to protect the satellite radio service the above statements apply.

In the advantageous embodiment of the invention, the conductor parts are essential horizontal extension 4b to form a roof capacity 31 with a curved Surface designed in the form of a semi-ellipsoid and the edge in a surface 30 is guided, which in one of its dimensions substantially perpendicular to the plane 0 and is thus oriented essentially parallel to level 1. This is exemplified in the figures 14a and 14b. Through a suitable choice of size and shape as the roof capacity 31 effective curved surface in conjunction with the appropriate dimensioning of the Impedances 7 can be both the vertical diagram and the one at the base of the Conductor parts with substantial vertical extension 4a existing base impedances set as desired. Here, the ladder parts can be horizontal Extension 4b to form the roof capacity 31 from wire or strip-shaped conductors 32 may be formed, as indicated in FIG. 14b, and may also be designed as lattice structures. For an embodiment of a roof capacity 31 that is formed in a particularly simple manner these are arranged completely in the surface 30 as a plane parallel to the conductive base surface 1 (Fig. 15a) and preferably formed in printed circuit technology, as in the figures 15a and 15b. This results in the particularly advantageous property that both the roof capacitance 31 and the mostly capacitive impedances 7 are highly accurate and can be produced reproducibly and thus both the directional diagram and the above Base impedances ensured in series production with small scatter can be. Another embodiment of the invention in printed technology shows Fig. 16.

In a further advantageous embodiment of the invention, the Conductor parts with a substantial horizontal extent 4b and several impedances 7,7 'in this way formed that with respect to level 0, in which the conductor parts with substantial vertical Extension 4a are also performed with regard to the impedance values of the impedances 7,7 ' symmetrical arrangement is given. The symmetry of the arrangement should also refer to one oriented perpendicular to both the base area 0 and the base plane 1 Plane of symmetry 33 be given. Such arrangements are in Figures 17a, 17b and 17c shown. To explain the operation of an antenna according to the invention, as in 17c, the ring structure 2 in FIG. 17a should first be considered. A such a ring structure contains the capacities 7,7 ' vertical line of symmetry symmetrical capacities of the frame thus formed is also electrically symmetrical. Capacities between ladder parts with essential horizontal extension 4b and the surrounding space do not disturb this symmetry. Consequently 17a represents an antenna which according to the main claim of Invention is designed and also has the property of symmetry. For better The mode of operation of this arrangement is indicated at level 0, in which also Conductor parts are introduced with a substantial vertical extent 4a and the Plane of symmetry 33 shaded.

Through the described coupling of a resymmetry network 9, e.g. in Fig. 9b is specified, can thus be made from the connection gates T1a and T1b from the symmetrical Antenna arrangement a voltage Us are coupled out. To explain the Operation is noted that in the plane 33 in Fig. 17a initially no conductor parts substantial vertical extent 4a are introduced. According to the nomenclature in Fig. 3a, the impedances marked with 7.7 'on one side of the vertical Line of symmetry 8 in Figures 17a to 17c with 7 and on the other side of the line of symmetry 8 marked with 7 '. Thus, all effective impedances in Fig. 17a are with respect to T1a and T1b marked gates with corresponding indexes 7,7 'with regard to the Placement in relation to the plane of symmetry 33 and due to the common effect the gates T1a and T1b additionally indicated with 1. The capacities not shown in Fig. 17a, which are in the plane of symmetry 33 are T1a and T1b with respect to the gates ineffective. In Fig. 17b the conductor parts are considerably more vertical for understanding Extension 4a with respect to the gates T1a, T1b omitted. With the same arrangement All blind elements 7 described in FIG. 17a become one in the plane of symmetry 33 Ring structure 2 formed with the associated gates T2a and T2b. The names for the Blind elements 7 are accordingly in accordance with the nomenclature introduced in FIG. 17a correspondingly related to these two goals. When combining the two ring structures 2 in Figures 17a and 17b result in the complete arrangement shown in Fig. 17c two according to the invention are perfect with respect to the vertical line of symmetry 8 symmetrical ring structures 2. It follows that an arrangement as shown in Fig. 18a is shown, with a suitable choice of the dimensions of the roof capacities shown there 31, which form coupling capacitances as shown in FIG. 17c, also according to FIG Invention is designed when the coupling capacities by appropriate training of Roof capacities the impedances 7 effective according to the invention with the required size form.

The current arrows for currents I1 and I2 shown in FIG. 18a indicate the principle Current flow of the two frames 2. The current arrows show how this works Impedance network consisting of impedances 7 jointly effective for both frame parts and in which of the impedances 7 the currents I1 and I2 are uniform and in which they are superimposed in opposite directions. 18a shows an example of a connection of the four gates T1a, T1b, T2a, T2b specified, which allows an antenna according to the described Invention to design for circularly polarized radiation. The following are in the Figures 18b, 19 and 20 exemplary embodiments for an antenna of this type listed. In Fig. 18b the two frames are in the vicinity of the vertical Line of symmetry 8 via a conductive central structure 37 via preferably printed coupling capacitors coupled. The correspondingly designed roof capacities 31 with their coupling capacities 34 to each other and such capacities to form a ring-shaped central structure 37 allow the dimensioning of the antenna with respect to a desired one Directivity pattern. The conductive central structure 37 of the antenna in Fig. 19 allows ring-shaped Training the introduction of a vertical antenna conductor 20 which is used to form a desired impedance at the connection gate Tu with a simple design Radiator coupling capacitance 38 is suitably coupled to the annular central structure 37. at Another example of an antenna according to the invention is a combination of in FIG Roof capacitors 31, which are on a dielectric body in the form of a Pyramid stumps are suitably designed, attached, so that over the coupling and Capacities sets the appropriate directional diagram.

In a further very advantageous embodiment of the invention, the antenna is for the coordinated and simultaneous reception of circularly polarized satellite radio signals and from in a radio frequency band of terrestrial that is closely adjacent in frequency Vertically polarized radio signals emitted by radio stations. For such Application is a frequency selective decoupling of the terrestrial radio service from Satellite radio service not possible due to the small frequency spacing. The symmetrical Embodiment of the antennas described above, however, has a perfect Decoupling between the vertical antenna conductor 20 and the output for reception the circular polarization To. Thus the system is not on a narrow band Frequency selection between the two radio services and it can terrestrial broadcast signal and the satellite broadcast signal independently received from each other. Mutual dampening through the withdrawal of power this does not apply to the other gate. Because of the symmetry of the antenna this property is therefore also given for signals with the same frequency such that the reception vertically polarized electrical field components on the vertical antenna conductor 20 none Attenuation regarding the reception of vertically polarized electrical field components on Gate relative to the output for receiving the circular polarization CLOSED. This The facts are given in the antennas according to FIGS. 10a, 10b, 19, 20 and 22.

In a further advantageous embodiment of the invention, an antenna for the additionally combined bidirectional radio operation with vertically polarized terrestrial Radio stations shown. Here, the vertical antenna conductor 20 is additionally for at least bidirectional radio operation with vertically polarized terrestrial radio stations used. The radiator length 43 of the vertical antenna conductor 20 for radio service with the The lowest frequency is advantageously chosen to be sufficiently large. In the case a required frequency-selective shortening of the electrically effective radiator length 43 for higher radio channel frequencies, as indicated in FIGS. 21a and 21b, on advantageous way in the longitudinal train of the vertical antenna conductor 20 breakpoints with suitable blind elements 41 for designing the vertical diagram and the Base impedance inserted for this frequency.

21a shows the block diagram of such a combination antenna. To the To effect impedance matching for the different radio services will be advantageous corresponding matching networks 29a, 29b, 29c with outputs 40a, 40b, 40c for connection of the corresponding radio equipment. To separate the impedance effects and the Signals in the different frequency ranges are the inputs of the matching networks 29a, 29b, 29c each via a frequency-selective isolating circuit 39a, 39b, or 39c to the common connection gate Tu switched on; that the adjustment ratios on Connection gate Tu in the radio frequency channels of the different radio services mutually so are influenced as little as possible.

To avoid radiation-related coupling between the connection gate Tu of the vertical antenna conductor 20 and the connection gates T1a, T1b, T2a, T2b Ring structures 2 are advantageous in the vicinity of the base points of the conductor parts vertical extension 4a each decoupling networks 42 used. These are like this carried out for signals on the frequency of a bidirectional radio operation with vertical polarized radio stations block the frequency of the circularly polarized However, satellite radio signals are permeable. This has the advantageous effect that the impedances present at the gates T1a and T1b via the resymmetry network 9 neither via their active component radiation attenuation on the frequency of a bidirectional radio service still have undesirable reactances on such Frequency cause a disturbing effect.

List of names

Level 0

conductive base area 1

Ring structure 2

Ladder parts with a substantial vertical extent 4a

Ladder parts with a substantial horizontal extension 4b

Antenna connection points 5, 5 '

first antenna connection point 5a, 5a '

second antenna connection point 5b, 5b '

Impedance connection point 6, 6 '

first impedance connection point 6a, 6a '

second impedance connection point 6b, 6b '

Impedance 7, 7 '

vertical line of symmetry 8

symmetrical receive voltages Us

asymmetrical receive voltages Uu

Balancing network 9

Unbalanced lines 10a, b

Collection point 11

Collection point for symmetrical voltages 11a

Collection point for unbalanced voltages 11b

Point of symmetry 12

Symmetrical line 13

Height 14

Transverse dimension 15

Section 16

Matching circuit 17

Phase shifter 18

Summation circuit 19

vertical antenna conductor 20

Power divider 21

Coaxial line 22

shielded two-wire cable 23

Two-wire line 24

Line connection point 25

Connection for circular polarization 26

PCB 27

Detour line 28

Matching network 29

Area 30

Roof capacity 31

Wire or strip-shaped conductors 32

Plane of symmetry 33

Coupling capacities 34

flat conductor structures (35)

Separating columns (36)

Central structure (37)

Spot length (43)

Radiator coupling capacity (38)

frequency selective isolation circuits (39)

Output (40)

Blind elements (41)

Decoupling network (42)

Wave incidence 80

Elevation angle 81

Connection gate T1a

Connection gate T1b

Connection gate T2a

Connection gate T2b

Connection gate Tu

symmetrical voltages Us

unbalanced voltages Uu voltage for circular polarization Uz

Claims (37)

Antenna for mobile satellite communication on a substantially horizontally oriented conductive base area (1) consisting of essentially linear conductor parts (4) and an antenna connection point (5)
characterized in that
a high-frequency conductive ring structure (2) is formed from the conductor parts with a substantial vertical extension (4a) and the conductor parts with a substantial horizontal extension (4b) together with the conductive base area (1), and the conductor parts with a substantial vertical extension (4a) and the conductor parts with a substantial horizontal extension (4b) are guided essentially in a plane (0) perpendicular to the conductive base surface (1) and one of the conductor parts with a substantial vertical extension (4a) or one of the conductor parts with a substantial horizontal extension (4b) to form the Antenna connection point (5) is interrupted and by interrupting one of the conductor parts (4a), (4b) there is at least one impedance connection point (6) connected to an impedance (7) and the positions of the impedance connection point (6) and the antenna connection point (5) as well as the Impedance (7) are chosen such that for the perpendicular to the conductive group plane (0) standing plane (0) with waves polarized in this plane for predetermined elevation angles (81) of the wave incidence (80) the predetermined antenna gain values are set (FIG. 1). Antenna according to claim 1,
characterized in that
the antenna connection point (5) is formed in the base of a conductor part with a substantial vertical extension (4a) with a first antenna connection point (5a) at the lower end of this conductor part and a second antenna connection point (5b) at a point adjacent to this on the conductive base area (1) and the position of the impedance connection point (6) and a reactance as the impedance (7) are selected such that an asymmetry of the radiation characteristic desired with respect to the zenith is formed with equally sufficient guide values at low elevation angles (FIG. 2). Antenna according to claim 1 and 2,
characterized in that
the ring structure (2) is symmetrical with respect to a line of symmetry (8) which is perpendicular to the conductive base (1) and thus, in addition to the first, there is another antenna connection point (5 ') which is symmetrical thereto and which strikes the lower end of the other on the conductive base (1) Conductor part is present and there is also a further impedance connection point (6 ') with the same size impedance (7') symmetrical to the first and the wiring of the antenna connection points (5 ') is selected such that symmetrical voltages Us are set there (Fig. 3a). Antenna according to claim 3,
characterized in that
A resymmetry network (9) for wiring the antenna connection points (5, 5 ') is available at its output at a collecting point (11), the symmetrical voltages Us formed on the input side symmetrically to the base area (1) are available asymmetrically combined (Fig. 3a). Antenna according to claim 4,
characterized in that
the unbalance network (9) consists of two unbalanced lines (10a, b) with the same characteristic impedance, each of which is connected on the input side to an antenna connection point (5) and which are connected in parallel at the output and whose lengths are selected such that their electrical lengths differ from each other by an odd multiple of half the operating wavelength (FIG. 3b). Antenna according to one of claims 2 to 5,
characterized in that
the ring structure (2) is rectangular and in the interest of sufficient antenna gain values at low elevation angles (81) of the wave incidence (80) in connection with the requirement for a particularly low overall height (14) the transverse dimension (15) is not chosen to be significantly smaller than half Operating wavelength (Fig. 5) Antenna according to one of claims 2 to 6,
characterized in that
the impedance or the impedances (7) are designed as capacitances, the value of which is set in accordance with the requirement for the antenna gain values to be achieved in the predetermined elevation angles of the wave incidence (81) (FIG. 1, FIG. 5). Antenna according to one of claims 2 to 7,
characterized in that
to achieve an antenna impedance at the antenna connection point (5) which is favorable with regard to the design of the resymmetry network (9) as a rough guide value for the extended length (16) of the section of the conductor part (4b) with an essentially vertical extension between the antenna connection point (5) and the position the impedance (7) a quarter wavelength is chosen (Fig. 3a, Fig. 5) Antenna according to one of claims 4 to 8,
characterized in that
The collecting point (11) is followed by a low-loss matching circuit (17) for transforming the complex impedance present at the collecting point (11) into a real impedance that can be implemented as a line impedance (FIG. 5). Antenna for circular polarization,
characterized in that
there are two identical antennas according to claims 4 to 9, the essentially linear conductor parts (4) of which are guided in mutually perpendicular planes (0) and the output signals of which are combined in a summation circuit (19) via a 90-degree phase-rotating element (18) (Fig. 6a, 6c). Antenna according to claim 10,
characterized in that
both antennas are attached to a conductive base surface (1) designed as a printed circuit board (27) and the resymmetry network (9) of both antennas is implemented as a microstrip line with a length of half a wavelength and the matching circuit (17) consists of dummy elements on this circuit board (27) are and the 90-degree phase shifter (18) as a printed detour line (28) with suitable wave resistance and the summation circuit (19) is realized as a simple parallel connection of printed lines (Fig. 6b). Antenna according to one of claims 2 to 11,
characterized in that
N similar antennas according to claims 4 to 9 are present, the substantially linear conductor parts (4) of which are each guided in one plane (0) and the planes (0) are offset from one another by the azimuthal angle of 360 ° / N, so that there is a rotationally symmetrical arrangement around a vertical line of symmetry (8) in such a way that in this line of symmetry there is a vertical conductor (4a ') as a conductor part which is common to all N antennas and has a substantial vertical extent (4a) and the output signals of the antennas in each case Via phase rotators (18), the electrical phase angle of which corresponds to the associated azimuthal angular offset of the associated plane (0), are combined in a summation circuit (19) (Fig. 7). Antenna according to claim 12,
characterized in that
the vertical conductor (4a ') resulting from the rotational symmetry of the arrangement is omitted (Fig. 8). Antenna according to one of claims 1 to 11,
characterized in that
the ring structure (2) is symmetrical with respect to a line of symmetry (8) perpendicular to the conductive base area (1) and the antenna connection point (5) at the point of symmetry (12) is formed symmetrically to the line of symmetry (8) and to a first impedance connection point (6) there is a further impedance connection point (6 ') with an equally large impedance (7) with respect to the line of symmetry (8) symmetrical to the first and the wiring of the antenna connection point (5) is selected such that there are symmetrical voltages ~ Us. with respect to the point of symmetry (12) adjust (Fig. 4a, 4b). Antenna according to claim 14,
characterized in that
at the antenna connection point (5) two straight conductors parallel to each other along the line of symmetry (8) are connected as a two-wire line (24) and at the end of the two-wire line (24) adjacent to the conductive base (1) a line connection point (25) is formed in this way that the asymmetrical voltage ~ Uu is present between each conductor end and the conductive base area (1) and the symmetrical voltage ~ Us is present between the two conductor ends (Fig. 4b). Antenna according to claim 15,
characterized in that
the two-wire line (24) is designed as a shielded two-wire line (23), the screen of which is connected to the base (1) at the other end of the line (FIG. 4c). Antenna according to claim 16,
characterized in that
Instead of the shielded two-wire line (23), two coaxial lines run parallel to each other, the inner conductor of which is connected at each end to a connector of the antenna connection point (5) and the outer conductor of which is connected to the base (1), so that at this point between the Inner conductors are the symmetrical voltages ~ Us and between each inner conductor and the base (1) the asymmetrical voltages ~ Uu (Fig. 4d). Antenna according to one of claims 4 and 14 to 17,
characterized in that
a decoupling network (9a) for decoupling unbalanced voltages ~ Uu in combination with the unbalance network (9) is present and is connected on the input side to the antenna connection points (5) or the line connection point (25), at the output of which the unbalanced side is connected to a first collecting point (11b) asymmetrical voltages ~ Uu formed to the base area (1) are combined asymmetrically and the symmetrical voltages ~ Us formed symmetrically to the base area (1) at the output of the resymmetry network (9) are asymmetrical at the second collecting point for symmetrical voltages (11a) (FIGS. 3c, 4d ). Antenna according to claim 18,
characterized in that
A vertical antenna conductor (20) is formed along the line of symmetry (8), which is connected at one end to the ring structure (2) and at the end of the vertical antenna conductor (20) adjacent to the conductive base surface (1) is a connection gate (Tu) Formation of an asymmetrical voltage ~ Uu is formed (Fig. 9a, 9b). Antenna according to claim 19,
characterized in that
In addition to the resymmetry network (9), which is connected on the input side to the antenna connection points (5) designed as the first connection gate (T1a) and second connection gate (T1b), and the low-loss matching circuit (17), a matching network (29) for designing an adapted decoupling of the asymmetrical ones Voltage ~ Uu is present (Fig. 9b). Antenna according to claim 20 in conjunction with claim 10,
characterized in that
the vertical antenna conductor (20) at the crossing and symmetry point (12) of the two antennas is connected to them (FIGS. 10a, 10b). Antenna for the reception of circularly polarized satellite signals according to one of Claims 10, 21 and 22,
characterized in that
with a length of the section (16) of approximately a quarter of the operating wavelength, the capacitance value of the impedance (7) is selected such that the reactance is approximately 5 to 30 times greater than the impedance of a quarter-wave monopole antenna and is therefore chosen to be sufficiently large, that the antenna gain of a radiation incident at small elevation angles and the radiation incident from the zenith is sufficiently large in accordance with the requirements. (Fig. 6c, 7, 8, 10a, 10b) The antenna of claims 19 to 22
characterized in that
for the additional transmission or reception mode with omnidirectional radiation with vertical polarization, an asymmetrical voltage ~ Uu is fed in or taken out at the connection gate (Tu) (FIGS. 10a, 10b). The antenna of claim 23
characterized in that
if the frequencies of the frequencies of the symmetrical voltages Us and the asymmetrical voltages Uu differ, in order to improve the decoupling between the collecting point for asymmetrical voltages (11b) and the collecting point for symmetrical voltages (11a), which is limited by residual asymmetry of the arrangement, by frequency-selective measures in the matching network (29) and or is improved in the adapter circuit (17). An antenna according to claims 3 to 24
characterized in that
in the presence of discontinuities in the conductive base area (1) or in the case of their inclination with respect to the horizontal, the impedances (7) to compensate for the resulting disturbance of the directional diagram in the individual branches are chosen differently from the otherwise given symmetry of the arrangement. Antenna according to claim 1
characterized in that
that the conductor parts with a substantial horizontal dimension (4b) are flat to form a roof capacity (31) and are guided in a surface (30) which is oriented in one of its dimensions essentially perpendicular to the plane (0) (Fig. 14a) Antenna according to claim 26
characterized in that
the conductor parts with a substantial horizontal extension (4b) for forming the roof capacitance (31) are formed from wire - or strip - shaped conductors (32). (Fig.14b) Antenna according to 26 and 27 in connection with claims 3 to 9
characterized in that
the surface (30) is designed as a plane parallel to the conductive base surface (1) and preferably in printed circuit technology. (Fig.15a, 15b, 16) The antenna of claim 28
characterized in that
for the design of the ring structure (2) the conductor parts with a substantial horizontal extension (4b) and a plurality of impedances (7, 7 ') are formed in such a way that with respect to the plane (0) in which the conductor parts with a substantial vertical extension (4a) are guided , there is also a symmetrical arrangement with respect to the impedance values of the impedances (7, 7 ') and the symmetry of the arrangement is also given with respect to a plane of symmetry (33) oriented both to the base area (0) and to the base plane (1) (FIG 17a, 17b) The antenna of claim 29 in conjunction with claim 10
characterized in that
the two antennas of the same type are formed such that the plane (0) of one antenna forms the plane of symmetry (33) of the other antenna and vice versa and the overall arrangement with respect to the line of intersection of plane (0) with plane of symmetry (33) of Antennas formed vertical line of symmetry (8) is designed from congruent quadrants. (Fig.17c, 17d)) The antenna of claim 30
characterized in that
to form the roof parts (31) of suitable size, each of which has a load on the upper end of the conductor parts with a substantial vertical extension (4a) and to form the impedances (7) as coupling capacitances (34) to form the ring structures (2) of both antennas in the area ( 30) there are in each case galvanically separated planar conductor structures (35), the mutually adjacent edges of which are suitably designed by shape and by the separating gaps (36) between them. (Fig. 18a,) An antenna according to claim 30,
characterized in that
To form the ladder parts with a substantial vertical extension (4a) at their upper end load-bearing roof capacities (31) of suitable size are present in the surface (30) in each case galvanically isolated flat ladder structures (35) and one surrounding the vertical line of symmetry (8) There is a central structure (37) to which the roof capacitances (31) for forming the impedances (7) are capacitively coupled as coupling capacitances (34) for forming the ring structures (2) of both antennas. (Fig.18b) An antenna according to claims 31 and 32 in conjunction with claim 19,
characterized in that
the area in the immediate vicinity of the vertical line of symmetry (8) is left free from conductor parts and the vertical antenna conductor (20) is capacitively coupled to parts of the ring structure (2), such as the central structure (37) or the roof capacities (31), and the radiator length (43) and the radiator coupling capacitance (38) for setting the capacitive coupling are selected with a view to a suitable impedance present at the connection gate (Tu). (Fig. 19, 20) An antenna according to claim 10 in conjunction with claims 21 and 30 for the coordinated and simultaneous reception of circularly polarized satellite radio signals and of vertically polarized radio signals transmitted in a radio frequency band which is closely adjacent in frequency by terrestrial radio stations,
characterized in that
the vertical antenna conductor (20) with the matching network (29) for receiving the vertically polarized terrestrial radio signals in the asymmetrical voltage Uu and the antenna with matching circuit (17), phase shifter (18) and summation circuit (19) for receiving the circularly polarized satellite radio signals in the Voltage for circular polarization Uz is designed, whereby, taking advantage of the decoupling provided by the symmetry, no effective frequency-selective measures for the mutual delimitation of the satellite radio signals from the terrestrial radio signals are given (FIGS. 10a, 10b, 19, 20) Antenna for according to claim 34 and for the combined bidirectional radio operation with vertically polarized terrestrial radio stations,
characterized in that
the radiator length (43) of the vertical antenna conductor (20) is chosen to be sufficiently large for the radio service with the lowest frequency and for the radio services corresponding matching networks (29a, 29b, 29c, ...) with outputs (40a, 40b, 40c, .. .) are available for connecting the corresponding radio devices and the inputs of the matching networks (29a, 29b, 29c, ...) are each connected to the connection gate Tu and contain frequency-selective isolating circuits (39a, 39b, 39c, ...) in such a way that the adaptation conditions at the connection gate Tu in the radio frequency channels of the different radio services are mutually influenced as little as possible. (Fig. 21a, Fig. 22) An antenna for according to claim 35
characterized in that
For frequency-selective shortening of the electrically effective radiator length (43) for higher radio channel frequencies in the longitudinal line of the vertical antenna conductor (20) interruption points with suitable circuits made of dummy elements (41) are introduced. (Fig. 21a) Antenna for according to claims 35 and 36
characterized in that
To avoid the radiation-related coupling between the connection gate Tu of the vertical antenna conductor (20) and the connection gates T1a, T1b, T2a, T2b of the ring structures (2) in the vicinity of the base points of the conductor parts with a substantial vertical extension (4a), decoupling networks (42 ) are available, which have a blocking effect for signals on the frequency of a bidirectional radio operation with vertically polarized radio stations, but are designed to be permeable for the frequency of the circularly polarized satellite radio signal. (Fig. 21b)

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